The Great Barrier Reef
"A Reef such a one as I now speak of is a thing
scarcely known in Europe or indeed any where but in these seas: it
is a wall of Coral rock rising almost perpendicularly out of the
unfathomable ocean."
Joseph Banks - August,1770
"We had wheat sheaves, mushrooms, stags horns,
cabbage leaves, and a variety of other forms, glowing under water
with vivid tints of every shade betwixt green, purple, brown, and
white; equalling in beauty and excelling in grandeur the most
favourite parterre of the curious florist."
Matthew Flinders - October, 1802
"In among the branches of the corals, like birds
among trees, floated many beautiful fish, radiant with metallic
greens or crimsons, or fantastically banded with black and yellow
stripes."
J. Beete Jukes 1842-46
The scale, biodiversity and beauty of Australia’s Great Barrier
Reef (GBR) continue to astound us hundreds of years after these first
written observations. Extending for over 2,000 km along the northeast
coast of Australia, the GBR covers 35 million hectares – an area
larger than England. Listed as a World Heritage Area (WHA) in 1981, in
recognition of its outstanding natural values, the GBRWHA is
the largest marine protected area in the world. The GBR is the best-managed
and protected coral reef ecosystem in the world. The impact of
climate change on coral reefs is receiving ongoing national and
international media attention. Consequences for Australia’s coral
reefs could be severe despite our significant efforts in protection
and management, if key issues are not addressed urgently. The
Australian Institute of Marine Science (AIMS) maintains the following
position on climate change and coral reefs:
What is known
- Global climate is changing rapidly due to human activities and
will result in continued rising temperatures both on land and in the
sea.
- Climate change due to the enhanced greenhouse effect has
significant consequences for coral reefs. There is a direct link
between unusually warm seawater temperature and bleaching of
reef-building corals around the world.
- Changing ocean chemistry due to rising CO2 may also
have serious implications for coral reefs and other marine
calcifying organisms and is likely to alter the makeup of marine
ecosystems and weaken coral reef structures.
- Increased mass bleaching events on the GBR and elsewhere since
the mid-1970s are linked to global warming.
- Well-protected and well-managed reefs are more resilient to
stresses but are not protected from the global-scale effects of
rising water temperatures and changing ocean chemistry.
- The Great Barrier Reef (GBR) has warmed ~0.4oC since
the 19th century (global warming ~0.7oC) and
has experienced 2 major coral bleaching events (1998 and 2002).
- During the 1998 coral bleaching event 42% of shallow water
corals reefs on the GBR bleached and an estimated 2% died that year.
- In 2002, the largest event on record, an even greater proportion
of the Reef bleached (55%) and an estimated 5% died.
- Coral bleaching was again observed in the 2006 summer,
particularly in the southern GBR, where local water temperatures
reached ~1-2oC above the seasonal average.
- Healthy reefs (more ecologically intact and less exploited)
recover better from bleaching than highly stressed reefs.
- AIMS research is monitoring & modelling ocean climate changes,
assessing impacts of climate change for coral reef organisms,
identifying potential adaptation mechanisms, and identifying
characteristics and locations which may provide refuge for marine
species in a rapidly changing world.
The Consequences
- The pace of warming is of major concern as it gives organisms
little time to respond or adapt to the changed climate conditions.
The GBR could be 1-3oC warmer by the end of this century
and, as it warms, conditions conducive to bleaching could occur
annually within ~20-30 years.
- There is a limit to what can be done locally to protect natural
ecosystems such as the GBR. Global leadership is required to commit
leading world economies to drastic reduction in greenhouse gas
emissions. There is only a small window of time for action before
changes are irreversible.
- Suggestions that rising sea levels and increasing temperatures
will be good for coral reefs and even allow the GBR to expand
southwards are unlikely as there is a lack of suitable substrate for
coral reefs south of the current GBR and also the rapidity with
which such changes would have to occur – tens of years compared with
the 100s-1000s of years required for intact ecosystems to migrate.
- The impacts of bleaching on coral reefs are expected to affect
large numbers of other reef organisms given that coral provides the
habitat and food for tens of thousands of other organisms.
The Science in Detail
Human Induced Climate Change Will Alter Life on Coral Reefs
The health of coral reefs in many parts of the world is declining
due to a variety of direct, local human pressures (such as overfishing
and land-based activities affecting water quality; see Wilkinson
2004). Coral reefs are now subject to an additional global-scale
threat to their long-term wellbeing due to the enhanced greenhouse
effect. The two most important consequences of the enhanced greenhouse
effect for coral reefs are warming of the oceans and changes in ocean
chemistry.
Rising sea temperatures increase the frequency of mass coral
bleaching events. Corals live only 1-2oC below their upper
thermal limit and sustained periods of water temperatures above this
threshold during the summer stress the coral and their symbiotic algae
(the essential partner for reef-building corals) which are expelled
when the coral is stressed. The host coral may die, partially die, or
recover, though coral growth and reproduction can be affected in
surviving corals. Approximately 16% of the world’s reefs were
seriously damaged during the 1998 bleaching event – probably the
warmest year experienced by modern corals. Based on the recovery of
some affected reefs, it is clear that healthy (more resilient) coral
reefs recover better than reefs degraded by other human pressures.
