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An ecosystem is defined as a biological community of interacting organisms and their physical environment. Ecosystems at Risk Geography Geography Ecosystems at Risk Table of Contents 1. Biophysical Interactions Which Lead to Diverse Ecosystems & Their Functioning .................... 6 a. What is an Ecosystem? ............................................................................................................... 6 b. Classifying Ecosystems .............................................................................................................. 6 i. c. Ecosphere ............................................................................................................................... 7 Ecosystem Structure and Functioning ...................................................................................... 7 i. Energy Flows .......................................................................................................................... 9 ii. Nutrient Cycling.................................................................................................................... 10 d. Ecosystem Cycles ...................................................................................................................... 11 e. Monsoonal Ecosystems Powerpoint ....................................................................................... 11 f. Factors Affecting the Functioning of Ecosystems .................................................................. 12 2. a. Introduction .......................................................................................................................... 12 b. The Atmosphere ................................................................................................................... 12 c. The Biosphere ....................................................................................................................... 12 d. The Hydrosphere...................................................................................................................13 e. The Lithosphere ....................................................................................................................13 Vulnerability and Resilience of Ecosystems ................................................................................ 14 a. Causes of Ecosystem Vulnerability.......................................................................................... 14 i. Location ................................................................................................................................ 14 ii. Extent ................................................................................................................................... 14 iii. Biodiversity ............................................................................................................................15 iv. b. 1. Genetic Diversity ...............................................................................................................15 2. Species Diversity ...............................................................................................................15 3. Ecosystem Diversity ..........................................................................................................15 Linkages .................................................................................................................................15 Natural and Human-Induced Environmental Stress............................................................... 16 i. Natural Stress ....................................................................................................................... 16 ii. Human Induced Stress ......................................................................................................... 16 iii. Human Threats to Biodiversity ............................................................................................ 18 c. Human Induced Modifications to Ecosystems ....................................................................... 18 i. Modifications to Natural Vegetation .................................................................................. 19 ii. Intentional Ecosystem Change............................................................................................ 19 iii. Change Through Negligence ............................................................................................... 20 d. Measuring Human Impacts ..................................................................................................... 20 HSC [1] Geography i. Magnitude of Change .......................................................................................................... 20 ii. Rate of Change..................................................................................................................... 20 e. 3. Ecosystems at Risk Population Pressure .................................................................................................................. 21 The Importance of Ecosystem Management and Protection ................................................... 22 d. The Maintenance of Genetic Diversity .................................................................................... 22 i. Thylacine ............................................................................................................................... 23 e. Utility Value .............................................................................................................................. 23 f. Intrinsic Value ........................................................................................................................... 25 g. Heritage Value .......................................................................................................................... 27 h. The Need to Allow Natural Change to Proceed ..................................................................... 27 4. Evaluation of Traditional and Contemporary Management Strategies .................................... 28 i. Contemporary Management Approaches .............................................................................. 28 i. Evaluation Criteria ................................................................................................................ 29 ii. Minimising Human Impacts on Ecosystems ....................................................................... 30 ii. 5. Traditional Management ......................................................................................................... 30 i. Manipulation of Ecosystems ................................................................................................31 ii. Long Term Management Practices ......................................................................................31 Case Study 1: Intertidal Wetlands ................................................................................................ 32 a. Introduction ............................................................................................................................. 32 b. Spatial Patterns and Dimensions ............................................................................................ 32 i. Location ................................................................................................................................ 32 ii. Altitude ................................................................................................................................. 32 iii. Size, Shape and Continuity .................................................................................................. 32 c. Biophysical Interactions .......................................................................................................... 33 d. Adjustments to Natural Stress and the Nature and Rate of Change Affecting the Ecosystem Function ......................................................................................................................... 36 i. ii. e. HSC Salinity .................................................................................................................................. 36 1. Mangroves........................................................................................................................ 36 2. Salt Marshes ..................................................................................................................... 36 Tidal Movements ................................................................................................................. 36 Human Impacts on Wetlands .................................................................................................. 37 i. Atmosphere.......................................................................................................................... 37 ii. Hydrosphere......................................................................................................................... 37 iii. Lithosphere .......................................................................................................................... 37 [2] Geography Ecosystems at Risk iv. Biosphere.............................................................................................................................. 37 v. Human Modifications of Intertidal Wetland Ecosystems .................................................. 38 vi. Positive Impacts ................................................................................................................... 38 vii. Negative Impacts ............................................................................................................. 39 viii. Why Protect the Intertidal Wetland Ecosystem? ........................................................... 39 1. Maintaining Genetic Diversity ......................................................................................... 39 2. Utility Value ...................................................................................................................... 39 3. Intrinsic Value ................................................................................................................... 40 4. Heritage Values ................................................................................................................ 40 5. The Need to Natural Processes to Continue .................................................................. 40 i. Traditional and Contemporary Management Practices......................................................... 42 i. Traditional Management Strategies ................................................................................... 42 iii. Contemporary Management ............................................................................................... 42 j. Mangroves................................................................................................................................ 43 k. Salt Marshes ............................................................................................................................. 47 6. Towra Point Nature Reserve ....................................................................................................... 48 a. Spatial Patterns and Dimensions ............................................................................................ 48 b. Biophysical Interactions .......................................................................................................... 48 i. Mangroves............................................................................................................................ 49 ii. Salt Marshes ......................................................................................................................... 49 iii. Rainforests ........................................................................................................................... 49 iv. Sand/Mud Flats..................................................................................................................... 50 v. Freshwater Wetlands........................................................................................................... 50 vi. Seagrasses ............................................................................................................................ 50 vii. Forests .............................................................................................................................. 50 1. Casuarina Forest............................................................................................................... 50 2. Dune Sclerophyll Woodlands .......................................................................................... 50 viii. c. HSC Importance ........................................................................................................................51 Human Impacts .........................................................................................................................51 i. Erosion ...................................................................................................................................51 ii. Weeds ....................................................................................................................................51 iii. Horse Riding ..........................................................................................................................51 iv. Boating ..................................................................................................................................51 v. Feral Animals .........................................................................................................................51 [3] Geography vi. Fragmentation ..................................................................................................................... 52 vii. Development and Construction ...................................................................................... 52 d. 7. Ecosystems at Risk Traditional and Contemporary Management Strategies ....................................................... 52 i. Traditional Management ..................................................................................................... 52 ii. Contemporary Management ............................................................................................... 53 The Great Barrier Reef ................................................................................................................. 54 a. Spatial Patterns and Dimensions ............................................................................................ 54 i. Location and Altitude .......................................................................................................... 54 ii. Size ........................................................................................................................................ 54 iii. Shape .................................................................................................................................... 54 iv. Continuity ............................................................................................................................. 54 b. Biophysical Interactions .......................................................................................................... 55 i. The Role of the Atmosphere ............................................................................................... 55 ii. The Role of the Lithosphere ................................................................................................ 55 iii. The Role of the Hydrosphere .............................................................................................. 55 iv. The Role of the Biosphere ................................................................................................... 55 v. Biogeographical Processes.................................................................................................. 57 c. 1. Rates of Reef Growth ...................................................................................................... 57 2. Resilience .......................................................................................................................... 57 3. Coral Spawning ................................................................................................................ 57 4. Ecological Succession ...................................................................................................... 57 Nature and Rate of Change Affecting the Ecosystem Functioning ...................................... 57 i. Natural Impacts .................................................................................................................... 57 1. Impact of Sea Levels on The Great Barrier Reef ............................................................ 57 a. The Nature of Change .................................................................................................. 57 b. The Rate of Change...................................................................................................... 58 2. Crown-of-thorns Starfish Infestations ............................................................................ 58 a. The Nature of Change .................................................................................................. 58 b. The Rate of Change...................................................................................................... 