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3756888
The impacts of sea-level rise on the index nesting beach
on Klein Bonaire for three species of Sea Turtle.
Marine Environmental Management | Jennifer Cheetham
Project Supervisor: Dr Sue Willis
Supervisor: Julie Hawkins
Organisation: Sea Turtle Conservation Bonaire
Candidate number 3756888
Acknowledgements
This study has only been possible due to support from Sea Turtle Conservation Bonaire
(STCB) who offered me this placement, taught me so much and valued me as a respected
member of the team, which allowed me to have such a wonderful experience. I am also
thankful to STCB for allowing me access to their database and resources. I would especially
like to thank Dr Sue Willis for her support, guidance and generosity during my time in
Bonaire as my supervisor and mentor. I am also thankful to Mabel Nava for her leadership
and organisation and allowing me to take part in all activities that further increased my
knowledge and enthusiasm for sea turtles. I also highly acknowledge the contribution made
by supporters of STCB such as the Board of Directors, Beach Keepers & Volunteers without
whom, the work of STCB and my research would not have been possible. I am grateful to
Dennis and Janice Elloway, Dennis for providing me with essential equipment needed for my
research and Janice for her commitment to STCB, enthusiasm and kindness. I would like to
express my gratitude to Naima Hall for giving up her time to help with my field work of
which I would not have been able to do alone. I would also like to thank Gerrie for taking us
to Klein Bonaire on his boat every Thursday free of charge so that I could collect data for my
research. I would especially like to thank Nathanial Miller from to Dutch Caribbean Nature
Alliance who allowed me the use of his computer and gave up his own time to give me
guidance on using Google Earth and GIS. I would also like to thank Eseld Imms and Abigail
Lynne for help with GIS. Lastly I would like to thank Elizabeth Downes and supporters of the
Alasdair Downes Memorial Fund for providing me with funding towards my summer
placement.
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Contents
Acknowledgements ........................................................................................................ 0
Abstract .......................................................................................................................... 3
Introduction .................................................................................................................... 4
Species found in Bonaire ................................................................................... 4
Threats to marine turtles .................................................................................... 7
Sea-level rise projections ................................................................................... 8
Methodology .................................................................................................................. 8
Collection of nesting data- ................................................................................. 8
Measuring the beach profile- ........................................................................... 10
Results .......................................................................................................................... 12
Sea-level rise scenarios .................................................................................... 16
Discussion .................................................................................................................... 17
Conclusion ................................................................................................................... 21
References .................................................................................................................... 22
Appendices ................................................................................................................... 27
Appendix i........................................................................................................ 27
Appendix ii....................................................................................................... 39
Appendix iii ..................................................................................................... 47
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Abstract
Globally, all extant sea turtles species are endangered due to centuries of uncontrolled
exploitation, furthermore they face future threats from climate change. The Caribbean is
home to six of the seven extant marine turtle species. Sea turtles have various nesting and
feeding grounds across the Caribbean but return to their natal beaches to breed. This study
focuses on nesting sea turtles in Bonaire, a small island in the south of the Caribbean, which
has three breeding species; the Green, Loggerhead and Hawksbill turtle. The index beach is
“No Name” beach on the small islet of Klein Bonaire, which is 800m west of Bonaire.
Global sea-level rise projections range between 0.18-0.59m by 2100 (IPCC, 2007). However,
the Caribbean region could experience 25% greater sea-level rise than the global average with
suggestions up to 1.6m. Sea-level rise threatens nesting beaches and is expected to negatively
impact the sea turtles. This investigation measured beach profiles along “No Name” beach to
create contours of elevation. The nests were identified, monitored and plotted onto maps.
Analysis of the distance from the nest to the HTM and elevations of nests indicate that
Loggerheads are more at risk from sea-level rise. However for all sea-level rise scenarios
there will be beach area and nests lost (using 2012 data). Where natal beaches cannot retreat,
they may be lost to sea-level rise; turtles must adapt to climate changes or will face an even
greater population decline.
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Introduction
Marine turtle species have existed for millions of years, with over 100 different species,
evolving from a single ancestor, over 200 million years ago in the Mezozoic era (Pritchard,
1997; Gulko & Eckert, 2004). However, there are only seven species extant today. Five of the
seven species are categorised as “endangered” and two species “critically endangered”
(WWF, 2008; IUCN, 2012). All living turtles share similar characteristics such as late
maturation, air breathing, high fecundity and external development but each species is
adapted to their specific habitat and diet, so there is little niche overlap (Gulko & Eckert,
2004). Within the Caribbean Sea, there has been a vast decline in the number of sea turtles
since records began in the 17th century (Harold & Eckert, 2005). It was reported by historical
mariner documents in the 17th and 18th century that populations of turtles were in the millions
(IUCN/SSC, 2008). Today the Caribbean is home to 6 of the 7 species, of which all
population numbers are significantly depleted in comparison to the historical levels. This
depletion is due to centuries of overexploitation and accidental death, including bycatch of
fisheries or entrapment from abandoned fishing gear (Bräutigam & Eckert, 2006; Harold &
Eckert, 2005). Habitat loss has also played a contributing factor to the declines in population.