The Great Barrier Reef (GBR) is the best managed and protected reef
in the world (because of Great Barrier Reef Marine Park Authority’s
Representative Areas Program, zoning and permitting systems, the July
2004 declaration of 33% No-Take Areas and the Reef Water Quality
Protection Plan), yet major bleaching occurred in 1998 and 2002 as a
consequence of the relatively modest warming of GBR waters (~0.4oC)
since the end of the 19th century.
Current projections suggest that average tropical ocean
temperatures could warm 1-3oC by the end of this century.
There is general scientific consensus that global warming and
consequent coral bleaching are a significant threat to the maintenance
of coral reef communities as they presently exist and that healthy
coral reefs (more ecologically intact and less exploited) will be more
resilient than those degraded by other human pressures. There is some
evidence emerging that corals may be able to adapt to climate change
by altering their symbiotic algae to more thermally tolerant partners,
though this may be at the expense of growth rates. This capability
may, however, only occur in a few species and not be sufficiently
rapid to keep pace with temperature rises. Current research at AIMS
focuses on these possible adaptive changes in corals and their effects
on coral growth.
Increasing atmospheric carbon dioxide (CO2, the
principal greenhouse gas) is changing the chemistry of the
oceans. About 30% of the CO2 released into the atmosphere
by human activities since the Industrial Revolution has been absorbed
by the oceans. This changes the chemistry of the oceans, which become
more acidic (lower pH; global ocean pH has already dropped by 0.1 and
could be 0.4-0.5 lower by the end of this century) thus altering the
concentrations of carbonate and bicarbonate ions. Many marine
organisms (corals, calcareous algae, shells, benthic and planktonic
organisms such as foramanifera and coccolithophores) use calcium and
carbonate ions from seawater to secrete calcium carbonate skeletons.
Changing the ocean chemistry essentially shifts the geochemical
equation by which these organisms "calcify". The implication of
continued change in ocean chemistry due to rising CO2 is
that these organisms will not calcify as well as they did in
pre-industrial times and thus produce weaker skeletons and grow more
slowly. For coral reefs, weaker structures would reduce their
resilience to the natural forces of erosion and slower growth will set
back the rate of recovery after bleaching and other disturbances.
Also, changing ocean chemistry will alter the ocean depths at which
dissolution of calcium carbonate skeletons of different mineralogies
occurs. Modelling and experimental studies (e.g. Biosphere 2 mesocosm)
have demonstrated that increased CO2 reduces coral
calcification rates (Kelypas et al., 2006).
Calcification rate also depends on water temperature. AIMS has
provided evidence (Lough & Barnes 2000) that several long-lived
massive Porites corals on the GBR had increased their calcification
rate towards the end of the 20th century (up to ~1980 when
cores were collected) which matched the observed rise in GBR water
temperatures (AIMS is currently examining more recent coral growth
rates from short coral cores). This finding generated some
controversy, as it did not match the model or experimental findings.
The conclusion from this work was that, at least initially, some
corals might respond more to rising water temperatures than to changes
in ocean chemistry. More recently scientists from UNSW, CSIRO and AIMS
(McNeil et al., 2004) published model results suggesting that
the warming effect on coral calcification (in one coral species)
outweighs changes in ocean chemistry and that coral calcification will
increase with global warming. Kleypas et al. (2005) refuted
these controversial findings and concluded that they were "based on
assumptions that exclude important factors and therefore need to be
viewed with caution." These studies focused, however, on the most heat
resistant type of coral and did not consider the overall effects on
reef calcification rates of the widespread death of the majority of
corals that are less heat resistant.
How much ocean warming reefs can withstand will, however, be
limited by the point at which temperature thresholds for coral
bleaching are regularly exceeded. The general scientific consensus is
that changing ocean chemistry due to rising CO2 has serious
implications for coral reefs and other calcifying marine organisms of
the open ocean. These changes could well alter the makeup of marine
ecosystems, alter food webs and weaken coral reef structures. Clearly,
there is much more we need to learn about the effects of rising CO2
and marine calcification. The importance of this problem and its
impacts on marine ecosystems is recognized in a recent report of the
British Royal Society (2005) and the outcomes from an international
workshop held in Florida in 2005 (Kleypas et al., 2006; Janice
Lough from AIMS was an invited participant in the workshop and a
contributing author).