58 3. ii. a. The Nature of Change .................................................................................................. 59 b. The Rate of Change...................................................................................................... 59 Human Impacts .................................................................................................................... 59 1. HSC Tropical Cyclones ............................................................................................................. 59 Climate Change ................................................................................................................ 59 [4] Geography Ecosystems at Risk 2. Boating and Commercial Shipping ..................................................................................60 3. Overfishing .......................................................................................................................60 4. Tourism .............................................................................................................................60 a. Importance ...................................................................................................................60 b. Impacts of Tourism ......................................................................................................60 5. Land Clearing .................................................................................................................... 61 6. Agriculture ........................................................................................................................ 61 d. Human Impacts ........................................................................................................................ 62 e. Traditional and Contemporary Management Strategies ....................................................... 64 i. Contemporary Management Strategies ............................................................................. 64 1. ii. HSC Tourism ............................................................................................................................. 64 a. The Role of Education .................................................................................................. 64 b. The Impact of Geographical Concentration ............................................................... 64 c. Pontoons ...................................................................................................................... 65 d. Recreational Boats ....................................................................................................... 65 e. Disturbance to Wildlife and Breeding Cycles.............................................................. 65 f. Whale Watching ........................................................................................................... 65 g. Turtles ........................................................................................................................... 65 h. Role of the Tourism and Recreational Reef Advisory Committee ............................66 2. Improving Water Quality .................................................................................................66 3. Anchoring and Mooring ................................................................................................... 67 a. Public Mooring ............................................................................................................. 67 b. Restrictions to Anchoring ............................................................................................ 67 Traditional Management Strategies ................................................................................... 67 [5] Geography Ecosystems at Risk Ecosystems at Risk 1. Biophysical Interactions Which Lead to Diverse Ecosystems & Their Functioning a. What is an Ecosystem? An ecosystem is a delicately balanced natural system in which there are complex interactions between: o Plants o Animals o Micro-organisms and o Their non-living (abiotic) environment Another term for ecosystem is an ecological system. Ecosystems are identifiable systems of interdependent relationships between living organisms and their biophysical environments. Community: a group of interdependent They are systems through which incoming solar energy is captured organism living and channelled through a hierarchy of life forms. together in a Each ecosystem has its own characteristic plant and animal community. common Components in an ecosystem can vary naturally or from human intervention. environment and Each variation affects other components in the ecosystem. interacting with one another. b. Classifying Ecosystems Ecosystems are usually classified according to their dominant feature such as: o Climate (e.g. polar ecosystem) o Physical features (e.g. mountain ecosystem) o Vegetation (rainforest ecosystem) The more small scale the ecosystem the more likely it will be named after a physical feature. Land Based Ecosystems (forests, grasslands, deserts) A.K.A Terrestrial ecosystems or biomes. Theses will vary according to changes in temperature and precipitation. HSC Water Ecosystems – Aquatic Ecosystems (ponds, lakes, rivers, reefs, inland wetlands) These will vary according to variations in dissolved nutrients, salinity, depth of sunlight penetration and average temperature. Ecosystems rarely have distinct boundaries, instead they blend into adjacent ecosystems via a zone of transition called a ecotone. Ecotones contain organisms common to both ecosystems, but may also have unique organisms. Therefore ecotones have greater biodiversity than surrounding ecosystems. [6] Geography i. Ecosystems at Risk Ecosphere The ecosphere is the collection of living and dead organisms (biosphere) interacting with one another and their non-living environments. An ecosphere is therefore the total of all world ecosystems. Ecology is concerned with interactions that occur at five levels of organisation: •The total of all world ecosystems. Ecosphere Ecosystems •A collection of living and dead organisms interacting with each other and their non-living environment. Community •Groups of populations of different organisms in a defined location. •Groups of individual organisms living in habitats. Population •Any living thing, single-celled or multi-celled. Organism c. Ecosystem Structure and Functioning HSC Ecosystem functioning is the ability of an ecosystem to capture, store and transfer energy, nutrients and water. The productivity of an ecosystem is expressed by: o The amount of biomass produced in an area (the mass of new living matter produced per metre squared – or within a volume of water) o Energy flows (the amount of energy in kilojoules that is locked into all the organisms in an area per unit of time) Both of the above rates depend on: o Available energy and nutrient in the environment o The efficiency in which energy and matter are incorporated into producers and passed up the food chain or food web. [7] Geography Ecosystems at Risk Ecosystem functioning depends on o Energy Flow o Nutrient Recycling These processes in turn link the energy, chemicals and organisms of an ecosystem. The word trophic means ‘food’ or ‘nourishment’. Most of the available food or nutrients for any ecosystem are found in the top layer of soil and leaf litter. Hence the biomass of food available is in the lowest trophic levels. At each trophic level there is a los of energy which perhaps explains why there are numerous small plants and insects at the lower tropic levels and many herbivores plus fewer carnivores and less energy to support them at the tertiary level. Lower trophic levels have a surplus of nutrients and energy, but there is a deficit at higher trophic levels. Abiotic Biotic Solar Energy Tertiary Consumers Precipitation Secondary Consumers Organic Material Water Primary Consumers Soil Decomposers Soil and Rocks Producers Soluble Chemicals HSC [8] Geography Tertiary Consumers Secondary Consumers Primary Consumers Producers Detritivores i. HSC Ecosystems at Risk •Fourth Trophic Level •Top carnivores that feed on other carnivores •Includes: Omnivores and scavengers •Third Trophic Level •Carnivores •Feed on smaller plant eating consumers •Second Trophic Level •Herbivores •Feed directly on producers •First Trophic Level •Plants •Convert elements such as carbon, oxygen and hydrogen to usable inputs (food) •Includes decomposers and detritus feeders •Feed off dead organisms and their waste products •Detritus feeders include: earthworms, crabs, temites and slaters •Decomposers are consumers like bacteria & fungi that break down or recycle organic material to get nutrients Energy Flows All life depends on energy from the sun Energy flows through ecosystems by means of food chains Producers, consumers and decomposers form a chain that allows the flow of energy from the sun through plants to animals. Sun Plant Herbivore Carnivore Second Carnivore Top Carnivore The different levels of a food chain are known as feeding or trophic levels At the first trophic level are the producers: o Land – plants, o Sea – phytoplankton At the next trophic level are the consumers: o Herbivores – primary consumers o Carnivores – secondary consumers [9] Geography ii. Ecosystems at Risk o Omnivores – meat and plant eaters o Detritivores – bacteria, fungi Simple food chains are rare as some animals feed at more than one trophic level and provide a food source at different trophic levels The complex network of feeding relationships is called a food web. At each trophic level there are thermodynamic heat losses. A plant will use up to 50% of the energy it receives through photosynthesis. Consumer organisms will lose up to 8090% of energy available. In fact only abut 1/10 of the energy received is passed on Nutrient Cycling Nutrient Cycling: The flow of energy through food webs that allow nutrients to be recycled from non-living environments to living environments then back to non-living environments HSC The consumption of herbivores by carnivores passes nutrients through the food web. Nutrient cycles are driven either directly or indirectly by the sun Examples of nutrient cycles include o Carbon o Oxygen o Hydrogen o Nitrogen o Phosphorous o Sulphur o Water [10] Geography Ecosystems at Risk d. Ecosystem Cycles Nitrogen Cycles Phosphorous Cycles Carbon Cycles •Living matter needs nitrogen to make proteins •Nitro comes from soils •Recycled through food chain •Released by weathering rocks •Dissolves in water, taken up by plants •Recycled through food chain and returned to soils through decaying matter •Carbon a basic building block of compounds necessary for life •Carbon obtained through pores in leaves by land plants •Phytoplankton from CO2 dissolved in water •Photosynthesis converts carbon in CO2 to glucose which is used as energy source and for plant growth before being passed down the food chain •O2 is biproduct of photosynthesis. e. Monsoonal Ecosystems Powerpoint HSC [11] Geography Ecosystems at Risk f. Factors Affecting the Functioning of Ecosystems a. Introduction The four components of the biophysical environment are: Atmosphere Biosphere Hydrosphere Lithosphere These components interact within ecosystems and ultimately affect the development of an ecosystem Time is also a factor in ecosystem development: Natural changes can take place over tens of thousands of years. Human induced changes are typically too rapid for natural systems to adjust. b. The Atmosphere The atmosphere is the main source of climatic factors that impact on ecosystem functioning. Temperature and the amount of rainfall determine the nature of all the factors within the ecosystem and the speed at which they function. The effects of atmosphere on ecosystems are diverse. The atmosphere is the main source of nutrients o Nitrogen o Carbon o Oxygen o Water Circulation patterns in the atmosphere determine the spread of pollutants. c. The Biosphere The biosphere is the domain on or near the earth’s surface where solar energy produces chemical changes necessary for life. The biosphere is all living and dead organisms on the earth’s surface. The biosphere is in a narrow zone from about 200m below the surface to about 9km above sea level The biosphere has two types of organisms: o Autotrophic Organisms (producers) Self sufficient manufacturers of food. Mainly green plants that make organic compounds via photosynthesis. Form the base of any food web o Heterotrophic Organisms (Consumers) Can’t make their own food. Includes herbivores, carnivores, omnivores and decomposers. HSC [12] Geography Ecosystems at Risk d. The Hydrosphere The hydrosphere is closely linked to the atmosphere and determines the nature of the water cycles. Large bodies of water moderate temperatures of adjoining land masses because water heats and cools more slowly than land. Polar Regions: o Have annual rainfall less than 250mm and little fresh water Tropical Rainforests: o Large volumes of rainfall in short spaces of time. o Creates an ecosystem with high levels of biodiversity. o This has a vigorous hydrological cycle that quickly leaches soil and erodes land. e. The Lithosphere The lithosphere determines the nature of soils and provides habitats for many decomposer organisms that recycle the minerals essential to the plants forming the basis of the food web. The capacity of the soil to store nutrients and store water helps determine the nature of particular ecosystems. o Non-porous clays can lead to wetlands as water is trapped close to or above the surface. o Sandy soils allow water to drain quickly leaving a very dry soil profile. Climatic factors affect the role soil plays in an ecosystem. o Climatic conditions in the tundra creates a permafrost (soil frozen for most of the year). o Landforms also affect ecosystems. o Small differences in elevation result in marked differences in plant communities. HSC [13] Geography Ecosystems at Risk 2. Vulnerability and Resilience of Ecosystems All ecosystems function in a state of dynamic equilibrium or a continual state of balanced change. This state of dynamic equilibrium is the product of the interrelationship of the elements in the ecosystem: the atmosphere, lithosphere, hydrosphere and biosphere. Change occurs because the interrelationship between minerals, energy and communities differs over time. It is the interdependence that makes an ecosystem vulnerable: a change beyond the limits of the equilibrium in any of these elements means that the system as a whole cannot exist. a. Causes of Ecosystem Vulnerability All ecosystems have some ability to withstand stress. They tend to resist being disturbed or altered and will restore themselves to their original condition ¡f not disturbed too drastically. In other words, ecosystems maintain themselves within a tolerable range of conditions. A number of factors are relevant to how vulnerable ecosystems are stress. These include location, extent, biodiversity and linkages. i. Location The location of an ecosystem affects its functioning. At a global scale, latitude, distance from the sea and altitude play decisive roles in determining climate and ultimately the nature of particular ecosystems. The microclimatic features of a location can be significant enough to create a range of distinctive ecosystem types within relatively small areas. Some ecosystems are located in environments considered extreme deserts (extreme heat and/or aridity), the polar regions and high mountain peaks (extreme cold), hvpersaline lagoons (extreme salinity and areas of nutrient deficiency. Organisms capable of living in such conditions are, by necessity; highly specialised. T he greater the degree of specialisation an organism has to a particular set of environmental conditions the more vulnerable that organism is to changes in those conditions. An example is coral: Corals are highly specialised organisms that flourish in the relatively shallow nutrient deficient waters of the tropics. An increase of just a few degrees above the usual summer temperature can be devastating. ii. Extent The extent (size) of any ecosystem is the product of a variety of factors. The boundaries of ecosystems tend to overlap each other (ecotones) Ecosystems that are restricted to small areas or have already been disturbed extensively are especially vulnerable. Tropical forests for example have relatively small populations of a large number of species confined to relatively small, localised communities. The loss of even small areas of rainforest can lead to the extinction of plant and animal species. HSC [14] Geography Ecosystems at Risk iii. Biodiversity Biodiversity is usually considered at three levels: genetic diversity, species diversity and ecosystem diversity. 1. Genetic Diversity Genetic diversity is the variety of genetic information contained in all individual plants, animals and micro-organisms. Genetic diversity favours the survival of a species, because it increases the chance that some members of the species will have characteristics to aid their survival if the population is subject to stress. Often a gene has costs as well as benefits. 