Many reef habitats have lost up to 80% of their coral cover in the past 50 years, due to
overfishing, sedimentation, pollution, contamination and climate change. These reefs are
critical feeding habitats for Hawksbill turtles. Today many global sea turtles populations have
been severely reduced and some local populations made extinct (IUCN/SSC, 2008).
However, the level of protection has increased through stricter law enforcement and better
management of coastal habitats and fisheries. This had led to a slight increase in the number
of Hawksbill turtles in the Caribbean (WWF, 2008; Halpin et al., 2009).
Species found in Bonaire
Bonaire is a small island in the south of the Caribbean, approximately 80km North of
Venezuela. Klein Bonaire was the main study site situated in the crescent of Bonaire mainland.
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Klein Bonaire is approximately 6km2 and is fully protected by law (Fish et al., 2005). There are
three species of sea turtle that nest on Bonaire and Klein Bonaire these are the Green, Hawksbill
and Loggerhead turtles (Gulko & Eckert, 2004; STCB, 2011). These species do not spend all of
their lives in the coastal waters of Bonaire, but complete different life stages in other areas of
the Caribbean and migrate back to these waters to breed (IUCN/SSC, 2008). Nesting females
return to the same beaches from where they were born, this phenomenon is known as natal
philopatry. The coastal habitat around Bonaire does not support adult turtles permanently; they
only come to Bonaire to breed. However, juvenile Hawksbill and Green turtles inhabit the coral
reefs and sea grass beds around the islands (STCB, 2011).
Hawksbill turtles (Eretmochelys imbricata) are one of the smallest species of marine turtle.
They can be identified by having a narrow head with a beak like jaw and overlapping scutes
(4 lateral scutes) (Ripple, 1996; WWF, 2008; Lutz & Musick., 1997). They are also among
the most endangered species of marine turtle being classified as “critically endangered”
(facing extremely high risk of extinction in the wild in the near future) by the International
Union for Conservation of Nature and Natural Resources (IUCN, 2012; Mortimer &
Donnelly, 2008). This species faces a global crisis, with the IUCN estimating that there was
an 80% decline in the population in just three generations, mainly due to human threats,
especially poaching. The tortoiseshell carapace is commercially valuable worldwide for
jewellery and ornaments (Reuter and Crawford 2006; IUCN, 2007). Hawksbill turtles occupy
a wide region and range of tropical habitats, from terrestrial where they hatch and nest to
coral reefs where they spend their adult lives. Sea turtles experience a variety of temperature
changes and external environments throughout their lives (WWF, 2008). Adult Hawksbills
feed on sponges, anemone and squid. Their nesting season on Bonaire is usually between
June and December (STCB, 2011). Mature females breed every two to four years, with three
to six nests per season (14-16 day intervals) and an average of 100-200 eggs per nest. Each
nest has an eggs chamber at least 50cm deep in the sand (Gulko & Eckert, 2004). The eggs
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incubate over 50-60 days. The current global population estimate is 22,900 nesting females
(Sea Turtle Conservancy, 2011).
Loggerhead turtles (Caretta caretta) are one of the most migratory species of sea turtle with
some individuals crossing the Atlantic or Pacific oceans (Bolten et al., 1998; Nichols et al.,
2000). They can be identified by their large head with strong jaws and reddish-brown heart
shaped carapace that doesn’t have ridges or overlapping scutes (there are 5 lateral scutes). The
adult carapace is 80-110cm in length. Loggerheads inhabit coastal bays and shallow coastal
waters where they can feed on their preferred food source of bottom dwelling shellfish
including crustaceans and molluscs (Gulko & Eckert., 2004). Individual adults nest every
couple of years laying 3 to 6 nests per season with an average of 100-130 eggs per nest. The
eggs incubate for approximately 60 days. Their nesting season on Bonaire is between May
and August (STCB, 2011). Loggerheads are listed as “Endangered” by the IUCN red list of
endangered species (IUCN, 2007; IUCN, 2012; Marine Turtle Specialist Group, 1996).
Incidental capture in fisheries has been a significant part of Loggerhead population decline in
recent years. There are currently an estimated 44,560 nesting females in the world (Sea Turtle
Conservancy, 2011).
Green Turtles (Chelonia mydas) also nest on Bonaire and Klein Bonaire, however this species
has the fewest nests compared to Loggerheads and Hawksbills. Green Turtles can be
identified by having a pair of prefrontal scales, a small blunt head with a serrated jaw (Gulko
& Eckhert, 2004). The carapace is large and the scutes do not overlap (4 lateral scutes). The
carapace colour varies from different shades of green to browns and yellows, with a length of
80-115cm (Gulko & Eckert, 2004). Green turtles have a wide range of habitats and are found
in both temperate and tropical regions. However this species is listed as “Endangered” by the
IUCN and face a very high risk of extinction in the wild in the near future (IUCN, 2012;
Seminoff, 2004). Adult Green turtles have a serrated jaw, which allows them to tear
vegetation such as algae and sea grasses. The population of green turtles in Lac Bay on the
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east coast of Bonaire has the fastest growth rates in the Caribbean. For Green turtles the mean
growth rate of recaptured turtles in Lac bay (since monitoring began in 2003) was 6.2cm/yr
compared to outside the bay in the reefs of Bonaire & Klein Bonaire which was 3.2cm/yr
(STCB, 2011). The nesting season is usually between July and September in Bonaire and
Green turtles return to their nesting grounds approximately every two to five years to breed
(STCB, 2011). There are usually 3-5 nests laid per season with each nest averaging 75-115
eggs (Gulko & Eckert, 2004). The nests are approximately 90cm deep, so require beaches
with soft deep sand. They incubate for around 60 days. The current population estimate is
88,520 nesting females (Sea Turtle Conservancy, 2011).
