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COASTAL RESOURCES CGE TRAINING MATERIALS FOR VULNERABILITY AND ADAPTATION ASSESSMENT Expectation from the Training Material • After having read this Presentation, in combination with the related handbook, the reader should: • Identify the drivers and potential impacts of climate change on coastal zones; • Have an overview of the methodological approaches, tools and data available to assess the impact of climate change on coastal zones; • Identify appropriate adaptation measures. 2 1.3 (I) Climate Change and Coastal Resources Coastal resources will be affected by a number of consequences of climate change, including: Higher sea levels Higher sea temperatures, sea-surface temperature, El Niño/La Niña-Southern Oscillation (ENSO) events/climate cycle Changes in precipitation patterns and coastal runoff Changes in storm tracks, frequencies, and intensities, and Other factors like Wave climate, Storminess, Land subsidence etc. Coastal Climate Change Drivers Primary drivers of coastal climate change impacts, secondary drivers and processes (adapted from NCCOE, 2004) Primary driver Secondary or process variable Mean Sea Level Local sea level Ocean currents, temperature and acidification Local currents Local winds Wind climate Local waves Rainfall/runoff Groundwater Some Climate Change Factors Net extreme event hazards Net regional mean sea level rise Timeframe Cause Predictability Recurring extremes (Storm surge/tide) Hour-days Wave, wind, storms Moderate to uncertain Tide ranges Daily-yearly Gravitational cycle Predictable Regional sea level variability Seasonaldecadal Wave climate, ENSO, PDO Moderate; Not well known Regional net land movement DecadesMillennia Tectonic Predictable once measured Regional SLR Monthsdecades Ocean warm/ current/climate Observable; future uncertain Global mean SLR Decadescentauries Climate change (temp, ice melt) Short term understandable; future uncertain Potential Impacts Climate Change: Air Temperature - Global Context 1900-2000: Global mean- surface air temp increased by 0.6 0C Projected increase (1990-2100): 1.4 – 5.80C (Based on greenhouse gas emission) 2030: + 0.7 in monsoon,+ 1.3 in winter 2050: + 1.1, + 1.8 in 2050. Current Global Predictions of Sea Level Rise Conclusions about future sea-level rise in the IPCC’s Third Assessment Report (TAR, 2001) and Fourth Assessment Report (AR4, 2007) were broadly similar. The IPCC AR4 projections estimated global sea-level rise of up to 79 centimeters by 2100, noting the risk that the contribution of ice sheets to sea level this century could be higher Post AR4 Research since AR4 has suggested that dynamic processes, particularly the loss of shelf ice that buttresses outlet glaciers, can lead to more rapid loss of ice than melting of the top surface ice alone. There is growing consensus in the science community that sea-level rise at the upper end of the IPCC estimates is plausible by the end of this century, and that a rise of more than 1.0 metre and as high as 1.5 metres cannot be ruled out. Post AR4 Source: Church et al, 2008 Projected Global Average Surface and Sea Level Rise at the end of 21st Century (Source: IPCC, 2007a) (Summary) Temperature Change (0C at 2090-99 relative to 1980-99)a Sea level rise (m at 2090-99 relative to 1980-99) Case Best estimate Likely range Model-based range excluding future rapid dynamical changes in ice flow Year 2000 concentration b 0.6 0.3-0.9 NA B1 scenario 1.8 1.1-2.9 0.18-0.38 B2 scenario 2.4 1.4-3.8 0.20-0.45 A1T scenario 2.4 1.4-3.8 0.20-0.43 A1B scenario 2.8 1.7-4.4 0.21-0.48 A2 scenario 3.4 2.0-5.4 0.23-0.51 A1F1 scenario 4.0 2.4-6.4 0.26-0.59 Notes: aThese estimates are assessed from a hierarchy of models that encompass a simple climate model, several Earth System Models of Intermediate Complexity, and a large number of Atmosphere-Ocean General Circulation Models (AOGCMs). bYear 2000 constant composition is derived from AOGCMs only. IPCC AR4 is missing the rapid ice flow changes…. “…an improved estimate of the range of SLR to 2100 including increased ice dynamics lies between 0.8 and 2.0 m.” Recent findings ~1 m Considering the dynamic effect of ice-melt contribution to global sea level rise, Vermeer and Rahmstorf (2009) estimated that by 2100 the sea level rise would be approximately three times as much as projected (excluding rapid ice flow dynamics) by the IPCC-AR4 assessment. Even for the lowest emission scenario (B1), sea level rise is then likely to be about 1 m and may even come closer to 2 