2. Species Diversity Species diversity is a measure of the number of species at each trophic level of an ecosystem. In simpler terms, the greater the species diversity, the more robust the ecosystem: if the population of one producer or consumer organism crashes, there are other producers and consumers available that can fulfil a similar function in the ecosystem. When ecosystems are diverse, there is a range of different pathways for the ecological processes, such as nutrient recycling. If one pathway is damaged or destroyed, there are other pathways that can be used as an alternative and the ecosystem can continue to function as normal. If the level of biodiversity is greatly diminished the functioning of the ecosystem is put at risk. Therefore the greater the level of diversity, the greater the opportunity to adapt to change. A species can be vulnerable even if the whole ecosystem is not 3. Ecosystem Diversity Ecosystem diversity refers to the diversity present within ecosystems in terms of habitat differences, biotic communities and the variety of ecological processes. iv. Linkages Interdependence, or linkages, is related to biodiversity. The greater the level of interdependence within an ecosystem the greater its ability to absorb change. HSC The loss of a primary consumer from a food web is unlikely to have a major impact on secondary consumers if there is a range of alternative primary consumers on which to feed. Ecosystems that have low levels of interdependence are much more vulnerable to change. For example, impacting the number of krill in an Antarctic ecosystem will directly impact the number of whales the ecosystem can support. [15] Geography Ecosystems at Risk b. Natural and Human-Induced Environmental Stress i. Natural Stress In nature, change tales place slowly. The biome gradually adapts as animal and plant species that have characteristics unsuited to the change die out and those more suited remain, breed and pass on their characteristics. This process is known as natural selection. Throughout history there have been natural disasters that caused whole species to die out instantly because they had no time to adapt. These disasters are, however, rare. Catastrophic Drought Flood Fire Volcanic Eruption Earthquake Landslide Change in Stream Course Disease Natural Sources of Environmental Stress Gradual Climatic Change Immigration Adaptation/Evolution Ecological Succession Disease ii. Human Induced Stress Humans are able to instigate large scale environmental change, pushing dynamic equilibrium beyond its limits. o Damming a river, draining a wetland, clearing natural vegetation for agriculture lost habitat and a destruction of a species The result is that humans have needed to re-establish some degree of dynamic equilibrium by utilizing resources found elsewhere. o Agricultural monoculture (growing a single crop) may lead to the need to add inputs of fossil fuel and fertilizer, pesticides and herbicides. Today human activities destroy or seriously threaten species and more importantly destroy or degrade their habitat. Such activities include: o Industrialisation o Urbanisation o Deforestation o Afforestation o Desertification o Agriculture HSC [16] Geography Ecosystems at Risk The causes of environmental degradation in today’s world are: o Massive population growth o Developing world poverty and the crippling burden of debt o Non sustainable consumption o Environmentally damaging waste generation in the developed world o Non-sustainable agricultural practices in many countries o Environmentally damaging industrualisation o Exploitation of natural resources especially in poor countries struggling for export earnings Effects of Environmental Stress Population Level Community Level Population increase/decrease Disruption of energy flows Change in age structure (old, Disruption of chemical cycles young and weak may die) Simplification Loss of genetic diversity and Reduction in species adaptability diversity Extinction Reduction or elimination of habitats Less complex food webs Human impacts can have a global dimension too when there is an interdependent global environment. Organism Level Fewer or no offspring Genetic defects in offspring Behavioural changes HSC [17] Geography iii. Ecosystems at Risk Human Threats to Biodiversity Species Introduction Hunting Habitat Destruction •Either deliberately or accidentally e.g. exotic species can wipe out local flora and fauna •This disrupts the flow of energy in ecosystems which gets magnified through the food chain •Leads to uncontrolled exploitation of and trade inw ildlife resulting in decimation of species. •Overfishing of herring and cod, leephants targeted by poachers for their ivory •Considered the major threat to biodiversity •Takes several forms: •Outright loss of areas for native species when converted to human use. •Fragmentation and degradation where native species deprived of food, shelter and breeding areas end up being squeezed into smaller and smaller areas. •Major threat to aquatic and land ecosystems e.g. acid rain's impact upon lake ecosystems and forest ecosystems in northern and eastern Europe. Pollution c. Human Induced Modifications to Ecosystems Because people are part of the biosphere, they play a role in maintaining or disturbing the dynamic equilibrium of any ecosystem. HSC Early hunters are believed to have destroyed populations of megafauna across multiple continents. Australian ecosystems have adapted to be fire resistant due to years of Aboriginal fire stick farming. [18] Geography Ecosystems at Risk The planet is an ecosphere that is the amalgamation of a large number of interrelated ecosystems. In turn these ecosystems are made up of a series of smaller interrelated communities. Humans have the ability to simplify natural ecosystems in order to grow food, build habitats and remove or extract resources. The great environmental challenge now facing humans is how to maintain a sustainable balance between simplified human ecosystems and the neighbouring, more complex, natural ecosystems on which the simplified ecosystems depend. Globally environmental damage is extensive. There are massive areas of sever marine and river pollution and radioactive and chemical contamination, as well as a large number of cities with air quality problems. i. Modifications to Natural Vegetation The use of ecosystems by humans is best described as degrees of modification to natural vegetation. Removal Replacement Utilisation •Clearing native vegetation and disruption of ecological processes. •Urban settlement, transport, industrial development and extractive industries. •Native vegetation may be removed and then replaced with intensively managed systems: agriculture, horticulture and plantation forestry. •Utilisation refers to the exploitation of native vegetation, with some consequent degree of modification: forestry (in a native forest), pastoralism and recreation in natural areas. •Pastoralism: raising grazing animals, such as cattle, on large, open grasslands •Conservation involves the maintenance of natural vegetation for conservation and scientific purposes with minimum deliberate modification of natural processes. •National parks, nature reserves, uncommitted governmental land and Aboriginal land are all Conservation examples of conservation. ii. Intentional Ecosystem Change It is not always easy to distinguish between the intentional and unintentional modification of ecosystems. HSC Some intentional modifications result in unintended consequences over the longer term. Aboriginal fire stick farming was intentional, though had an unintentional long term effect on the evolution of Australian vegetation. Some cases are inarguably intentional, like the Kuwait oil fires and the pouring of oil into the Persian Gulf during the 1991 Gulf War. [19] Geography Ecosystems at Risk iii. Change Through Negligence Meeting the needs and wants of humankind and a rapidly increasing human population will inevitably bring about large scale environmental damage. An explosion of population in the biosphere is compensated for by an adjustment somewhere else in the biosphere An increase in grasshoppers will decrease the plants they feed upon, reducing the grasshopper population back to usual. This is an example of dynamic equilibrium. d. Measuring Human Impacts There is no standard measurement except to observe and note changes, though a starting point is necessary. Students May Assess: Lost species i. Loss of habitat Loss of biodiversity Magnitude of Change Magnitude of change is the extent that an ecosystem has been stretched beyond its state of dynamic equilibrium. o It could be a small extent. o Or extremes like totally wiping out the ecosystem. o It may replace an ecosystem e.g. Urban environment. To measure magnitude of change a comparison must be made between known data and a benchmark. ii. Rate of Change Ecosystem change relates mainly to: o Rapid population growth. o Increasing demand for resources disproportionately by the developed world. HSC [20] Geography Ecosystems at Risk Most ecosystem degradation is in the developing world, however it is often the demand for resources by the developed world that has caused a great deal of destruction. Developing countries are forced to rely on the exploitation of raw materials in order to pay for imported goods and repay debts. The technology that enables the exploitation is often supplied by transnational corporations. Forests in developed countries are largely stable or actually increasing whilst deforestation in developed countries is greater than 0.8% per year. e. Population Pressure Population pressure is closely related to the rate of ecosystem change. In developing countries their governments need money to improve diet, health and education through social and economic programs. They then encourage TNC’s to invest in their resources to gain the funds for their programs There are often no environmental controls. The need for money also leads to the giving over of land to cash crops for export. This situation means: The use of damaging inputs like fertilisers and pesticides. Use of irrigation. Loss of prime agricultural land that supported subsistence farmers Even aid programs can be inappropriate and problematic: Permanent water supply permanent settlement of nomadic herders overgrazing and environmental degradation o Irrigation schemes have contributed to salinisation in marginal lands Often developing country governments can look for a quick solution and environmental impacts are not carefully considered. Growing populations need food, access to fuel and water. o In marginal lands the intensification of agriculture and fuelwood collection is causing land degradation and desertification. o Globally almost 11 million hectares of arable land are degraded per year o It takes 100-2500 years to build 2.5cm of topsoil. o Global action is required to reduce ecosystem destruction especially in developing countries with high populations and economic issues. HSC In developed countries a key issue is the short term exploitation of natural resources especially soil. o Crop harvesting removes large amounts of organic matter that would normally decompose and return nutrients to the soil. o This organic material also helps control erosion and nutrient leaching. [21] Geography Ecosystems at Risk o Adding to this is the problem of contamination by chemicals used in the production process. 3. The Importance of Ecosystem Management and Protection The variety of life on earth is of fathomless value. It provides the basis for the preservation of people and the environment. The conservation of the environment is therefore central to the future welfare of the Earth and its inhabitants. There are a range of methods to protect the earth’s biodiversity including: o Setting aside and protecting large areas of wilderness o Preservation of species in zoos o Botanical gardens o Seed banks ( store of seeds from an endangered plant) Unfortunately these steps alone won’t save many species from extinction or from areas being degraded. People need to re-examine their relationship with the biophysical environment and with each other. People need to adopt values, attitudes and practices that are compatible with sustainable development Reasons for Managing and Protecting Ecosystems: Maintenance of Genetic Diversity Utility Value (current and potential) Heritage Value Intrinsic Value The Need to Allow Natural Change to Proceed d. The Maintenance of Genetic Diversity HSC Greater genetic diversity allows for different traits to survive when a species suffers a disaster. A diversity of traits allows for the species to have a greater chance of survival. This process is called natural selection. Ecosystems with greater genetic diversity generally have higher resilience than ecosystems with lower diversity. [22] Geography Ecosystems at Risk Species that can successfully regenerate and adapt are less vulnerable to changes in the ecosystem. Species with high genetic diversity often survive periods of stress because some of the organisms are usually not affected by the change. Up until recent decades people have not had sufficient knowledge of ecological processes. It is expected that 10’s of 1000’s of species are yet to be discovered! Diversity on earth has taken millions of years of evolution. Living diversity is dynamic and increases when a new genetic variation is produced. Living diversity decreases when species decrease, become extinct or an ecosystem is lost Ecologists say that of an estimated 5 - 30 million species currently inhabiting the planet, only 1.4 have been identified. The 1.4 million identified only represent 10% of all species that have actually existed on earth 90% have been lost to evolutionary extinction which causes the loss of about 1 species per year. i. Thylacine The thylacine was the largest known carnivorous marsupial of modern times. It was commonly known as the Tasmanian tiger due to the distinctive stripes on its back. The thylacine was one of only two marsupials to have a pouch in both genders (the male pouch is used to protect the genitals whilst running through thick brush). The thylacine had the appearance of a small to medium sized dog with a stiff tail and a pouch (reminiscent of a Kangaroo). The thylacine possessed a ravenous hunger for livestock and was described as a formidable predator because of its ability to survive and hunt prey in extremely sparsely populated areas. The thylacine was an apex predator that resided at the top of its food chain. The Thylacine was endemic to Australia, Tasmania and Papua New Guinea, though is now believed to have been extinct since 1930. The demise of the thylacine is often attributed to intensive hunting encouraged by bounties, though disease, the introduction of wild dogs, the concurrent extinction of prey species and human encroachment on its habitat are also factors that are believed to have contributed to its extinction. These factors occurred predominantly as a result of European colonisation of Australia. The thylacine is still believed to exist and many sightings have been reported, though none have been conclusively proven. Scientists have been experimenting with museum stored thylacine DNA and are attempting to replicate its DNA sequence and ‘clone’ the thylacine, though these efforts have not yielded any proper success as only a mitochondrial genome was replicated. e. Utility Value HSC All living and non-living elements of the Earth’s ecosphere have existing or potential value or usefulness. This is what geographers refer to as utility value. Examples include: o Sustaining life o Protecting the physical wellbeing of humanity o A source for present and future medicines [23] Geography HSC Ecosystems at Risk o Energy source/supply Australia’s flora and fauna make a substantial contribution to our economy. We gain value domestically and internationally from: o Forestry o The pastoral industry o Fisheries o Tourism o Land reclamation o Beekeeping o Wildflower harvesting o Kangaroo trade There is enormous value in the variety of ecosystems on the planet that can play roles in: o Protecting catchments o Purifying water o Regulating temperature o Regenerating soil o Recycling nutrients and wastes o Maintaining air quality The problems involving maintenance of wild species: o The environments that contain the wild species must be preserved. o Make it worthwhile for subsistence farmers to continue growing traditional varieties so they don’t take up modern higher-yielding strains. Many human diseases are cured by medicines derived from plants, animals and microorganisms. In Australia we have: o 2 species of corkwood that have medicinal value o Hyascine, a plant extract that helps motion sickness, stomach disorders and the side-effects of chemotherapy o The vine Tylaphora – a source of the drug tylocrebrine – effective in treating lymphoid leukemia o A threatened species of frog (Rheobatrachus) found only in QLD has chemical compounds that is useful in treating gastric ulcers In rainforests o Naturally produced chemical compounds in rainforests have protective mechanisms that many organisms rely on to live. o These compounds are a major pharmacological resource. o The loss of even a small amount of rainforest could mean the loss of diseaseconquering chemical compounds. o Medical scientists believe they have only examined about 50 000 of the estimated 250 000 pharmacologically valuable plants in the rainforests. Whilst placing a monetary value on ecosystems could come as a reality check to some who are willing to pay to preserve the ecosystem, it could also deter some when seeing the figure and how much is required to protect an ecosystem. Cash values are placed on biomes based upon the services they provide to humanity. The value of many ecosystem services is however difficult to price. [24] Geography Ecosystems at Risk