Threats to marine turtles
Marine Turtles face many threats both natural and man-made; natural threats include
predators and climate fluctuations and anthropogenic threats include pollution (rubbish and
oil spills), fishing activities, invasive species, destruction or modification of habitat,
harvesting (eggs, shells and meat), artificial lighting, disease or parasites and human induced
climate change (Choi & Eckert, 2009; Gulko & Eckert, 2004; Knowles et al., 2009). Survival
to adulthood is low (IUCN/SSC, 2008). Anthropogenic threats occur within all population
ranges, all species are threatened and because they are highly migratory, when localised
populations decline this could be due to local or foreign threats, so prove difficult for study
for scientists to target the source of the decline. The Wider Caribbean Sea Turtle
Conservation Network (WIDECAST) has found that all species are affected by coastal
development, pollution, invasive species and erosion (WIDECAST, 2008; Knowles et al.,
2009). Anthropogenic pressures can increase stress levels to turtles throughout their life
histories and cause reduction in population size and reduce their resilience to climatic
fluctuations (WWF, 2008). These threats are a global problem, and because turtles have long
life stages before they are sexually mature and can reproduce, they are not reproductively
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successful. Without adaptation to these threats, conservation efforts and mitigation, recovery
of sea turtle populations will be difficult to accomplish.
Sea-level rise projections
The Caribbean has a tropical climate, and in the future this is expected to experience regional
differences in temperature, precipitation and sea-level rise. The level of global average sealevel rise varies between different scenarios and considerations, the IPCC estimates a sealevel rise in the range of 0.18 to 0.59m by 2100 (IPCC, 2007). However this does not consider
regional changes. The IPCC estimates that the Caribbean will experience a greater sea-level
rise than the global average and that small islands will be threatened and sea-level rise could
be up to 25% greater than the global average. When thermal expansion and melting of global
frozen freshwater stores contribute to rising sea-levels, estimates of sea-level rise should be
higher. The Dutch Delta committee estimates that the maximum sea-level rise for the BES
islands (Bonaire, Saba, Sint Eustatius) could be up to 1.6m and that this estimate should be
used for adaptation (Debrot & Bugter, 2010). Sea-level rises are likely to accelerate beach
erosion rates, further increasing the loss of sandy beaches. Tidal surges are expected to
become more frequent, further accelerating coastal erosion and inundation of coastal habitats
due to higher wave energy (Hawkes et al., 2009).
Methodology
Collection of nesting data“No Name” beach on Klein Bonaire is the index nesting beach Bonaire (Figure 1). It is
monitored by Sea Turtle Conservation Bonaire (STCB) three times a week during the nesting
season (May to November). STCB is a non-profit, non-governmental organisation that
conducts research and conservation activities to ensure the protection of sea turtles in Bonaire
and throughout their natural range. When turtle activity was seen, termed a “crawl”, the tracks
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were investigated to discover whether the tracks led to a nest, a false crawl or an unsuccessful
attempt at nesting. When a nest was found, the location was recorded using a GPS point with
the location stakes providing distance along the beach (these are located every 50m along the
beach). The vegetation type around the nest, freshness and observers were also recorded. In
order to confirm the nest, the body pit created was carefully dug and if the eggs were found it
is marked as a confirmed nest. If the nest was confirmed the distance from the HTM was also
recorded. There were 70 nests (end of September) on Klein Bonaire both confirmed and
unconfirmed, used in this study.
Figure 1: Image from Google Earth showing Bonaire and Klein Bonaire.
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Measuring the beach profile-
Figure 2: Image from Google Earth showing Klein Bonaire and the location of "No Name" which
was sampled in this study.
Figure 3: Image from Google Earth of "No Name" beach and the location of the HTM, stake and
transects every 50m along the beach.
The study site was the Bonaire’s index beach for nesting marine turtles called “No Name”
beach on Klein Bonaire, measuring 2000m in length (Figure 2 & 3). The beach had
permanent location stakes every 50m along the beach marking the distance along the beach.