m. http://www.msnbc.msn.com/id/42878011/ns/us_newsenvironment El Niño, La Niña, SST, and the Nino Region El Nino is a major warming of the equatorial waters in the Pacific Ocean. It usually occurs every 3 to 7 years NINO1+2 (0-10S, 80-90W) Warms first when an El Niño event develops NINO3 (5S-5N; 150W-90W) Has the largest variability in SST on El Niño time scales NINO3.4 (5S-5N; 170W-120W) Has large variability on El Niño time scales, and that is closer (than NINO3) to the region where changes in local SST are important for shifting the large region of rainfall typically located in the far western Pacific. NINO4 (5S-5N: 160E-150W) Changes of SST lead to total values around 27.5C, which is thought to be an important threshold in producing rainfall 13 Climate Change: El Niño/ La Niña -Southern Oscillation (ENSO) Global context (Warm SST) Develops in JAS, strengthen through OND, and weakens in JFM lowP El Niño—major warming of the equatorial waters in the Pacific Ocean The anomaly of the SST in the tropical Pacific increases (+0.5 to +1.5 deg. C in NINO 3.4 area) from its long-term average; A high pressure region is formed in the western Pacific and low-pressure region is formed in the eastern Pacific —this produces a negative ENSO index (SOI negative). La Niña—major cooling of the equatorial waters in the Pacific Ocean H(Cold SST) low The anomaly of the SST in the tropical Pacific decreases (-0.5 to -1.5 deg. C in NINO 3.4 area) from its long-term average; A high pressure region is formed in the eastern Pacific and low-pressure region is formed in the western Pacific—this produces a positive ENSO index (SOI positive). 14 La Niña (strengthened trade winds) La Niña, El Niño (Cold SST) high pressure system (Warm SST) low pressure system El Niño (weakened trade winds) Sea Level Change during EL Niño Year + 24” - 12” SA H NINO 3.4 B A G NWP Nino 4 M Nino 3 SP A S W E 17 El Niño/ La Niña Years (1950-2012) The numbers of El Niño/ La Niña years have considerably increased in the recent years. Scientists argue that this is the result of climate variability and change (instability) and This trend is likely to continue in future as we are in a stage of changing climate; 12 *2008-09 13 *2009-11 So, more frequent extreme events are likely in the future— 18 El Niño/ La Niña, Global Temperatures, and Precipitation El Niño Asia Africa NA SA La Niña Asia Africa SA 19 Impacts of ENSO: Venezuela • Venezuela is in the midst of a genuine power and water crisis. There may not be a clear cut answer to this question “What is causing Venezuela's energy crisis”, and different people provide differing interpretations. Among others, pointing the finger at weather changes, President Chávez said “It's El Niño,” partly to be blamed for this recent crunch; The El Niño is blamed to have resulted in a lack of rainfall and the cause of water shortages, which in turn have starved Venezuela's hydroelectric dams which provide approximately three quarters of the nation's electricity. Climate Change: Trend in Sea Level Change (1993-2008), PDO Global Context Green, Yellow, Red: Rising SL; Blue, purple: Falling SL Other Climate Change (Hurricane Katrina) Global to Local context Pacific Storms Storms Coastal storms, and the strong winds, heavy rains, and high seas that accompany them, pose a threat to the lives and livelihoods of the peoples of the Pacific. http://www.pacificstormsclimatology.org/index.php ?page=partners Pacific Storms (formerly PRICIP) is focused on improving our understanding of patterns and trends of storm frequency and intensity - “storminess”- within the Pacific region. ♦ It is exploring how the climate-related processes that govern extreme storm events are expressed within and between three thematic areas: heavy rains, strong winds, and high seas. ♦ It is developing a suite of extremes climatologyrelated data and information products. Daily Time Series – Water levels (all storm..) (all tide..) (storm, tide..) Land Subsidence Subsidence on the coast of Turkey following an earthquake in 1999 Non-Climate Drivers Port/harbour construction Coastal protection works Upstream damming for freshwater supply Hydroelectric power Deforestation Coastal subsistence due to ground water abstraction—particularly significant in delta region Socio-economic scenario changes in coastal regions including urbanization Geological natural hazards—earthquake. Uncertainty in Local Predictions Relative sea level rise: global and regional components plus land movement Land uplift will counter any global sea level rise Land subsidence will exacerbate any global sea level rise