The scientists behind TEEB (The Economics of Ecosystems and Biodiversity) believe that ‘conservation has to be seen as an investment and not a cost’. Many ecosystems are responsible for recycling moisture, maintain the water cycle, creating soil and performing many other functions vital to life on Earth. These functions have yet to be valued by any ecological economist. The basis for the world’s economy is biodiversity. Everything in the economy is a product of biodiversity and ecosystem functioning. The goal of reducing species loss by 2010 was not achieved. New goals will be set involving stemming the loss of biodiversity, controlling invasive species and conserving at least 10% of all the world’s major biomes. Diversita’s Three Conservation Aims: Aim Colour Protect human safety ad include conserving mangroves to shield coastlines against Red storms, maintaining coral reefs to prevent the loss of local fisheries and preventing deforestation that causes landslides. Protect things that societies value – sacred forests or charismatic species like the great Green whales. Protect key ecosystem services, like carbon sinks in forests, soils and permafrost that Blue help maintain the climate. Coral reefs have such a range in value as the value is based upon the quality of the ecosystem. Prime locations have a higher utility value whereas poorer locations have lower utility value. Scientists might disagree as woodlands play extremely important roles in providing oxygen through photosynthesis and the removal of greenhouse gases like carbon dioxide from the atmosphere. f. Intrinsic Value HSC Ecosystems are endowed with their own intrinsic (naturally occurring) and ethical values. This means they have a right to exist irrespective of their utility value. Whilst most agree that we need to protect ecosystems for the benefit of future generations, there is still no generally agreed mechanism or strategy by which this could be achieved. Central to the notion of intrinsic value is a recognition that the biophysical environment provides for many of the inspirational aesthetic and spiritual needs of people. In an increasingly urban society, aesthetic values make an important contribution to emotional and spiritual wellbeing. By interacting with biophysical elements, humans are reminded that they live in an interdependent natural world. Aesthetic qualities are also valued for their recreational potential. For e.g o Photography o Trekking o Bushwalking o Bird watching o Field studies [25] Geography HSC Ecosystems at Risk The growth of ecotourism is also closely linked to the growing appreciation of the aesthetic and ecological qualities of environments. The links between indigenous people and the biophysical environment are particularly strong. Throughout the world aboriginal people derive spiritual strength from their relationships with the biophysical environment. Traditional aboriginals generally have an ecocentric view. They acknowledge through their behavior and beliefs that they are responsible for the continuity of their world. Beliefs about creation, spiritual and physical existence provide the framework for the way the people live. The intrinsic value taken to the extreme would mean that no, or minimal human uses would take place in an ecosystem. This would assist the long term survival of the ecosystem, though adjacent areas may cause indirect human damage. Intrinsic means having value in existing alone as a natural phenomenon. Intrinsic value is used to signal amenity value – the value in providing pleasure, enrichment or satisfaction. Most ecosystems are inherently useful and frequently regarded by economists as natural capital to become useful at some time in the future. Many different religions’ theologies include an intrinsic value for nature It is hard to put into words the intrinsic value of an ecosystem, it is far easier to experience it. Intrinsic value is related to amenity value. As amenity value is difficult to attach monetary amounts to, it tends to be ignored by economists or business people. Such cultures have viewed the earth as ‘terra matter’ (mother earth), a very different stance from ‘terra nullius’ (no mans land). [26] Geography Ecosystems at Risk Luther Standing bear, Sioux Chief Chief Seattle of the Suquamish tribe JudaeoChristian's new ecotheology The intrinsic worth of certain ecosystems is also enhanced by what we have left as opposed to what has been destroyed. g. Heritage Value Definitions World Heritage Conservation Council: Natural features consisting of physical and biological formations or groups of such formations, which are of outstanding universal value from the aesthetic or scientific point of view. Australian Heritage Commission: Those places, being components of the natural environment of Australia or the cultural environment of Australia, that have aesthetic, historic, scientific or social significance or other special value for future generations, as well as the present community. In Australia the concept of natural heritage is wide enough to encompass both large areas of pristine wilderness and those sites more readily accessible to humans. Education has played a critical role in developing public support for heritage listing. As support has grown additional sites have been added to the list (in some cases, after public controversy arising from a development proposal that would have degraded the heritage values of the ecosystem). Preserving important elements of our natural heritage for the enjoyment and wellbeing of future generations is a responsibility that we must all share. h. The Need to Allow Natural Change to Proceed HSC The multiplicity of life on earth are a product of ongoing evolutionary process. [27] Geography Ecosystems at Risk Many ecologists and environmentalists argue that humans have an ethical responsibility, and selfish rationale, to see that this evolutionary process continues relatively unimpeded. To ensure that this occurs it will be necessary to protect large areas of representative ecosystems. To achieve the desired objectives these areas should Be large enough to protect and conserve intact ecosystems effectively and to allow evolutionary processes to continue. Have boundaries that reflect environmental rather than political needs. Be surrounded by a 'buffer zone' where human ctivity is carefully managed. Take into account the interests of local people. Be well managed and effectively resourced. 4. Evaluation of Traditional and Contemporary Management Strategies Throughout the world there is a growing recognition that people must accept responsibility for protecting and managing ecosystems, especially those considered to be at risk. We now have great knowledge of how we impact upon ecosystems but we also have great knowledge about how to intervene. There is no ONE measure of successful ecosystem management. Any success must be measured over a period of time to ensure they are not part of normal fluctuations in ecosystems. Increasingly, the environmental impact of human activity is being judged in terms of its ecological sustainability. i. HSC Contemporary Management Approaches A management strategy is a plan of attack – a response to a problem and a way to achieve goals and objectives. There are a number of approaches to the way ecosystems are managed. Four broad approaches can be identified: o Preservation o Conservation o Utilisation o Exploitation [28] Geography Ecosystems at Risk Preservation – ‘lock it up’ Refers to the protection of habitat in its existing form. It involves prevention of all human activities in the area being protected. Conservation – ‘Use a little’ On the other hand involves active resource management. It is the planned use of natural resources in an effort to minimise environmental damage. Exploitation – ‘Selfishly use for a profit’ Occurs when an ecosystems resources are used irrespective of ecological consequences. Utilisation – ‘Just use it’ Involves the replacement of an ecosystem with a human made environment that is capable of providing a sustainable yield. Philosophies of Ecosystem Management Radical Environmental Romanticism/ Stewardship Utilitarianism Environmental Imperialism Underpinning the main management approaches are five key attitudes that help us define the relationship people have with the environment. These are: o Radical Environmentalism – This includes a wide range of views ranging from those who advocate the right of all species to survive to those against all development. o Romanticism – A view that values the beauty of nature. Support for the protection of wilderness areas. o Stewardship – This view contends that humans occupy a privileged position in relation to the rest of nature. People have a responsibility to protect and nurture the land for the benefit of future generations. They are custodians. o Utilitarianism – This view is based on the belief that things only have value if they contribute to the happiness and well being of people. o Environmental Imperialism – This egocentric world view holds that everything in nature is subordinated to the needs and wants of humans. Ecosystems are to be exploited for profit. i. Evaluation Criteria Contemporary management approaches focus on the extent to which the strategies adopted promote ecologically sustainable development (ESD). The ultimate measure of ecological sustainability will be higher living standards within the context of ESD. Sustainable development is achieved by maximising peoples economic and social well being while protecting and maintaining the biophysical environment. ESD incorporates four important concepts: o INTRAgenerational equity – All people in the present generation have the right to benefit equally from the Earth’s resources. o INTERgenerational equity – The present generation should not use resources or degrade environments to the extent that it leaves future generations in a worse position. HSC [29] Geography Ecosystems at Risk o The Precautionary Approach – Measure that could prevent serious or irreversible environmental damage should not be postponed due to scientific uncertainty. o Biological Diversity – An essential feature for the evolution and maintenance of earth’s life support systems, as well as having aesthetic cultural value. To achieve sustainable development there are a range of global issues that need collective responsibility. These include: o A reduction in political tension within and between countries. o Provision of adequate food, shelter, clean water, fuel, health care for all people which will reduce exploitation of ecosystems. o Access to education and training. o Initiatives to curb population growth. Monitoring the progress made in addressing global issues provides an indicator to the extent to which ESD is being achieved. Indicators of sustainability include: o Conservation of scarce resources o Species diversity o Prevalence of pests o Ability of the ecosystem to recover from disturbance ii. Minimising Human Impacts on Ecosystems People can implement a range of strategies to minimize environmental impact and to maximise ecosystems. They are measured against ESD and include exclusion, education, restoration, rehabilitation, design and legislation. o Exclusion – Ecosystems at risk are protected by excluding activities likely to have an adverse impact. o Education – Provides opportunity to inform people about an ecosystem, its needs, problems and ways people can minimize their impact. Techniques used to address various types of degraded ecosystems include: o No Action – because restoration is too expensive, previous attempts have failed. o Restoration – of an area to its original species composition by a program of introduction. o Rehabilitation – of some ecosystem functions and some original species. o Replacement – of a degraded ecosystem with another productive ecosystem. o Design – when it is impractical to remove the source of stress, artificial ways must be planned to minimize impacts of stress factor. o Legislation – policies applying to various ecosystems. ii. HSC Traditional Management Traditional indigenous cultures generally have a much closer affinity with the biophysical environment. Their attitudes emphasise respect and coexistence. They believe that they have a responsibility to protect and nurture the land for the benefit of future generations. They see themselves as custodians of the land. As such the philosophy that best reflects them is that of stewardship. [30] Geography Ecosystems at Risk The goals and objectives of their ecosystem management focus on: i. Collection of food. Provision of shelter with respect for the Earth. Respect for the Earth, its fragile nature and the interdependent relationship between people and the environment. Self-sufficiency. Manipulation of Ecosystems They often manipulated and managed ecosystems. Aboriginal Australians built artificial dikes, dug trenches and dammed rivers and used firestick farming. Whilst these practices did not reduce the resilience of ecosystems in some cases they did have long term impacts. o Sustained burning of the bush caused a modification of Australian vegetation. o Aboriginals may have contributed to the extinction of some megafauna. Major degradation has been caused by large scale farming, mining and industrial and urban land uses. ii. Long Term Management Practices Planting of yams back into the holes they came from for regeneration. Resettled bee hives to start new ones. Dug pits which filled with water providing breeding places for frogs. Other Strategies of Management Included: - HSC Restriction of species caught. Closed seasons. Taboos. Designated areas for individuals and groups. Leadership according to age, ecologically sound practices to be handed down from one generation to another. Limits to population growth. Sustainable methods of hunting Traditional societies are generally familiar with the cycles and processes of the ecosystem in which they are living. From tribe to tribe different methods of hunting, gathering, farming and food production highlights that Aboriginals did recognise the unique characteristics of each environment. The intricate knowledge of ecosystems is passed down. [31] Geography Ecosystems at Risk 5. Case Study 1: Intertidal Wetlands a. Introduction For many years intertidal wetlands were considered mosquito infested wastelands. However they are in fact an integral part of marine ecosystems. They have a vital role in the life cycles of aquatic organisms that form the basis of marine food chains. They sustain fisheries and an abundance of other life forms. 2/3 of the worlds fish catch begins in an intertidal wetland. Their still waters protect both eggs and fry (younger newly hatched fish) from strong currents and turbulence. The dense vegetation provides some protection from predators. Examples of intertidal wetlands include: o Mangroves o Salt Marshes Intertidal wetlands are at risk from: o Increasing coastal populations o Being cleared for aquaculture o Reclaimed for new land used in: Agriculture Urban landscapes Industrial areas o Being used as landfill sites b. Spatial Patterns and Dimensions i. Intertidal wetlands develop in coastal areas subject to periodic inundation (flooding) by salty water They are the breeding grounds and habitats for a variety of life and also protect the quality of coastal waters by diluting, filtering and settling sediments, excess nutrients and pollutants. Location Intertidal wetlands are found in coastal areas of tropical regions where: o Air temperature o Wave action o Salinity levels and o Sediment movements Are moderated by the locational features of the estuarine environment. They exist between 32° North and 38 North and 38° South of the Equator. ii. Altitude They exist within the limits of the tidal range. iii. Size, Shape and Continuity The area covered by intertidal wetlands is determined by the limits of the tidal range and, increasingly, by human obstructions and imposed restrictions. HSC [32] Geography Ecosystems at Risk In wetlands the ATMOSPHERE INTERACTS WITH other spheres for example: - The hydrosphere contributes high humidity levels - The lithosphere (soil) contributes to gases eg nitrogen - The biosphere contributes to bacteria which are essential to the creation of hydrogen sulphide gas in the soils Intertidal Wetlands In wetlands the HYDROSPHERE INTERACTS WITH other spheres for example: c. Biophysical Interactions - HYDROSPHERE In wetlands the LITHOSPHERE INTERACTS WITH other spheres for example: - - The atmosphere’s contribution of rainfall, which can alter the salinity level of the wetlands soil. The hydrosphere’s contribution to soil moisture, especially in the mangroves where it is necessary for plant growth The biosphere’s organisms, such as mangrove air-breathing snails, which recycle nutrients. HSC The atmosphere’s contribution of gases that are found in water, especially high dissolved oxygen levels. The lithosphere’s soil movements, which high turbidity present in the water coming into the wetland. The biosphere’s organisms, such as mangrove air-breathing snails, which recycle nutrients. - ATMOSPHERE - - In wetlands the BIOSPHERE INTERACTS WITH other spheres for example: LITHOSPHERE BIOSPHERE - - - [33] The atmosphere’s contribution to the climatic conditions required to support intertidal wetlands. They hydrosphere’s contribution to the slightly alkaline conditions necessary for some plants and animals. The lithosphere’s waterlogged characteristics, which are necessary for the distinctive flora and fauna of the intertidal