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At each 50m location stake, beach profiles were taken. Transects were laid out with a
measuring tape, perpendicular to the sea line from the High Tide Mark (HTM) up to 20m
along the profile (this was not always possible where vegetation was very dense). The HTM
marks the highest water level of the sea usually seen by a line of marine debris or a line in the
sand or rocks. Coordinates of the HTM & location stake were taken using a handheld global
positioning system (Garmin GPS 72H) which is WAAS-enabled, giving accuracy up to 3m
(Garmin LTD., 2009).The distance between the HTM and location stake was also taken. At
every 2m along the profile the elevation of the land was taken using a measuring pole and a
support stick with a level balanced on top to read the change in height of the land at 2m
intervals (Figure 4) (Emery, 1961). Also at every 2m interval a fixed-point photograph was
taken (at 30cm above the ground facing the left side of the transect) in order to create a
merged photograph of the entire profile. The vegetation type along each profile was also
recorded. Each beach profile was then drawn with Microsoft Excel to show the gradient of
each slope.
B
A
HTM
2m
d
Up to 20m
Figure 4: The Emery method was used to measure the beach profile (Emery, 1961). This measures
the elevation between two points. In this study elevations were taken every 2m along the transect (up
to 20m). The measuring poles were 2m apart, a Level was placed on top of pole A, the observer at A
looked through the level and read the horizontal measurement on pole B which gave the elevation d.
The cumulative elevation along the transect gave the beach profile shape.
The GPS points of the transects were then plotted onto Google Earth and imported into
ArcMap (ESRI, 2011) for computer analysis and building 3D models of “No Name” beach.
Using the elevations between transects, contours of land heights were created. Nest locations
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were added by species specifying whether the nests were confirmed or unconfirmed. Using
GIS software (ESRI, 2011), projections were made to predict how much of the beach would
be lost at different sea-level rise projections, this used the samples of the elevations of the
beach profiles and analysed how many were below each sea-level rise projection in relation to
the overall number of elevation samples collected. An analysis was also made to find the most
vulnerable species to sea-level rise at various projections. This compared the nest location on
the beach profile for each species by measuring distance from the HTM to the nest and the
expected elevation of the nests.
Results
Figure 5: ArcMap showing the GPS points of the nest sites with some anomalies.
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The GPS points for each of the 70 nests were plotted into Arc Map. However there were some
anomalous points (Figure 5) which may have been due to human error, such as typos during
data entry or not waiting until the GPS had transmitted the satellite signal. In Figure 5 the
cluster of nests indicates the actual position of “No Name” beach (top left) and there are
approximately 13 observed anomalies (i.e. nests not lying within the beach area). The Garmin
GPS tracker used was accurate to 3m. However there can be occasional signal errors if the
receiver does not pick up a signal.
Figure 6: The Location of all the nests on "No Name" Beach, Klein Bonaire
Toward the west of “No Name” beach there are an even spread of Hawksbill and Loggerhead
nests (Figure 6). However from approximately 1000m to 1850m along the beach the nests
mostly belong to Hawksbills. This section of the beach area is steep and highly vegetated with
a lot of hard vegetation especially Oleifi (Bontia daphnoides), which is unsuitable nesting
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habitat for other species (STCB, 2011). The Loggerhead turtles nests were largely
concentrated in the dune areas.
(A)
(B)
Figure 7: The HTM of "No Name" beach (A) with the nest locations (B)
The locations of the nests were plotted on maps of Klein Bonaire, with Figure 7 showing the
position of the nests in relation to the HTM (Figure 7 (A & B). These distances were only
measured for ‘confirmed’ nests and they varied for each of the three species. Patterns showed
that the Loggerhead turtles nested closer to the HTM than the Hawksbills, this is what was
expected. The average distance from the nests to the HTM for Loggerhead turtles was 6.01m,
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for Hawksbill turtles was 8.98m and Green turtles was 14.00m (Figure 8). There is a
statistically significant difference (P =0.01) in the means when comparing the Hawksbill and
Loggerhead position of the nests in relation to HTM (Appendix iii).The evidence suggests
that the Green turtles nested much higher up the beach than the other two species but this is
not significant due to there only being 3 green turtle nests on Klein Bonaire, compared to 24
nests from Hawksbill turtles and 22 from Loggerhead turtles.
Figure 8: The mean distance from the confirmed nests to the HTM for three species of turtle;
Hawksbill (Ei), Loggerhead (Cc) and Green Turtles (Cm).
However, using the distance from the nest to the HTM does not provide the adequate
information on how sea-level rise will affect the nests, so beach profiles were also measured.
These beach profiles could be used to find the elevation along the beach and create contours
to estimate the elevation of each nest, which gives a better indication of the risk from rising
sea-levels.
The profiles were drawn in Excel and photos taken along each transect put together to provide
visualisation of each profile (Appendix i). These can be used to show the loss of beach area at
various sea-level rise projections if beach dynamics remain the same. From 200-1000m the
beach is mostly sand dune habitat and from 1000-1800m the profile is steep and highly
vegetated. After 1800m to 2020m the profile of the beach rose up in the dunes to a maximum
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elevation of 0.6m then decreased to below the level of the HTM. A large area behind the
dunes is vulnerable to flooding with sea level rise above 0.4m.
Measuring the elevation of beach profiles at regular intervals along the beach allowed
contours to be created on maps that allow estimations of height of entire beach. GIS has been
used to create these contours at 0.2m intervals using the elevations recoded during beach
profiling (Figure 9). These contours were then used to estimate the height of each nest and
estimate of the impact of sea-level rise on “No Name” beach by identifying the percentage of
nests and beach area that would be at risk under the different sea-level rise scenarios.