Other dynamic oceanic and climatic effects cause regional differences (oceanic circulation, wind and pressure, and ocean-water density differences add additional component) Science Summary Under a high-emissions scenario, a sea-level rise of up to a meter or more by the end of the century is plausible. Changes in the frequency and magnitude of extreme sea level events, such as storm surges combined with higher mean sea level, will lead to escalating risks of coastal inundation. Under the highest sea-level rise scenario by mid-century, inundations that previously occurred once every hundred years could happen several times a year Sea-level rise will not stabilise by 2100. Regardless of reductions in greenhouse gas emissions, sea level will continue to rise for centuries; an eventual rise of several meters is possible. 1.3 (II) Potential Impacts Effect category Example effects on the coastal Environment Bio-geophysical Displacement of coastal lowlands and wetlands Increased coastal erosion Increased flooding Salinization of surface groundwater Socio-economic Loss of property and lands Increased flood risk/loss of life Damage to coastal infrastructures Loss of renewable and subsistence resources Loss of tourism and coastal habitants Impacts of agriculture/aquiculture and decline soil and water quality Biophysical Impacts Climate driver (trend) Main physical/ecosystem effects on coastal ecosystems CO2 concentration Increased CO2 fertilization, decreases ocean acidification negatively impacting coral reefs and other pH SST (I, R) Increased stratification/changes circulation; reduced incidence of sea ice at higher latitudes; increased coral bleaching and mortality; poleward species migration; increased algal blooms. (I: increasing, R:Regional variability) Sea level (I, R) Inundation, flood and storm damage; erosion; saltwater intrusion; rising water tables/impeded drainage; wetland loss (and change) Storm Intensity (I, R) Increased extreme water levels and wave heights; increased episodic erosion, storm damage, risk of flooding and defence failure Altered surges and storm waves and hence risk of storm damage and flooding Storm frequency (?, R); Storm Track (?, R) Wave Climate Run-off (R) Altered wave conditions, including swell; altered patterns of erosion and accretion; re-orientation of beach plan form Altered flood risk in coastal lowlands; altered water quality/salinity; altered fluvial sediment supply; altered circulation and nutrient supply. Vulnerable Regions Mid-estimate (45 cm) by the 2080s Caribbean Pacific Oc ean SMALL ISLANDS A C PEOPLE ATRISK (millions per region) A > 50 million B 10 - 50 million C < 10 million region boundary vulnerable island region C Indian Oc ean SMALL ISLANDS B Coastal Hotspots Low-lying coastal areas, deltas and countries—many of which are small island developing states—and less developed countries are especially vulnerable to climate change impacts. Other vulnerability hot spots include areas with poor and insecure land tenure, and dense or urbanized populations that will have to migrate with sea level rise. Atolls Impacts of Climate Change: Antigua and Barbuda • Damage to critical habitats (beaches, mangroves, sea grass beds, coral reefs) • Loss of wetlands, Lands due to Sea level change • Increased coral bleaching as a result of a 2°C increase SST by 2099 • Destruction to coastal infrastructure, loss of lives and property • Changes in coastal pollutants will occur with changes in precipitation and runoff • General economic losses to the country Source: http://unfccc.int/resource/docs/natc/antnc2.pdf Also see: http://unfccc.int/national_reports/non-annex_i_natcom/items/2979.php Coastal Megacities (>8 million people) Tianjin Dhaka Seoul Osaka Istanbul Tokyo New York Shanghai Manila Los Angeles Bangkok Lagos Mumbai Lima Karachi Buenos Aires Rio de Janeiro Madras Jakarta Calcutta Sea-Level Rise: Summary New research indicates: 1. 2. 3. 4. 5. 6. Doubled melting rate of Greenland ice sheet, Net melting of the Antarctic ice sheet, Global rise approaching 3.0 mm/yr, twice the rate last century, Continued heating of atmosphere – heating of water column, More than 1 m rise is now expected during this century. 30C temperature rise suggests 3-6 m sea-level rise in a century. There are still major uncertainties in sea-level science, but these latest results are significant in that: 1. 2. 3. They do not point in the direction of smaller rates of rise, They are consistent with the worse case of longstanding predictions, Counter arguments grow fewer and fewer…… Mitigations 38