wetlands. Geography Ecosystems at Risk CHARACTERISTICS OF INTERTIDAL WETLANDS ACCORDING TO THE BIOPHYSICAL ENVIRONMENT Atmosphere Microclimate: air temperature lower in mangroves, and higher in salt marshes, than in surrounding areas. •Minimal wind movement in mangroves; greater in salt marshes. •Humidity is generally high •Gases: hydrogen sulphide asnd nitrogen created. Hydrosphere Water brackish; salinity levels vary with tides and floods. •Water temperature around 5˚ lower than air temperature. •Phosphates higher than in olther water bodies. •Water movement slowed by vegetation. Lithosphere Small soil particle size. •Soil type dependent on region but often a clay mix. •Soil profile, particularly in mangroves, divided into a small aerobic soil player and large anaerobic soil layer. •Composition of soil largely organic. •pH levels acidic in mangroves. Biosphere High fauna diversity; mostly visitors from other sites •Low flora diversity, highly adapted to the conditions. HSC [34] Geography Ecosystems at Risk Any examination of biophysical interactions affecting intertidal wetlands needs to take into account : 1. Dynamics of weather and climate 2. The geomorphic, hydrological and biogeographical processes 3. How the ecosystem adjusts to stress (d.) Precipitation in particular affects the height of the water table - Proximity of fresh water - Soil salinity - Photosynthesis - Respiration - Growth rates - Transpiration The stress of high rfall -> - Rejuvenation - Recolonisation - Spread of wetlands Rainfall variations also affects migratory and sedentary terrestrial fauna in the wetlands HSC Biogeographical Processes Relate to the distribution of plants and animals and e/s DYNAMICS OF WEATHER AND CLIMATE Wetland distribution is largely determined by temperature and rainfall. Geomorphological processes include: erosional and depositional processes and weathering. They modify surface material and landforms GEOMORPHOLOGICAL AND HYDROLOGICAL PROCESSES Rising Sea Level Rise of sea level after the last ice age affected nature and the shape and position of coastlines. The rivers, inlets, estuaries of NSW are a product of this e.g. Sydney Harbour was once just a valley. In some cases previous conditions have more effect on plant distribution than the current. E.g. Mangrove species in North Eastern Australia are linked to the inundation of land bridges to South East Asia. Weathering The intertidal wetland is where large amounts of weathered material accumulate. Grey mangroves produce organic material (around 600 tonnes per year) and all mangroves transfer the organic matter the soil where it provides valuable nutrients and provides a buffer against stress events. Erosion Intertidal wetlands are sheltered by embayment’s that characterise them to accumulation of sediment rather than erosion. Wetlands are designed to absorb flood water to reduce erosion. Erosive power of a storm may overwhelm the protective capacity of the vegetation. The saline nature means the bondage of soil particles are vulnerable to breakage which leads to erosion from physical pressure. [35] Transport & Deposition Given the hydrology of river catchments it is not surprising that the sediment deposited in coastal wetlands tends to be very fine. Over the length of the river system the speed and strength of flowing water has sorted the sediment. Often only the finest sediment makes it to the estuarine environment. The deposition of sediment in the intertidal wetlands ultimately results in the creation of new land. The deposition of alluvial material may be accompanied by the accumulation of toxic pollutants which become trapped in the sediment. Any disturbance to the soil profile can result in the release of these pollutants. Soil Formation Type of soil reflects the parent material, topography, climate and vegetation. Intertidal soils are usually: grey, poorly drained, rich in organic matter. Soils are constantly shifting due to water movements. Geography Ecosystems at Risk d. Adjustments to Natural Stress and the Nature and Rate of Change Affecting the Ecosystem Function i. Stress can be defined as any environmental influence that causes an environmental change, The intertidal wetlands provide a good example of how an ecosystem responds to stress. In the intertidal wetland ecosystem, natural stress includes, but is not limited to salinity and tidal movements. Salinity Intertidal wetlands are located in coastal estuaries (where rivers meet the sea). They receive both fresh water (from rivers) and salt water (from the ocean). They therefore must be able to survive: o Salt water at high tide. o Fresh water at low tide. o Brackish water at other times. The saline water is a very difficult condition for plants to survive in. Plants in intertidal wetlands have many adaptations that help them survive in saline conditions e.g. the many adaptations of mangrove plants. 1. Mangroves Though quite resilient, the grey mangrove is vulnerable to the changes in salinity that occurs through human impacts e.g. altered drainage patterns that change the ratio of salt to fresh water. 2. Salt Marshes The plants of the salt marsh must be able to survive a range of salinity levels in both the soil and water. Plants on lower slopes must be able to cope with being inundated with salt water during high tides. Glasswart (sarcocornia) is a plant that dominates this zone. It accumulates both salt and water to keep the internal ratio low. While this adaptation allows it to cope with salty conditions, it also makes it vulnerable to pollution, as it absorbs pollution dissolved in the water. ii. Tidal Movements Intertidal wetlands are an example of an ecosystem that has stress-dependent organisms and processes. This means that they rely on changes to stimulate biological processes. For example: As the tide recedes, organic material transported from the catchment area is deposited on the roots of the vegetation and floor of the mangrove forest. This organic material is used by crabs, snails and scavengers, which forms the basis of the detritus food chain. The pneumatophores (aerial roots) of mangroves can exist under high tidal water for a short time using gases (oxygen) stored in the roots of the tissue. HSC [36] Geography Ecosystems at Risk If the magnitude or frequency of inundation is changed and the roots are submerged for too long, the mangrove tree can be pushed beyond its threshold limit. Likewise, if substances such as oil cover the pneumatophores, their ability to absorb air will suffer. Intertidal wetlands have features of both aquatic and terrestrial ecosystems. The intensity and duration of the stress is what is important when assessing its impact on the ecosystem. The location of intertidal wetlands means that even healthy ecosystems are vulnerable to changes in the catchment area. e. Human Impacts on Wetlands i. Atmosphere Human modification of the atmosphere in the intertidal wetlands includes the changing of wind patterns caused by the inappropriate location and design of buildings and the construction of walkways within the wetlands. The atmosphere in an intertidal wetland interacts with all three other spheres. These interactions are: Hydrosphere – high humidity levels, which are affected by alteration of water flows Lithosphere – Hydrogen sulphide produced by the waterlogged soils which produced the rotten egg smell Biosphere – contributes gases, especially oxygen ii. Hydrosphere The straightened and mainly concrete lined storm water channel of Powells Creek is an example of the way in which the levels of dissolved oxygen can be altered by modifications to the hydrosphere. Water loses dissolved oxygen when it absorbs heat from the concrete walls and base of the channel. Industrial land uses can increase turbitiy and oil spills are a constant threat. Extensively modified systems are unlikely to transport natural levels of organic material into intertidal wetlands, which can increase concentrations of phosphates from detergents and garden fertilisers. iii. Lithosphere The construction of bund walls can change the hydrology of a site by reducing and redirecting the flow of water. The reduction in flow can affect soil moisture in the mangroves. This has the potential to elevate levels of acid sulphate, damaging the health of the mangroves and adversely affecting the decomposer organisms that recycle minerals essential to the functioning of ecosystems. iv. Biosphere The atmospheric gases necessary for plant and animal growth may be altered by pollution. Interactions between the hydrosphere and biosphere are better understood. The widespread death of marine organisms within these wetlands has been associated with the dumping of toxic chemicals in the catchments waterways. HSC [37] Geography Ecosystems at Risk The alteration of the lithosphere, especially the construction of rock and dirt bund walls, not only alters the pattern of tidal flow but also introduces weeds into the intertidal wetland ecosystem. v. Human Modifications of Intertidal Wetland Ecosystems The use if intertidal wetlands ecosystems by humans can be described by degrees of modification to natural vegetation. Removal: Areas of intertidal wetlands have been cleared to accommodate residential and industrial land uses, transport facilities and waste-disposal sites. Replacement: Areas of intertidal vegetation have been replaced with a managed system of pasture. Utilisation: Salt marshes were modified and exploited as salt pans in the early 1800s, and for recreation in contemporary times. Conservation: The remnant natural vegetation of the intertidal wetland ecosystem has been preserved for conservation and scientific purposes. The deliberate modification of natural processes has been minimised, but there may be indirect impacts from the land use activities on adjacent or nearby sites. Known human disturbances to the energy and nutrient cycles of the intertidal wetland include the introduction of feral animals, the impact of chemicals and altered soil pH on the organisms responsible for nitrogen fixing and recycling as well as the strengthening of the bonds between soil particles. vi. Positive Impacts Impact Explanation Exclusion Those responsible for the management of wetland areas often facilitate public access to a small, designated area while restricting access to other areas. This can be through the provision of defined walkways and boardwalks. Education In the past, intertidal wetlands were often regarded as smelly, mosquito ridden wastelands. Education campaigns have helped to change public perceptions and engender public support for the protection of these highly productive yet threatened ecosystems. Education programs need to embrace a total catchment management approach due to the location of wetlands in the lower regions of catchments. Action Too little is known about the intertidal wetland ecosystem to successfully reinstate all natural conditions. Management can focus on rehabilitation of sites and removal of human-induced stress factors. These can help the ecosystem recover through its own reproduction capabilities. Design Design interventions have proved successful in minimising sources of environmental stress. Hydrologists, for example, have designed structures that maximise tidal flows and maintain the health of the ecosystem. Pollution booms have been designed to gloat on top of the water, where oil accumulates, so that they do not interfere with the free flow of flora, fauna or soil within the water. Legislation Legislation and regulation is used to protect intertidal wetlands. The most significant of these are the Ramsar Convention; the Asia-Pacific regionally based Japanese Australian Migratory Bird Agreement (JAMBA) and Chinese Australian Migratory Bird Agreement (CAMBA); the nationally based Wetlands Policy of the Commonwealth Government of Australia; and the state-based New South Wales Wetlands Management Policy and Environmental Planning Policy 14 on Coastal HSC [38] Geography Ecosystems at Risk Wetlands. vii. Negative Impacts Impact Explanation River River regulation and water diversion is the principal threat to wetlands in NSW. Regulation Dams, weirs and other diversion structures have been constructed on rivers and and Water the timing and volume of river flows have been altered. Many NSW wetlands are Diversion receiving decreased flows of water from rivers and overland runoff. Some wetlands have been completely isolated from the river systems that once nourished them. River regulation and water diversion affect the plants and animals, hydrology, water quality and geomorphology. Development Direct impacts on wetlands from development include clearing of wetlands for and urbanisation and other coastal development, clearing of wetlands for agriculture Catchment and changes in the hydrology and nutrient levels of wetlands. Changes in a Disturbance catchments land use can have profound effects on the functioning of wetlands. Downstream of development there can be increases in the loads of nutrients and suspended solids in waterways, leading to blue-green algal blooms which have profound effects on the food chain. Introduction Weeds and pest animals compete with native wetlands species and habitats and of Weeds and may replace them altogether. Common weeds and pests in coastal wetlands Pest Animals include lantana, salvinia, caulerpa and pigs, which can affect water quality and destroy habitats through digging and wallowing. Weeds and pests in inland wetlands include the introduced plant lippie, pigs and European carp, which can displace native fish in rivers and wetlands. Climate Climate change will affect wetlands and the rivers that supply water to them Change through changes to rainfall and increased temperature and evaporation. This will reduce surface and groundwater supply and put increased pressure on plants and animals that rely on these sources of water. Extraction of water and modification to flow regimes has a considerable effect on biodiversity and combined with climate change the impacts could be much greater. Human induced climate change has been listed as a key threatening process under the Threatened Species Conservation Act 1995. viii. 1. Why Protect the Intertidal Wetland Ecosystem? Maintaining Genetic Diversity The genetic diversity of intertidal wetlands should be valued and protected. Many of the organisms of the intertidal wetland are yet to be identified and recorded. The animals that use the wetlands are for the most part visitors. This means that wetland ecosystems are inextricably linked to many other ecosystems. 2. Utility Value The wetlands have been used in Australia’s past for the production of wood for construction and heating purposes and the harvesting of marine life. Once these resources have been used, the land is often reclaimed for agricultural, industrial and residential purposes. HSC [39] Geography Ecosystems at Risk The land of the intertidal wetlands of Homebush Bay has been used in the past for salt extraction, chemical industries, public utilities such as radio towers and gas lines and as a rubbish dump. 3. Intrinsic Value The intrinsic value of wetlands has often been ignored in the human oriented exploration of these ecosystems for economic returns. The decrease in fish stocks and increase in harmful algal blooms have forced our society to appreciate the unique characteristics of these ecosystems and develop an appreciation of their intrinsic worth. Today wetlands are being protected for their intrinsic value and uses are limited to those who do not exploit or disrupt the components of the ecosystem. 4. Heritage Values Natural areas, including wetlands, are an important part of our natural heritage and can provide an insight into ways people lived in the past, especially their historical or cultural significance to past communities. These also represent a legacy, to be passed on to future generations. 