Figure 9: Contours of 0.2m elevation increase from the HTM for the profile of "No Name"
beach, Klein Bonaire. Contours include; HTM (Orange line with cross poles), 0.2m (Bright
Yellow dashed line), 0.4m (Fusia Pink dashed line), 0.6m (Lime Green dashed line), 0.8m (Blue
dashed line), 1m (Black line), 1.2m (Red dashed line), 1.4m (light pink dashed line) and 1.6m
(White/Yellow dashed line).
Sea-level rise scenarios
A 0.2m rise in sea-level will not severely impact many nests (Appendix ii: Figure 12), 19% of
the beach area would be lost along with 7 % of nests using 2012 data (Table 1). Loss of beach
area will only occur between 500-1000m and 1850-2050m. With an increased sea-level rise
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up to 0.4m, 34% of the beach are will be affected (Appendix ii: Figure 13 & 14) and 14% of
current nests would be at risk especially the ones between 1850-2050m (Table 1). With a
0.8m sea-level rise most of the sandy beach area is expected to be flooded, this is 70% of the
Loggerhead habitat and 56% of total nests using 2012 data (Appendix ii: Figure 17 & 18).
Most of the area between 1850-2050m will be flooded as the dunes only reach a maximum of
0.6m above the HTM. For the maximum projected scenario projected for the Caribbean by
the end of the century (1.6m sea-level rise), 98 % of nests and 98% of beach area would be at
risk (Table 1; Appendix ii: Figures 25 & 26).
Sea-level rise
% of nests lost
(m)
0.2
7
0.4
14
0.6
25
0.8
56
1.0
72
1.2
81
1.4
95
1.6
98
% beach area
lost
19
34
53
67
80
91
95
98
Table 1: This table gives a summary of the percentage of nests lost during various sealevel rise scenarios, using the data from 57 nests, both confirmed and unconfirmed (2012
nesting data). 13 of the nests had anomalous GPS points as the location did not appear
upon “No Name” beach, so these were not used in this analysis. The percentage of beach
area lost was determined by comparing the number of elevations recorded below
various sea-level rise scenarios against the overall number of elevations recorded during
sampling of beach profiles.
Discussion
The climate of the Earth is changing at a significant rate that has never been seen before in the
Earth’s history. This is likely to be caused by acceleration in consumption of fossil fuels and
the release of anthropogenic atmospheric emissions (Johns et al., 2003; The Royal Society,
2010; Hoegh-Guldburg et al., 2007). Such rapid climate changes will negatively impact sea
turtles and their habitats world-wide (WWF, 2008). The changes in climate since 1996 have
been much greater than expected (Rahmstorf et al., 2007; Witt et al., 2009). Since 1850
global temperatures have increased by 0.8°C (±0.2°C), future projections predict an increase
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of 2.4°C to 6.4°C by 2100, depending on the scenario (IPCC, 2001; The Royal Society,
2010). As the world warms, glacial melt and thermal expansion are expected to cause a rise in
sea-levels and increase of extreme weather events are likely to produce more frequent tidal
surges, which are expected to impact the nesting beaches of marine turtles.
For all marine turtle species, success is dependent on the availability of nesting habitat
(Hawkes et al., 2009). Sea-level rise is likely to significantly reduce the number and size of
nesting beaches especially where coastal squeeze is imminent i.e. where retreat of beaches is
inhibited by coastal development or on islands that may be submerged with increasing sealevels (CCCCC, 2009; Fish et al., 2005). Some species of turtle may be more affected by sealevel rise than others depending on their nesting characteristics. In this study there was
statistically significant evidence that Loggerhead turtles nested closer to the HTM than
Hawksbill turtles suggesting that they could be at more risk from sea-level rise. However, the
distance from the nest to HTM was only measured if the nest was confirmed, so this reduced
the number of nests in the analysis. Nevertheless, the outcomes of this analysis fitted what
was expected, that Loggerheads nest further down the beach profile i.e. in the sand dunes,
compared to the Hawksbills that prefer to nest in the vegetation further along the profile and
steeply sloped beaches (Horrocks & Scott, 1991). This was also observed when analysing the
estimated elevations of the nests, where there were a greater number of Loggerhead nests at
lower elevations than Hawksbill nests.
This investigation also analysed the area of “No Name” beach that would be lost under
various sea-level rise projections. An earlier study by Fish et al. (2005) on Bonaire’s nesting
beaches suggested that 30% of nesting habitat is expected to be lost by a 0.5m sea-level rise
and that there would be a 50% loss of Hawksbill nesting habitat with a sea-level rise of 0.9m.
Another study in Hawaii by Baker et al. (2006) predicted a 40% decline in Green turtle
nesting area if sea-level rose by 0.9m. Within the Caribbean research showed that by 2006,
approximately 20% of nesting sites had already been lost and another 50% were threatened
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(McClenachan, 2006). During this study, there was evidence that a 0.8m sea-level rise would
put 70% of the Loggerhead nests at risk. Sea-level rise is expected to impact large sections of
the beach whereby a 19-53% beach area is estimated to be lost with a 0.2-0.6m sea-level rise
by 2100 (IPCC, 2007). If the maximum sea-level rise scenario of 1.6m is reached by the end
of the century then 98% of beach area and 98% of nests would be lost. These projections
assume that the current beach morphology and profile is maintained (Debrot & Bugter, 2010;
Fish et al., 2005).