Other impacts of climate change on coral reefs and associated
coastal ecosystems will result from changes in air temperatures (2005
was the warmest year on record in Australia), rainfall and river flow,
the occurrence and intensity of tropical cyclones, ocean circulation
patterns and sea-level rise. Taken together, such climate change
impacts threaten the biodiversity of marine ecosystems. In June 2005,
the Department of Environment and Heritage supported a workshop
National Biodiversity and Climate Change Action Plan, Research and
Information Gaps Workshop: Synthesis and Summaries for Four Key
Objectives (Janice Lough, AIMS was a co-facilitator with Jo
Johnson, GBRMPA of the Climate change and marine, estuarine and
coastal ecosystems theme). The GBRMPA is co-ordinating preparation
of a book GBR Ecological Vulnerability Assessment which will
consider climate change impacts on all aspects of the GBR, not just
coral reefs (Several AIMS scientists are chapter lead authors: Janice
Lough – climate change scenarios; David Mckinnon – plankton; Nicole
Webster- microorganisms, Katharina Fabricius – reefs; and other AIMS
staff will be contributing authors).
The Scientific Advice
Coral reefs of the world are under threat from both local and
global-scale stresses. The enhanced greenhouse effect (through
bleaching and ocean chemistry changes) is likely to alter the
community structure of reefs, including the world’s best-managed reefs
of Australia. The impacts of bleaching on coral reefs are expected to
affect large numbers of other reef organisms, given that coral
provides the habitat and food for tens of thousands of other
organisms. There is a clear scientific consensus that reducing and
reversing local human pressures on coral reefs has to be accompanied
by drastic reductions in greenhouse gas emissions to limit the amount
of global warming if coral reefs are to survive. Furthermore, there is
an urgent need for improved monitoring of the GBR as well as more
research into the impacts and response of coral reefs to climate
change and climate variability. The impacts of climate change and
climate variability is a high priority research area for AIMS.
The Future
Even with rapid global implementation of strategies to stabilize
and reduce greenhouse gas concentrations, we are committed to
significant rapid climate change and possibly accelerated sea level
rise. The urgent scientific challenge is to understand how these rapid
environmental changes will affect tropical marine ecosystems such as
the GBR and, in particular, how reef communities will respond and/or
adapt to the changing physical environment. Climate change and global
warming pose significant challenges (in a number of ways) to the GBR –
a vast and beautiful ecosystem that we do not, and will probably
never, fully understand.
Current understanding suggests that the GBR will not disappear but
its appearance and community structure will change from the
coral-dominated reef described years ago by Banks, Flinders and Jukes
and that we know today. If temperatures rise to a level that is
unsustainable for corals, the limestone base structure of the reef
will persist. Given the massive size of the GBR, at least a few corals
are likely to survive in sheltered locations. Under such a worst-case
scenario, however, the ecological goods and services provided by the
GBR (including commercial values associated with tourism and
fisheries) will dramatically alter as coral communities dwindle and
reefs of the GBR shift from being dominated by corals to reefs
dominated by algae and filter feeders.
AIMS Research
Ongoing scientific research at AIMS directly addresses key issues
associated with the regional impacts of global warming and climate
variability. Scientists from AIMS are approaching the issue of climate
change using technologies ranging from genetic analysis to monitoring
of whole ecosystems. AIMS scientists are:
- monitoring detailed changes in weather, climate and circulation
on the GBR.
- looking back into the past using centuries-old coral cores to
detect recent environmental trends and track the growth responses of
corals to changing environments.
- studying the potential for reef corals to adapt to climate
change by focusing on the key relationship between corals and the
single-celled algae living within their tissues. Prior research
suggests that this relationship is critical in predicting a coral’s
ability to withstand varying environmental conditions.
- leading the implementation of the GBR Ocean Observing System – a
integrated state of the art observing system for the whole of the
Great Barrier Reef.
Additional Reading
Kleypas, JA, RW Buddemeier, M Eakin, JP Gattuso, J Guinotte, O
Hoegh-Guldberg, R Iglesias-Preito, PL Jokiel, C Langdon, W Skirving
& AE Strong (2005). Comment on "Coral reef calcification and climate
change: the effect of ocean warming". Geophys Res Lett. 32, L08601
Kleypas JA, RA Feely, VJ Fabry, C Langdon, CL Sabine, & LL
Robbins (eds) (2006). Impacts of Increasing Ocean Acidification on
Coral Reefs and other Marine Calcifiers. Report from international
Workshop on the Impacts of Increasing Atmospheric CO2 on
Coral Reefs and Other Marine Calcifiers, 18-20 April 2005, St
Petersburg, Florida sponsored by NSF/NOAA/USGS.
Lough, JM & DJ Barnes (2000). Environmental controls on growth of
the massive coral Porites. J Exp Mar Biol Ecol 245: 225-243.
Lough J, R Berkelmans, M van Oppen, S Wooldridge & C Steinberg
(2006) The Great Barrier Reef and Climate Change. Bulletin
Australian Meteorological & Oceanographic Society 19: 53.58.
McNeil BI, RJ Matear & DJ Barnes (2004) Coral reef calcification
and climate change: the effect of ocean warming. Geophys Res Lett
31, L22309
The Royal Society (2005). Ocean Acidification due to Increasing
Atmospheric Carbon Dioxide. Policy Document 12/05, London UK, (www.royalsoc.ac.uk),
60pp
Wilkinson, C (2004). Status of Coral Reefs of the World: 2004.
GCRMN, ICRI, AIMS
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