5. The Need to Natural Processes to Continue The area protected must be large enough to allow evolutionary processes to operate as they would in nature. Buffer zones and proper management are required to allow natural processes to continue. Not all wetlands have access to these and some are poorly maintained. HSC [40] Geography Ecosystems at Risk General Impacts of Climate Change IMPORTANCE OF INTERTIDAL WETLANDS Contribute a wide range of ecosystem services. High animal diversity and high productivity. Commercially important fish and crustacean species are strongly linked to the area of mangroves and salt marshes. Boundary of terrestrial and marine environment and thus are regions of high biogeochemical activity. Mangroves have an important role in protecting coasts from storm and tsunami damage. Storms can have a large impact on mangroves, with catastrophic destruction being observed in the Caribbean and Bangladesh, often with slow recovery or none at all. Intense storms can strongly influence surface elevation of wetlands through erosion, deposition and subsurface processes which can influence rates of recovery. HSC Adaptability of Intertidal Wetlands Impacts of Human Induced Climate Change on Intertidal Wetlands Extreme Events (cyclones) Position in the intertidal exposes them to a multitude of ocean and atmospheric climate change drivers which leads to high vulnerability to climate change. Extremely sensitive to sea level rise. Too much flooding will drown mangroves, too little will reduce productivity and may be replaced with salt marsh or cyanobacterial (blue-green) algae communities. The strong regulation of productivity and species composition by soil salinity and humidity in tidal wetlands also makes these ecosystems highly sensitive to changes in rainfall. Southern mangroves are limited by low temperature and thus rises in air and sea temperatures is likely to allow their movement even further south where they will enter salt marsh habitats. Rainfall Changes in rainfall will have a major effect on tidal wetlands. The predicted changes in rainfall with climate change are complex. Increases in intensity are expected, which is likely to influence erosion and other processes in catchments which will affect intertidal wetlands. Despite their vulnerability to climate change the adaptive capacity of tidal wetlands to climate change is also high. We also know that mangrove forests can grow rapidly on newly deposited sediments and that recovery from storms and other disturbances can be rapid. Increasing CO2 CO2 concentrations are expected to double by 2080 with potentially profound impacts on ecosystems. Due to high sensitivity, mangrove forests and salt marshes are likely to be susceptible to increased CO2 Increased CO2 can affect decomposition processes and nutrient cycling in intertidal wetlands. [41] Sea Level Rise Mangroves, salt marshes and salt flats are within the intertidal zone of low energy coasts and are thus highly sensitive to rising sea levels. Geography Ecosystems at Risk i. Traditional and Contemporary Management Practices i. Traditional Management Strategies Indigenous Australians managed wetlands in ways that acknowledged the unique nature of the ecosystem. They used the wetlands as a source of food and, in doing so, took only what was needed to meet their immediate needs. The traditional objectives for the management of wetland areas were built around the use of wetland resources for food, shelter and tools. Grey Mangrove wood, for example, was used to make shields, shells were made into fishing hooks and marine animals were used for food. In the case of Towra Point wetlands, many aspects of traditional Aboriginal management have been lost. There is little/no documentation of sites sacred to the local Aboriginal people such as the Darug. iii. Contemporary Management There are many steps being taken today to manage coastal ecosystems. A growing awareness of the importance as an ecosystem has helped to promote this. Effective Management requires that some of the following guidelines need to be achieved: 1. Management Goals and Objectives Need to be Identified 2. Determination of the Boundaries of the Unit Under Management This can be difficult especially when the nature and movement of some integral components are considered such as water. The wider the boundary the greater the control, but the greater the demand on economic and human resources. It may entail government at all levels. 3. Develop and Implement Management Plans Wetlands are dynamic and so are contemporary attitudes. Today modern society demands the protection and management of intertidal wetlands. Plans must be realistic and flexible. Plans must accommodate scientific and technological advances, changing social and political attitudes. Plans must be consistent with Australia’s international obligations as defined in various international treaties and conventions. 4. Select and Use Ecosystem Management Tools and Technologies Contemporary approaches have benefited from a growing body of international research. This knowledge can be applied to particular wetlands and ecosystems. 5. Clearly Identify Ecological Constrains or Limitations We still have a fairly limited knowledge of intertidal wetlands. HSC [42] Geography Ecosystems at Risk This is not surprising given that it is only in recent years that modern society has become more concerned for intertidal wetlands. Today too little is known of the ecological constraints and limitations of intertidal wetlands. Acquisition of this knowledge is now a high priority. 6. The Collection, Analysis and Use of Economic, Social and Ecological Information This informs the decision making process. Information can be gathered by university research projects, other government institutions and consultants. 7. Be Ecologically Sustainable To be effective management should conform to ecologically sustainable ideals. In turn consideration needs to be given to: i. Sustainable under what conditions ii. Short and long term considerations iii. Precautionary approaches – don’t postpone measures that prevent damage due to scientific uncertainty. iv. Acknoqledge the global dimension – this can be enhanced by sharing data internationally v. Involve the community – include key stakeholders in the management. vi. Education programs – from schools to universities to the general public. vii. Environment Impact Assessment – a legislative framework that assesses the potential impact on the wetlands. j. Mangroves A mangrove is a salt-tolerant plant or plant community that grows between the land and the sea where the mud is regularly covered and uncovered by the ebb and flow of the tide. HSC The greatest species diversity occurs in tropical and subtropical regions, nut they can grow further south. They grow successfully on mud flats, which is a difficult environment because of the high salinity and low oxygen. The soft sediment is a mixture of fine alluvial silt, decaying mangrove leaves, washed up sea grass and material brought downstream by rivers. Some species have special roots, called pneumatophores, projecting up out of the mud to get oxygen from the air and water. The mass of above ground roots and the soft, muddy soil make mangrove forests very difficult for large animals (and humans) to penetrate. Small seaweed and microscopic algae grow on the surface of the mud. The algae, together with decaying mangrove leaves, support a rich and diverse animal community. Crabs feed on the organic particles in the mud; oysters attach themselves to mangrove roots and filter small organisms from the water; and wood boring molluscs bore holes into fallen logs and feed on the wood. [43] Geography Ecosystems at Risk The richest mangrove communities occur in areas where the water temperature is greater than 24°C in the warmest month and where annual rainfall exceeds 1250mm. Distribution of Mangrove Wetlands in Asia and Southeast Asia 60 40 20 Area (100000ha) 0 HSC They also need protection from high energy waves, which can erode the shore and prevent seedlings from becoming established. Different mangrove species have different requirements. Some are more tolerant than others. Other factors that affect their distribution include: o Wave energy o Soil Oxygen levels o Drainage o Differing nutrient levels Where one species finds its preferred conditions – or at least those which it is able to tolerate better than other plants – it tends to become dominant. Worldwide there are 181000km2 of mangroves, approximately 43% of which are located in just four countries: o Indonesia o Brazil o Australia o Nigeria [44] Geography Ecosystems at Risk Global Distribution of Mangrove Wetlands East Africa and the Middle East Australasia West Africa The Americas South and Southeast Asia Management decisions taken in these countries will have a significant effect on the global status of mangrove ecosystems in the future. Over million of years, mangrove species have developed a range of adaptations that allow them to cope with constantly changing environmental conditions, high levels of salinity and a lack of oxygen. In addition to the ebb and flow of the tide, which inundates the mangrove community with salty water, the mangroves must cope with floods of fresh water, especially during periods of high rainfall. Apart from altering the salinity levels, these fluctuations can alter water temperature. Being salt tolerant allows mangroves to dominate in a saline environment free of competition. The characteristics that enable mangroves to tolerate high levels of salinity include: The Ability to Secrete Salt The Ability to Exclude Salts The Ability to Store or Concentrate Salt HSC •This occurs through special glands, which are usually found on the leaves, where tiny white flecks of salt are frequently visible. •This is achieved by root based cells that prevent the larger salt ions from entering, and take in the smaller water molecules. •Some species can exclude 90% of salt in this way. •This is usually done in the bark or older leaves, which are an 'expendable' part of the mangrove plant. •Eventually, the leaves and bark fall off, taking the excess salt with them [45] Geography Ecosystems at Risk Some mangrove species use only one of these methods, but many use two or more. In addition, mangroves have a number of features that help to minimize water loss from the plant. These include thick, waxy leaves or dense hairs that reduce transpiration. Most water loss occurs through the stomata (pores in the leaves). These are indented below the leaf surface where they are protected from drying winds. The leaves of many species are able to store water in fleshy internal tissue. Mangroves have adapted to the anoxic (oxygen deficient) soil conditions by developing ways to obtain oxygen necessary for root metabolism which include: Pneumatophores •These are special types of root which grow upwards from the main root system to absorb oxygen from the air at low tide via special tissue called lenticels. •When the roots are submerged in water, the pressure within the tissue falls as the stored oxygen is used by the plant. •As the root is exposed at low tide, more air is drawn in through the lenticels. Stilt or Prop Roots •These are another type of aerial root which grow from the trunk and lower branches of the mangrove. •These lenticel covered roots enable the mangrove to absorb oxygen, with the added bonus of supporting the mangrove in unstable sediments. HSC There is always a danger that the breathing roots of the mangroves may become covered as sediments accumulate. To avoid being buried, the pneumatophores grow vertically. Mangroves have also developed specialised forms of reproduction. In common with many terrestrial plants, mangroves reproduce by producing flowers and relying on pollination by bees and insects. Once pollinated, however, the seed remains on the parent plant where it germinates and grows stems and roots before being dislodged. Once in the water they travel horizontally and on reaching the brackish water they turn vertically, making it easier for them to lodge in the mud. Once lodged in the mud they quickly produce additional roots and begin to grow. This gives the young tree a better chance of not being swept away by the ongoing tide. The production of live seedlings (known as vivipary) is very rare in plants other than mangroves. Other species of wetland plant release their seed inside a capsule. The capsule floats until it is deposited in a suitable location, germinates and sends out roots. [46] Geography Ecosystems at Risk k. Salt Marshes Salt marshes are coastal wetlands that are flooded and drained by salt water brought in by the tides. Along intertidal shores in middle and high latitudes throughout the world, salt marshes replace mangrove swamps as the dominant type of coastal wetland. They are found on all continents other than Antarctica. A salt marsh is an ecosystem, that is integrally part of a bigger system, that of estuarine or intertidal wetlands. The herbs, grasses, reeds and low shrubs in salt marshes are terrestrial in origin and are essential to the stability of the salt marsh in trapping and binding sediments. Salt marshes play a large role in the aquatic food web and the exporting of nutrients to coastal waters. Salt marshes are inhabited by oysters, crabs and prawns. They also contain a large number of birds that stop over in the course of migration. The distribution of salt marsh is within a vegetation zonation which depends on elevation and hydrology. In Australia, when salt marshes and mangroves coexist, saltmarshes are typically found at higher elevations where they are inundated less frequently than mangroves. When seagrass beds are found adjacent to salt marshes and mangroves, many material links and shared plant and animal communities can exist. The most common site for a salt marsh, after estuaries and lagoons, is the sheltered side of a sand spit. As plants colonise the area, they slow down the flow of water and cause additional silt to accumulate. The soil in salt marshes is often composed of deep mud and peat. Peat is made of decomposing plant matter that is often several feet thick. Peat is waterlogged, root-filled and very spongy. Because salt marshes are frequently submerged by the tides and contain a lot of decomposing plant material, oxygen levels in the peat can be extremely low. The sediments contain numerous bacteria which produce the sulfurous rotten egg smell that is often associated with marshes and mud flats. Salt marshes are extremely productive ecosystems, but they are not very diverse. The inner marsh zone, which is flooded most of the time, is composed almost entirely of sedge-type plants. Gradually, however, the grass-dominated community of plants and animals is replaced by more complex communities that are finely tuned to the variations in salinity, alternate drying and submergence, and extreme daily and seasonal temperature variations. Diversity within the marsh tends to increase with distance from the zone of inundation. Only a small percentage of the salt marsh vegetation is eaten by animals. The rest dies, decays and becomes suspended as fine particles (detritus) in the water. Most of the nutrients produced are recycled within the marsh. Adaptations HSC [47] Geography Ecosystems at Risk Oxygen in the water in the soil is used up, often by the activity of decomposers like bacteria. Marsh plants have air spaces in their stems which allow oxygen to move from the leaves to the roots. They generally have thick roots with a corky layer and without root hairs. Other marsh plants are able to survive in low oxygen conditions by relying on anaerobic respiration (respiration that does not use oxygen). 6. Towra Point Nature Reserve a. Spatial Patterns and Dimensions Towra point is located between 151°8’0” E, 34°1’40” S and 151°12’30” E, 31°0’0” S Towra Point Nature Reserve is located on the southern shore of Botany Bay about 16 kilometres from the Sydney CBD. Towra Point Nature Reserve covers an area of 603.7 hectares and the area of the Ramsar site is 386.5 hectares. b. Biophysical Interactions HSC [48] Geography Ecosystems at Risk The above map shows the distribution of mangroves, salt marshes, terrestrial vegetation, beaches, sand spits and freshwater wetlands at Towra Point Nature Reserve. i. Mangroves Two species of mangrove can be found at Towra Point Nature Reserve: The grey mangrove (Avicennia marina) which has a large number of pneumatophores allowing it to breathe. The river mangrove (Aegiceras corniculatum) which, along with the grey mangrove, has the ability to excrete salt out of its leaves and change salt water into fresh. The leaf litter provided by the mangroves creates detritus which feeds the smaller organisms in the ecosystem, which are in turn eaten by increasingly larger organisms. Mangroves in Towra Point Nature Reserve perform a number of important functions: Reduce water pollution. Provide shelter, refuge and food for many forms of wildlife. Prevent bank erosion. Act as nurseries for fish species. A number of forms of wildlife can be found in the mangroves of Towra Point Nature Reserve: Shore crabs (which are abundant in the mangroves and live in complex networks of tunnels buried in the sand) Birds (such as herons, egrets, spoonbills and ibises) ii. Salt Marshes There are over 10 species of salt marsh plant in Towra Point Nature Reserve, existing in areas that are subjected to both tidal and freshwater inundation. Glasswort is the most common of these plants. The terrestrial boundaries of the salt marshes are covered in the brackish water reed Juncus krausii. Salt marshes appear as open plains dotted with the occasional mangrove. The tidal inundation and rainfall help to form standing pools of water. Some areas are inundated regularly whilst others are only inundated occasionally Salt marshes cover 100 hectares of Towra Point Nature Reserve and are the last remaining in the Sydney region. iii. Rainforests Rainforests in Towra Point Nature Reserve are home to a number of plant species including: HSC Magenta brush cherry (Syzygium paniculatum), a vulnerable species found in small groves of littoral (relating to or situated on the shore) rainforest. Lilli Pilli (Acmena smithii) which supplies food to a number of birds such as rosellas and lorikeets. Ferns can be found in the understorey layer. An invasion of lantana is making it a struggle for seedlings to grow. [49] Geography Ecosystems at Risk iv. Sand/Mud Flats The sand flats are of particular importance for a number of species of waterfowl and migratory birds and have large numbers of molluscs, polychaetes (segmented worms) and small crustaceans. The mud flats of Quibray Bay are also popular as a feeding area for birds. v. Freshwater Wetlands The Reserve has a number of freshwater wetlands and ponds including Weedy Pond and Towra Lagoon. Weedy Pond is a small attractive pond which is fringed by casuarinas and often remains dry for long periods, filling after periods of heavy rain. Weedy Pond is also surrounded by a pocket of littoral (relating to or situated on the shore) rainforest. Towra Lagoon is the largest fresh water wetland in the Reserve and once