If the beach area cannot retreat, nesting area will be significantly reduced. This may be observed
where flood defences or coastal development are present and coastal squeeze in inevitable or on
low-lying islands which may be submerged by sea-level rise. In this scenario if similar numbers
of nesting females return to nest, nesting areas could reach a carrying capacity and further
nesting attempts are likely to be closer together, risking turn out of previous nests (Mazaris et
al., 2009; Hawkes et al., 2009). If the beach cannot retreat there will be more nests closer to the
HTM, so there is an expected increase in the number of nests that are vulnerable to tidal
inundation (Fish et al., 2005). Nests may also face increased risk of water-logging from below,
whereby rising sea-levels may cause the groundwater saturation to increase and the water table
to rise, reducing the success of the clutch (Witt et al., 2009; Wetterer et al., 2009). In this
instance the species that lay nests closer to the HTM or that lay deeper nests are more at risk,
evidence from this study suggests that Loggerhead nests would be most at risk. The choice of
nesting site by turtles is dictated by a variety of factors including sand type, distance from the
HTM, salinity, ventilation, vegetation and sand depth (Kamel & Mrosovsky, 2006). If there is
not sufficient optimal nesting area at a reasonable distance above the HTM, the number of nests
will be reduced. Success of a site depends on the number of turtles that return to their natal
beaches to breed, so this decline might not be identified for many years.
However, on Klein Bonaire there is no development so nesting beaches have the possibility to
retreat and beach morphology dynamics could allow creation of new nesting habitat. In this
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study no beach morphology changes were recorded however, this investigation allows
morphological changes to be studied in the future by observing changes in the beach profile
via the profiles recorded and the photographs taken. There has been much speculation about
the effects of sea-level rise on the rates of beach accretion and erosion (Pethick, 2001). Sealevel changes will alter the wave energy gradients both perpendicular and parallel to the
shore. In 1962 Bruun predicted that beach profiles would respond to sea-level rise by
maintaining their morphological characteristics relative to the water level. This was expected
due to the movement of eroded material, supplying sediment to build the beach profile at
other places on the beach but only if there was net sediment balance (Bruun, 1962; Bruun,
1988; Schwartz, 1967). The vegetation on the beach could also impact the coastal
morphological dynamics by altering profile characteristics and stabilising the sand (Hesp,
2008). In this study the vegetation has been recorded along each transect, this can be used for
further research observing changes along the profile in subsequent years.
Only data from 2012 was used in this study (May to the end of September, more nests could
have been laid since), this does not allow analysis past levels of sea-level rise which has
already occurred at a rate of 3.4mm/year using global averages (Rahmstorf, 2007). This data
can be used for further study of sea-level changes in the future.
Sea-level rise must not be seen as a single entity it must also be considered along with other
climate change factors such as global warming and ocean acidification, to incorporate how all
factors might have implications on sea turtle behaviour. Sea turtles display ectothermic
characteristics so their body cycles, behaviour and development are dependent on temperature
(Gulko & Eckhert, 2004). They are sensitive to fluctuations in the external environment,
including temperature, level of precipitation and seasonality (Hawkes et al., 2007).
Temperature affects their life histories from hatchling sex determination (Yntema &
Mrosovsky, 1980) to alteration in adult distribution and migratory patterns, also by altering
ocean currents and impacting feeding habitats. Extreme weather events such as increased
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frequency and severity of hurricanes and tidal surges are expected to become more common
in the future (Meehl et al., 2000; Knutson et al., 2010). Regional variation in precipitation
levels across the Caribbean are expected (CCCCC, 2012). Some areas will experience
drought conditions where there will be less precipitation. In these areas sea turtles may find
creation of nests difficult due to dryer sand and the external temperatures may get too hot for
nest incubation. Higher temperatures will lead to skewed sex ratios and temperatures too great
can be lethal (Hawkes et al., 2007). The opposite extreme is that some areas will experience
heavy precipitation, whereby nests may become saturated, which could reduce the oxygen
content of the sand, lowering the success rate. With the increase in carbon dioxide in the
atmosphere the oceans will become more acidic (Hoegh-Guldberg et al., 2007). Acidification
could impact the food sources of marine turtles, for example crabs will find it difficult to
make their calcareous shells. Also coral reefs could be destroyed by bleaching due to the
stresses of unusually warm temperatures and more acidic water (Hoegh-Guldberg et al., 2007;
Orr et al., 2005). These are vital food sources and habitats associated with sea turtles,
whereby loss of these habitats will negatively impact turtles. The alteration in the temperature
and pH of the oceans may directly affect internal mechanisms and homing ability. Sea turtles
may be used as an indicator species of climate change due to their sensitivity to
environmental changes (Sea Turtle Conservancy, 2011).
Conclusions
The impacts of climate change and furthermore, sea-level rise will undoubtedly affect the
nesting behaviour of marine turtles. The climate change factors must also be considered along
with existing human threats in order for adaptation and mitigation strategies to be
incorporated into conservation and coastal management plans (Fish et al., 2005). This study
has deduced that Loggerheads are more at risk from sea-level rise than Hawksbills. Also that
if beach morphology dynamics do not keep pace with current and future levels of sea-level
rise, nesting area is likely to be significantly reduced. If sea turtles do not adapt to these
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changes when they return to their natal beach to breed, many turtles may not be able to nest
and many populations will decline. This investigation raises further questions, for future
research such as, will sea turtles continue to nest on their natal beaches even if they are
reduced in area or will they find new beaches? Is climate change happening too fast for them
to adapt and will we see an accelerated decline in numbers in the future? Research needs to
undertaken each year documenting the changes in nest number, beach area and whether there
is increased incidence of extreme weather events that will impact sea turtle nesting behaviour.
The severity of sea-level rise risk to sea turtle populations depends on whether changes in
coastal morphology could create new nesting beaches or the ability of sea turtle populations
to naturally adapt to climate change.
Word Count = 5,000
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16. Harold, S. & Eckert, K.L. (2005). Endangered Caribbean Sea Turtles: An Educators
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25. Johns, T.C., Gregory, J.M., Ingram, W.J., Johnson, C.E., Jones, A., Lowe, J.A.,
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26. Kamel, S.J. & Mrosovsky, N. (2006). Deforestation: Risk of sex ratio distortion in
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28. Knutson, T.R., McBride, J.L., Chan, J., Emanuel, K., Holland, G., Landsea, C., Held,
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32. McClenachan, L., Jackson, J.B.C.& Newman, M.J.H. (2006). Conservation
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34. Mortimer, J.A & Donnelly, M. (IUCN SSC Marine Turtle Specialist Group) 2008.
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Rodgers, K.B., Sabine, C.L., Sarmiento, J.L., Schlitzer, R., Slater, R.D., Totterdell,
I.J., Weirig, M.F., Yamanaka, Y. & Yool, Y. (2005). Anthropogenic ocean
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& Somerville, R.C.J. (2007). Recent Climate Observations Compared to Projections.
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Trade in Marine Turtle Products in the Dominican Republic and Colombia. A Report
from the Field. TRAFFIC. 12 pp.
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Erosion. The journal of Geology, 75 (1): 76-92.
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44. Seminoff, J.A. (Southwest Fisheries Science Center, U.S.) (2004). Chelonia mydas.
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ants, beach replenishment and nest placement by sea turtles. Environmental
Entomology, 36: 1084-1091.
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Protecting the impacts of climate change on a globally distributed species:the case of
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Appendices
Appendix i.
Beach Profiles taken at every 50m along “No Name” beach. These include the slope of the
profile in Microsoft Excel, photographs of the profile and how each profile will be affected by
different leveld of Sea Level Rise.
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SLR
0.8m
0.2m 0.4m
SLR
SLR
0.2m
0.4m
0.2m 0.4m
0.8m
1.2m
1.6m
0.8m
1.6m
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SLR
SLR
SLR
0.2m 0.4m
0.8m
0.2m 0.4m
0.2m
0.4m
0.8m
0.8m
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0.2m
SLR
SLR
SLR
0.8m
0.4m
0.2m
0.2m
0.4m
0.8m
0.4m
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SLR
0.4m
0.2m
SLR
0.2m
0.4m
0.8m
0.8m
0.8m
SLR
0.2m
0.4m
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SLR
0.2m 0.4m
SLR
SLR
0.4m
0.2m
0.2m
0.4m
0.8m
0.8m
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0.2m
0.4m
0.8m
SLR
SLR
SLR
0.2m
0.4m
0.2m 0.4m
0.8m
1.2m
0.8m
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SLR
0.2m
SLR
0.2m 0.4m
SLR
0.2m 0.4m
0.8m 1.6m
0.8m
0.8m
1.2m
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SLR
SLR
SLR
0.2m 0.4m
0.2m 0.4m 0.8m
0.2m 0.4m
SLR
m
0.8m
0.2m 0.4m
0.8m
0.8m
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SLR
0.2m0.4m 0.8m
SLR
0.2m 0.4m 0.8m
SLR
0.2m 0.4m 0.8m
1.2m
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SLR
SLR
SLR
SLR
0.2m 0.4m 0.8m
0.2m 0.4m
0.2m
1.6m
0.8m
1.2m
0.8m
0.4m
0.2m
0.4m
0.6m
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SLR
0.2m
0.4m
SLR
0.2m 0.4m
SLR
0.2m 0.4m 0.6m
0.6m
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SLR
SLR
SLR
0.2m
0.2m 0.4m
0.2m 0.4m
Appendix ii
Images taken from ArcMap indicting various levels of sea level rise in relation the location of
nests along “No Name” beach.
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Figure 2: the nest location in relation to the transect location on “No Name” beach.
Projections
Figure 3: The orange line represents the HTM, the yellow dotted line is the elevation of 0.2m,
which will be lost with 0.2m of sea-level rise.