supported three species of dabbling duck and the endangered green and golden bell frog. However, due to saltwater incursions from Botany Bay, these birds are rarely seen in the lagoon. The eastern-long necked tortoise was also an inhabitant of this lagoon but is intolerant of any salt and has also disappeared (along with the frog). vi. Seagrasses The waters around Towra Point support meadows of seagrasses predominantly: Eelgrass (Zostera) Strap weed (Posidonia) Paddle weed (Halophila). Seagrasses grow below the low tide level in the sheltered shallow waters of estuaries and are flowering plants that generally prefer soft sediments like sand or mud. Seagrasses are restricted to waters no deeper than two metres due to their need for light. Seagrasses are important as habitats for small aquatic animals and also provide feeding and nursery grounds for fish and give shelter to juvenile and small adult fish and invertebrates such as prawns and crabs. Seagrasses provide nutrients in the form of detritus, which contributes to the nutrient cycling of Botany Bay. vii. Forests 1. Casuarina Forest Another plant community found at Towra Point Nature Reserve is the Swamp Oak forest which is characterised by tall Casuarina glauca (swamp she-oak) trees as well as a species of Melaleuca ericifolia (swamp paperbark). Casuarinas have fruits which attract seed-eating parrots. The casuarina forest is the first above the influence of the tide. 2. Dune Sclerophyll Woodlands These forests occur on the shoreline and are characterised by Teatree and Coast Banksia. The woodlands are inhabited by a number of weeds which inhibit the regrowth of these forests. HSC [50] Geography Ecosystems at Risk viii. Importance Towra Point Nature Reserve was listed as a Ramsar site under the Ramsar Convention in 1984 as it meets a number of the nomination criteria: Towra Point Nature Reserve supports three threatened species – grey headed flying fox, magenta Lilli Pilli and green and golden bell frog. Towra Point Nature Reserve is an important area for maintaining the biodiversity of the Sydney region. It is also one of the most important migratory bird sites in NSW and is a breeding ground for the endangered little tern Towra Point Nature Reserve provides critical roosting and feeding habitat for migratory shorebirds and supports the little tern and a number of species of juvenile species. Towra Point Nature Reserve is a significant habitat and food source for at least 60 species of fish. Towra Point Nature Reserve contains the last remaining tidal wetlands in the Sydney region as most of the wetlands that existed prior to European settlement have been reclaimed for housing, recreation and industry. Towra Point Nature Reserve holds around half of Sydney’s remaining mangroves and most of the remaining salt marshes. c. Human Impacts i. Erosion Dredging in Botany Bay has increased wave energy and accelerated erosion along sections of Towra Beach. Offshore breakwalls and sand nourishment have been suggested as solutions. The water in Towra Lagoon has become brackish. ii. Weeds The vegetation at Towra Point Nature Reserve has been subjected to clearing and burning for agricultural and grazing reasons since the 1860’s, leading to extensive invasion by weeds including lantana, bitou bush and African boxthorn. iii. Horse Riding Horse riding leads to trampling and disturbance of soil and vegetation and the spread of weeds, as well as causing disturbances to birds. A major management problem is that the horse stables are located close to the entrance to the Reserve. iv. Boating Boat chains, anchors and jet skis cause damage to seagrasses and disturb wading birds. v. Feral Animals Feral animals, such as foxes, pose a threat to the breeding sites of the Little Tern and all other fauna found on the reserve. The best Little Tern breeding site on Little Tern Spit may become connected to the mainland, causing difficulties with the control of feral animals. HSC [51] Geography Ecosystems at Risk vi. Fragmentation Not all of the Towra Point Nature Reserve is owned or managed by the National Parks and Wildlife Service. A number of private stakeholders including developers own portions of the Reserve, as can be seen on the map below (privately owned areas are yellow). The disjointed land ownership creates problems when horses and trail bike riders gain easy access to the Nature Reserve and other areas of high conservation significance through nonNPWS land. vii. Development and Construction Development and erosion have caused significant losses to seagrasses and erosion has been attributed to nearby dredging. Dredging for construction has led to considerable erosion. d. Traditional and Contemporary Management Strategies i. Traditional Management Towra Point Nature Reserve was of great importance to the Aboriginal Communities who lived in the surrounding areas. The area was rich in seafood, providing for the needs of the local people and was also a source of fresh water. Three middens remain today and show that the local Dharawal people used the area for its resources. Captain Cook mapped the Botany Bay area in 1770 and also mapped Towra Lagoon, making it a key historical site in the reserve. Towra Point Nature Reserve was used as land for sheep grazing by Thomas Holt, an early European settler, and was also the home of the first oyster farm. Early settlers copied the Aboriginal peoples use of plants and also used the area for food. Industrial land uses adjacent to Towra Point Nature Reserve remove resources from the wetland, increase turbidity and toxins in the water supplied to mangroves and changes in nutrient and energy cycles and the food chain. Adjacent land uses include: HSC Airport Crude oil importing port [52] Geography Ecosystems at Risk Oil refinery Container port These land uses can threaten the ecological character of Towra Point Nature Reserve. ii. HSC Contemporary Management As can be seen on the map in the above section, a large portion of Towra Point Nature Reserve is privately owned and managed. The rest is managed by the National Parks and Wildlife Service and has been since 1982 for the purpose of conservation of wetlands and migratory birds. The National Parks and Wildlife Service have placed restrictions on access to minimise the amount of damage caused by humans. Horses and dogs are not allowed in the reserve and a permit is required before entering the reserve. As well as nature conservation, the Reserve provides opportunities for environmental education and scientific research and students from a number of institutions regularly visit the reserve. The Towra Point Aquatic Reserve is managed by NSW Fisheries. The establishment of an Aquatic Reserve was designed to protect the highly significant marine habitats that surround the Nature Reserve (e.g. seagrasses) by placing restrictions on fishing and prohibiting bait gathering. More than 200 fish species have been recorded in the Aquatic Reserve. This diversity can be attributed to the abundance of different habitats, particularly for juvenile fish NSW Fisheries have defined two distinct management zones within Towra Point Aquatic Reserve. These two zones, seen on the map, are the Sanctuary Zone, and the Refuge Zone. The Sanctuary Zone is for observation only. Disturbing, interfering with vegetation or removing fish is not allowed in this zone. In the Refuge Zone some fishing is allowed. [53] Geography Ecosystems at Risk 7. The Great Barrier Reef A reef is a marine ridge that is located close to the surface of oceans and seas. It consists mainly of living coral, compacted coral skeletons and other organic material that consolidate into limestone. Coral reefs cover only an estimated 0.17% of the ocean floor. However their importance cannot be underestimated: o Reefs provide a habitat for approximately 25% of all marine species o Coral polyps absorb carbon dioxide as part of the carbon cycle o Reefs act as natural barriers to erosion by reducing wave energy o Coral reefs build atolls, beaches and islands which are ecosystems a. Spatial Patterns and Dimensions i. Location and Altitude They occupy less than 0.1% (284 300km2) of the world’s ocean surface Though they provide a home for 25% of all marine species Although corals exist in both temperate and tropical waters, shallow-water reefs form only in a zone extending from 30° N to 30° S of the Equator The optimum temperature for most coral reefs is 26-27°C and few reefs exist in waters below 18°C The Great Barrier Reef is in the Coral Sea, on Australia’s north-eastern coast It stretches more than 2300 km from o 8 S at PNG’s Fly River to o 24°07’ S at Fraser Island, north of Bundaberg ii. Size The GBR is composed of 2900 individual reefs including: o 750 fringing reefs attached to the mainland and offshore islands o 2150 outer reefs The reefs range in size from a few 1000m2 to up to 120km2 The GBR ecosystem also includes approximately 600 islands Of these, 250 continental islands and 70 coral cays are named on maps The Great Barrier Reef Marine Park covers an area of 348 700km2 iii. Shape The GBR has many different shaped reefs within it, from narrow ribbon reefs to wide platform reefs iv. Continuity The current Great Barrier Reef has existed for approximately 8000 years Around 10 000 years ago the polar ice from the most recent ice age began to melt, causing sea levels to rise Coral growth responded to the rise of sea levels and as the sea rose, the reefs grew As the sea levels dropped, the coral died off and turned into limestone This formed the base for the current coral to develop on HSC [54] Geography Ecosystems at Risk b. Biophysical Interactions i. The Role of the Atmosphere GBR lies within Australia’s cyclone zone Tropical cyclones have shaped the ecosystem Cyclones damage corals as a result of large storm waves Waves rip apart softer corals and chip hard corals Cyclones may bury the reef system in sediment They can also alter salinity and turbidity Cyclones can also remove accumulated sediment and reduce the temperature of the reef ii. The Role of the Lithosphere Reefs produce solid limestone from the remains of coral polyps Limestone is weathered and redistributed to create new landforms Limestone allows reef systems to withstand the erosive power of waves Sediments can create turbidity and reduce the amount of penetrating light, interrupting the process of photosynthesis iii. The Role of the Hydrosphere Coral reefs grow best where there is high wave energy Reefs are very effective at interfering with wave energy Water flow tends to be towards the north for most of the year Summer monsoonal conditions result in a reversal of this pattern The warm, highly saline waters that flow down bring relatively high nutrient levels iv. The Role of the Biosphere More than 300 species of coral are found in the GBR Greatest diversity in the northern section of the reef Although predominantly rock, made of living polyps Primitive organisms that consist of digestive sack and outer skeleton of limestone Within the polyp live a symbiotic algae called zooxanthellae. Mutually beneficial to each other Zooxanthellae algae give corals their brilliant colours Polyps reproduce to create a colony The colony expands the reef upwards and outwards Polyps die, limestone remains to form base for new coral Coral release eggs in spring Constant recycling of nutrients Thousands of species of fish Predators attracted by fish Large numbers of cnidarians (invertebrates – coral and jellyfish), molluscs and crustaceans Echinoderms Sea birds are important HSC [55] Geography Ecosystems at Risk The Environmental Requirements for Optimum Growth of Corals: Depth of Water Corals thrive in water 2-30 metres deep. This allows photosyntehsis by the zooxanthellae Warm Water Low Sediment Levels 20-35°C 26-27 is optimum for limestone build up. If corals are blanketed by sediment they will die High Oxygen Levels Clear Water Corals like areas where water is continually oxygenated by waves e.g. on the outer edges of the reef With low nitrogen, phosphate and ammonium. Phosphates interfere with skeletal development. Constant High Salinity They will die with fluxtuations in salinity HSC [56] Geography v. 1. Ecosystems at Risk Biogeographical Processes Rates of Reef Growth In the southern section of the GBR the reefs grow slowed due to the colder water Slow growing corals often use chemical warfare against fast growing corals to ensure their existence Vertical zones exist: o Some species tolerate low light conditions and are found in deeper water o At depth growth rates are slower 2. Resilience The high rate of biodiversity in the Great Barrier Reef ecosystem allows the reef to cope with significant change e.g. cyclones Some changes cannot be adjusted to because of the high rate of specialization in the GBR ecosystem e.g. rise in water temperatures All corals are adversely affected by an increase in temperature Its low elasticity means it may not return to pre-stress levels for a long time 3. Coral Spawning They spawn in late summer on the night after the full moon Water temperature, light, moon cycle and tidal cycle have to be right The annual synchronised mass spawning of corals is considered an amazing biological event. The polyp larvae depend on tides and currents Towra Point Nature Reserve distribute them in favourable colonisation areas 4. Ecological Succession Every 15 years a cycle has developed that the Crown of Thorns starfish has a population explosion This is a result of many factors: o Increase in algae blooms because of use of fertilisers o Collection of predators (notably the Giant Triton) o Cyclones This predator when in plague proportions can wipe out entire reefs When not in plague proportions the Crown of Thorns promotes biodiversity and ecological succession c. Nature and Rate of Change Affecting the Ecosystem Functioning i. Natural Impacts 1. Impact of Sea Levels on The Great Barrier Reef HSC a. The Nature of Change Reefs grow when sea levels are high and die when sea levels are so low that they are exposed Historically, sea levels stabilised at the present level around 6200 years ago. [57] Geography Ecosystems at Risk The modern Great Barrier Reef started growing between 8000 and 8500 years ago over older reef structures. Scientists have drilled and have discovered that periods of reef growth and decline are linked to the rise and fall of sea levels. b. The Rate of Change Over the past hundred years, Australian seas appear to have risen an average of 12 to 16 centimetres. Global warming may be a cause, but earth movements can also cause rises and falls in sea levels. If the rate of sea level change occurs slowly in the Great Barrier Reef, its corals may be able to keep growing to keep pace with the rising water levels. But if the sea level changes occur rapidly in the Great Barrier Reef, its coral may not be able to grow fast enough and there may be destruction in some areas 2. Crown-of-thorns Starfish Infestations a. The Nature of Change The crown-of-thorn starfish is considered a boom or bust organism (i.e. an organism that is either found in small numbers or plague numbers). The crown of thorn starfish alters the reef by eating the coral polyps. When it is in plague proportions it severely alters the Great Barrier Reef by damaging it and creating conditions for other organisms to invade the reef b. The Rate of Change Scientists have found that there have been periodic infestations of crown-of-thorn starfish during the past 6000 and 8000 years. Therefore some see the outbreaks as a natural phenomenon. Some believe that the starfish help regulate the overgrowth of coral. However, in recent times the outbreaks have occurred more frequently. Some argue this is due to human induced modifications to the Great Barrier Reef ecosystem through such things as: o Shell collectors removing the starfish’s predators (crabs love eating the starfish) o Sediment runoff from eroded banks caused by humans o Excessive nutrient runoff from farms that flow into rivers and out to sea. o Overfishing, trawlers catching many unwanted species as part of their by catch which may remove many natural predators of the starfish when they are in their larvae stage. The problem with the change of rate is that the coral in the Great Barrier Reef has low elasticity (rate of recovery) sometimes it takes 12 to 15 years for coral to reach its pre infestation levels. If reinfestation occurs within the elasticity period it could alter the Great Barrier Reef significantly HSC [58] Geography Ecosystems at Risk 3. Tropical Cyclones a. The Nature of Change Cyclones can destroy reefs through the creation of large waves Can increase sediment and turbidity levels Can bury corals or remove accumulates sediment Can decrease salinity b. The Rate of Change Over 142 cyclones occurred between 1909 and 1992 Cyclones and their effects are in effect immediately ii. Human Impacts 1. HSC Climate Change Climate change has a number of impacts in Northern Australia: o Increase in sea surface temperatures o Increase in sea levels o Change in rainfall patter o Changes to ocean currents and circulation o Increased El Nino events o Increased Carbon Dioxide (CO2) levels Ongoing climate change will have many different consequences for the Great Barrier Reef Climate change directly impacts: o Fish o Invertebrates o Birds o Mammals o Aquatic and Terrestrial Plants o Root functioning Climate change alters sea temperature and will affect the movement of water in ocean currents Ocean currents act as a part of the nutrient cycle in the reef ecosystem More dissolved CO2 results in a change in the chemical structure of the water Sea birds are already declining Failure of eggs to hatch has occurred in a number of rookeries of seabirds Fish species are also in danger Climate change will affect location, frequency and timing of nutrient upwellings Upwelling’s are ocean currents that bring nutrients from the sea floor upwards They attract fish and in turn attract predators such as sharks and dolphins [59] Geography Ecosystems at Risk 2. Boating and Commercial Shipping Recreational boating is a common pastime on the reef. On any day of the year thousands of small craft can be observed fishing, sightseeing and sailing up and down the length of the reef. While for humans those waters represent a relatively safe boating paradise the boats have the potential to damage the reef ecosystem. When boats anchor, the heavy metal anchors damage the reef’s coral formations and dredge up the sea grass beds. The boats are also a source of pollution through oil and fuel spills, rubbish and sewage. Careless boat owners vent their sewerage systems while a sea, releasing raw sewage into the water. When hundreds of boats do this the impact is considerable. The Great Barrier Reef Marine Park Authority estimates that around 6000 large commercial ships transit through the Great Barrier Reef each year. These ships carry everything from grain, minerals, bulk cargo (such as cars) and oil. Fortunately there has not yet been a major oil spill on the reef. However, with such a large number of ships the potential for a major spill is very real. Ships also bring with them rubbish and small slicks associated with leaks. The ships also have the potential to introduce feral aquatic species by releasing ballast water. This is water used to balance the ship: water is no longer needed. Small animals and plant species can be transported across the oceans in this way. 3. Overfishing Commercial fishing has long been an important economic activity for Queensland’s coastal communities. Unsustainable fishing practices in the past have left many areas with depleted fish stocks and it is important that these areas are now managed sustainably. While many areas of the reef are today off limits to commercial fishers, various areas of the reef can still be fished. Local fishers are no longer a major threat to the reef as they understand the need to protect the area’s fish stocks. However, the reef remains threatened by illegal fishing, which is often carried out by foreign fishing trawlers, and by unsustainable recreational fishing. 