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Figure 4: Pink line shows a 0.4m elevation above HTM, this area of beach will be lost with 0.4cm
rise in sea-level.
Figure 5: The 0.4m elevation contour shows how much beach will be lost with 0.4m sea-level rise
and which nests would be at risk (using 2012 nest data).
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Figure 6: Lime green dashed line represents a 0.6m elevation contour above the HTM.
Figure 7: The 0.6m elevation contour shows how much beach will be lost with 0.6m Sea-level rise
and which nests would be at risk using 2012 nest data.
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Figure 8: The blue dashed line represents an elevation of 0.8m above the HTM
Figure 9: The 0.8m elevation contour shows how much beach will be lost with 0.8m Sea-level rise
and which nests would be at risk using 2012 nest data.
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Figure 10: The purple line represents 1m elevation above the HTM.
Figure 11: The 1m elevation contour shows how much beach will be lost with 1m sea-level rise
and which nests would be at risk using 2012 nest data.
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Figure 12: The Red dashed line represents a contour 1.2m above the HTM.
Figure 13: The 1.2m elevation contour shows how much beach will be lost with 1.2m sea-level rise
and which nests would be at risk using 2012 nest data.
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Figure 14: The contour (pink dashed line) represents an elevation of 1.4m above the HTM.
Figure 15: The 1.4m elevation contour shows how much beach will be lost with 1.4m sea-level rise
and which nests would be at risk using 2012 nest data.
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Figure 16: The white/yellow dashed line represents a contour of 1.6m above HTM (the maximum
expected SLR by 2100).
Figure 17: The 1.6m elevation contour shows how much beach will be lost with 1.6m Sea-level
rise (SLR) and which nests would be at risk using 2012 nest data. 1.6m SLR is the maximum
projected SLR for the Caribbean.
Appendix iii
A table to show the number of nests (confirmed and unfirmed) from each species that are
impacted by different levels of se level rise. Paired T-tests were used to identify whether the
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mean of the distance between the nest and the HTM is significantly different between the 3
species.
Ei
Cc
Cm
?
SLR
(m)
Confirmed
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.6+
Unconfirmed
Confirmed
1
3
2
3
3
2
7
5
1
2
6
1
4
5
1
Unconfirmed
Confirmed
Confirmed
Unconfirmed
1
1
1
1
1
1
1
1
1
1
1
Paired Samples Statistics
Mean
Pair 1
Pair 2
Pair 3
N
Std.
Std. Error
Deviation
Mean
Ei
8.6336
22
3.70003
.78885
Cc
6.0114
22
2.26031
.48190
Ei
12.5333
3
4.31895
2.49355
Cm
14.0000
3
5.04777
2.91433
Cc
6.0333
3
1.05040
.60645
Cm
14.0000
3
5.04777
2.91433
Paired Samples Correlations
N
Correlation
Sig.
Pair 1
Ei & Cc
22
.076
.736
Pair 2
Ei & Cm
3
.754
.456
Pair 3
Cc & Cm
3
-.126
.919
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Paired Samples Test
Paired Differences
95% Confidence Interval
Mean
Std.
Std. Error
Deviation
Mean
of the Difference
Lower
Upper
Sig. (2t
df
tailed)
Pair 1
Ei - Cc
2.62227
4.18622
.89250
.76621
4.47834
2.938
21
.008
Pair 2
Ei - Cm
-1.46667
3.35460
1.93678
-9.79995
6.86662
-.757
2
.528
Pair 3
Cc - Cm
-7.96667
5.28425
3.05087
-21.09348
5.16015
-2.611
2
.121
Extra-Curricular activities.
During my time in Bonaire I did my PADI open water dive certification and
completed a few more dives after that including a clean up dive and night dive. With
STCB I also carried out a variety of other jobs that were not to do with my own
research, these included in-water snorkel surveys, maintenance of the sea grass beds,
beach cleans, rescues, data entry, communicating with the public and Beach Keepers
via talks, email and social media. I also helped out with hatchling releases and
presentations that were in the evening, encouraging many people to come to these
events. I carried out all the tasks of an intern including many admin roles and general
tasks that were set such as making Beach Keeper identification badges and selling
merchandise, as well as doing my own research.
In my free time I also visited the National Park, Donkey Sanctuary and took Salsa
lessons. I also liked to snorkel in my own time, which was very peaceful and I saw so
many wonderful species on the reefs. I liked to cycle to many places on the island,
visiting the key sites and beaches. I also wrote a blog about my time in Bonaire,
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which allowed me to communicate to the world and my friends at home, what I had
been doing in Bonaire. I am also going to write a few more blogs on Bonaire to tell of
my overall experience.
Overall, I had such a wonderful time in Bonaire especially with the turtles and seeing
conservation in action. I especially liked releasing trapped hatchlings that would not
have made it without intervention, it was such a wonderful feeling to see them free.
The people were really friendly and supportive and I ended up making good contacts
in STCB, CIEE, DCNA, STINAPA and in Dive Friends Bonaire. I always felt
welcome and safe, and enjoyed everything I did in Bonaire.
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