4. Tourism a. Importance Tourism is one of Northern Queensland’s most important industries Worth over $4 billion each year, the GBR is a tourist attraction of international importance b. Impacts of Tourism There are six main ways of categorising the impacts of tourism on the reef: o Coastal Dune Development Most visitors stay in hotels and resorts along the coast of the mainland. This places stress on coastal environments e.g. estuarine ecosystems o Island-Based Tourism HSC [60] Geography Ecosystems at Risk o o o o 5. The encroachment of tourism and associated development onto the reef’s surrounding islands poses risks, especially those associated with sewage and rubbish discharges Marine-Based Tourism Tourist boats make thousands of journeys out to the reefs each year These boats bring with them rubbish and the potential for oil spills They also require mooring areas, usually located on outer reefs, which destroy the coral as does the dropping of anchors Water-Based Activities Diving and snorkeling are popular and most divers are careful A small proportion of divers break coal as the fragile branches are especially susceptible Wildlife Attractions Most operators do not allow their customers to get too close to wild animals Some careless operators and tourists disrupt wildlife and impact on breeding and natural interactions Other Impacts Trampling of coral (walking along reefs at low tide is now illegal) Taking souvenirs of coral, shells etc. (also illegal) Land Clearing There are 26 major river systems that flow from mainland Queensland to the GBR 25% of the land area of QLD is drained onto the reef This runoff represents urban and agricultural development and aquaculture Development of urban zones adjacent to coastal areas is expanding rapidly This places pressure to clear land in order to accommodate the expansion Due to this, surface runoff is increased dramatically The GBRMPA noted that the clearing of wetlands has encroached on the sustainability of the reefs Estuaries provide nursing for many reef species 6. Agriculture Aquaculture is a popular commercial farming activity in ponds near the GBR It includes the commercial manufacture of: o Several fish species o Pear o Edible oysters The aquaculture farms can release chemicals and diseases impacting on natural species Conventional agriculture: The coastal plain adjacent to the reef has been of a constant concern for reef and marine biologists Use of chemical fertilisers increases nutrients that lead to algal growth Algae smothers the reef and reduces light penetrations Land clearing removes vegetation cover resulting in erosion, increasing turbidity and smothering corals HSC [61] Geography Ecosystems at Risk d. Human Impacts Climate Change Boating and Commercial Shipping loss of species oil spills Overfishing HUMAN THREATS TO THE GBR dredging and sandmining Tourism land clearing sewage agriculture Human Impact Climate Change HSC Effect The El Nino effect is considered to be the primary culprit in the increase in water temperatures that have begun to strike the Great Barrier Reef with increasing frequency. The impact of coral bleaching is just one of the ways in which higher temperatures affect the reef. Climate change in general is believed by many prominent biologists to be a massive threat to the reef’s future, predicting its gradual decline until it becomes practically extinct by the year 2030. A temperature rise of 2-3 degrees is believed to put 97% of the reef in the danger zone of bleaching every year. The rise in levels of atmospheric greenhouse gases are believed to be another significant factor – particularly carbon dioxide, which if it rises to a level of 450ppm, [62] Geography Boating & Commercial Shipping Overfishing Tourism Land Clearing Agriculture Sewage Dredging & Sandmining HSC Ecosystems at Risk will put coral and reef habitats in an extremely vulnerable position. Recreational boating is a common pastime on the reef. The reef represents a safe boating paradise, though the boats have the potential to damage the ecosystem. Anchoring damages coral formations and sea grass beds. The occurrence of collisions and groundings leave an immediate and drastic effect on the ecosystem as debris and other objects enter the water and remain there for a long period of time. 6000 large commercial ships transit through the Great Barrier Reef every year. Reefs are suffering directly and indirectly from the increasing pressure of man’s resource exploitation. Overfishing is one driving pressure that has had devastating impacts on coral reefs. Aggressive fishing methods have hurt coral reefs sometimes beyond repair. However, over-fishing in general is also a damaging problem to many coral reefs around the world. Specifically to the Great Barrier Reef, overfishing has caused a shift in the reef ecosystem. Overfishing of certain species near coral reefs can easily affect the reef’s ecological balance and biodiversity. While many areas, techniques and species of marine life in the reef are protected by law, trawling for various types of permitted sea life inevitably leads to other species getting caught in the nets as a side effect. Tourism has five broad impacts on the reef: Coastal tourism development – Most visitors stay in hotels and resorts, which strain coastal environments including estuaries. island based tourism – The encroachment of tourism and associated development on the reefs islands poses risks marine based tourism – Boats make thousands of journeys on the reef each year, bringing rubbish and potential oil spills water based activities – A small proportion of divers break corals, especially fragile branching corals Wildlife interactions – A small proportion of careless operators and tourists interrupt wildlife, impacting natural interactions Other impacts – Trampling of coral and souveniring of coral are both illegal, though still performed 26 major river systems flow from mainland Queensland into the Great Barrier Reef, covering 25% of the area of Queensland. This runoff represents a major threat to the reef as agriculture, urban development and aquaculture all affect the quality of the water that flows into the Coral Sea. Expanding coastal developments have an increased surface runoff which brings more nutrients and sediments to the reef and increase sewage and pollution. 80% of the land adjacent to the Great Barrier Reef is farmland that supports agricultural production, intensive cropping of sugar cane and major beef cattle grazing. Fertilisers contain high levels of phosphates and nitrates which promote algal growth. Runoff carries this into the Great Barrier Reef ecosystem. Pesticides used by farmers are made of heavy metals such as lead, mercury, arsenic and other toxins which are dangerous to aquatic plant and animal species. Nutrient runoff from agricultural land has promoted growth of the Crown of Thorns starfish, which eat coral polyps in plague proportions. Boats venting their on board sewerage system release raw sewage into the water. The sewage from a single boat is not damaging in itself, though the impact of numerous boats is considerable. The sewerage systems of residents can be transported through runoff into the Great Barrier Reef ecosystem. Agricultural waste can cause increase in phytoplankton levels, resulting in outbursts of the threatening Crown of Thorns Starfish. Dredging and material placement (also called spoil dumping) have relatively well-known potential impacts such as degradation of water quality, changes to hydrodynamics, [63] Geography Oil Spills Loss of Species Ecosystems at Risk smothering of benthic fauna and flora, damage to marine wildlife through the dredge mechanism, translocation of species and removal of habitat. If inappropriately managed, dredging activities may impact areas of conservation value. Dredging and material placement processes need to be carefully managed to ensure any adverse effects are prevented or confined to areas of low conservation value. Despite the best efforts of government agencies to keep the Great Barrier Reef in the best condition possible, there have been a huge number of oil spills over the last few decades that gave directly affected the reef and its marine life. While the act of oil drilling is banned on the reef, spills caused by passing oil container ships have still continued to occur. A recent spill created a massive grounding scar over 3 kilometres long. As a result, some of the damaged areas have become uninhabitable for marine life and there are estimates from experts that the reef may take 10 to 20 years to recover from the incident. Six of the seven species of marine turtles in the world are found on the Great Barrier Reef. All six species are threatened. An estimated 1750 turtles are caught in trawl nets each year. The Queensland population of loggerhead turtles are facing extinction 70-90% population decline caught in numbers over the last 30 years 14% of turtles caught in trawl nets are loggerhead turtles Average size of nesting female green turtles has been reducing over the last 20 years Analysis of 10 years nesting data of hawksbill turtles shows a downward trend in numbers of breeding females Over 90% decline in Dugong numbers south of Cooktown since the 1960’s. Dangerous organo-chlorine pesticide residues have been found in dugongs and dolphins. The Great Barrier Reef remains one of the last areas in the world with viable populations of dugongs. Michaelmas Cay has seen a 25% decline in population of Crested Tern and Sooty Tern and a 45% decline in Common Noddy tern population since the 1980’s. e. Traditional and Contemporary Management Strategies i. Contemporary Management Strategies 1. Tourism HSC a. The Role of Education Tourism plays an important role in educating people about this fragile ecosystem and why it needs to be protected. One of the aims of the World Heritage Conventions is to promote education about environmental protection and the impact of human activities on ecosystems. Every visitor to the reef pays a small fee which is used by the Great Barrier Reef Marine Park Authority to run educational programs b. The Impact of Geographical Concentration 85% of visitors visit the reef around Cairns and the Whitsundays These two regions represent 7% of the total area of the reef In excess of 1 million people visit the reef in these tiny areas and consequently, the potential impact is enormous and careful management is essential. [64] Geography Ecosystems at Risk c. Pontoons Most visitors to the reef are day-trippers and most of these spend their day on floating pontoons There have been a number of accidents involving pontoons including sinking As a result, pontoon operators need to complete a detailed environmental impact statement d. Recreational Boats Management of tourist boats is a key issue for the GBRMPA Speed limits are enforced to reduce the impact of wake from boats GBRMPA runs a massive education program about boat pollution HSC This is particularly important when boats travel close to shore Advertisements are used along with signs at boat ramps e. Disturbance to Wildlife and Breeding Cycles Breeding cycles with some bird colonies were being affected by tourists Seabirds on Michaelmas Cay had stopped breeding Bird breeding islands are controlled by the Queensland Parks and Wildlife Service The service regularly assesses colonies for danger Many islands are now permanently closed to humans The QPWS is working closely with tourist operators to limit but allow tourist access f. Whale Watching Whale watching has become a popular tourist activity on the reef Commonwealth and Queensland laws prevent operators from steering too close to whales A small number of operators allow tourists to swim near whales A code of conduct ensures that this is not adverse for the whales This includes fully briefing swimmers about correct conduct with whales g. Turtles The most common interaction between humans and turtles is on the beaches where they lay their eggs [65] Geography Ecosystems at Risk Nesting turtles can be easily disturbed so a code of conduct was established The Commonwealth Government has protected turtles through legislation h. Role of the Tourism and Recreational Reef Advisory Committee The Tourism and Recreational Reef Advisory Committee acts as a liaison between the authority and the tourism industry The TRRAC meets several times a year and has representative members from a broad cross section of the GBR tourism industry Through the TRRAC the tourism industry plays an important role in managing the GBR It is in the best interests of the industry to protect the reef 2. Improving Water Quality Research by the Commonwealth and Queensland governments discovered that many of the inshore and fringing reefs are being degraded by poor water quality These findings led to the creation of the Reef Water Quality Protection Plan which aims to reduce the decline in water quality of water entering the GBR system Reef Plan Goals To reduce the To rehabilitate the amount of water river catchments pollutants entering and better manage the GBR them The Reef Plan recognises the need for cooperation Some recent initiatives include: The development of regional plans to better manage river catchments Farm Management Systems initiative launched to identify and deal with environmental risks The Queensland Wetlands Program designed to research, protect and HSC rehabilitate wetland ecosystems [66] Geography Ecosystems at Risk 3. Anchoring and Mooring a. Public Mooring At many of the most popular boating destinations, the GBRMPA has installed public moorings These are permanently fixed to the seabed and remove the need for anchors This removes the damage caused by anchors b. Restrictions to Anchoring The zoning plan forbids anchoring in many parts of the reef This is difficult to police due to the sheer size of the reef and many careless skippers still use anchors in a damaging way ii. Traditional Management Strategies Aboriginal and Torres Strait Islander believed that they were not above nature but part of it thus they approached their management of the GBR by being stewards as there is an obligation to look after one's country because of the deep spiritual links with the land. Thus, traditional management strategies focus on using marine and terrestrial resources in a sustainable way. They did this through a detailed practical knowledge of the ecosystem, its natural history and habitats, animal migration patterns and seasons. This detailed knowledge and connectedness led to strategies such as: o Setting size limits on the fish they caught, some local Aboriginal people believe the sizes allowed these days are too small o Seasonal hunting, ensured that species could recover and be plentiful for the future o Assigning sacred animal totems so that person or group was responsible for its survival o Maintaining relatively small population levels and relatively low-level technology so it did not place stress on the ecosystem. HSC [67]