Climate Change and Conservation – Part II
Arctic Ocean Ice Cover
Loss of Arctic Ocean Ice
Polar Bear (Usinus maritimus)
Polar Bear as Indicators In 2007, the US Fish and Wildlife Service listed the polar bear as a threatened species The polar bear is a significant seal predator and depends on ice as a platform to hunt seals There are three distinct subpopulations that will be differentially affected by changing sea ice Projected reductions in arctic sea ice will result in the loss of 2/3 of the population by 2050
Global Change and Antarctic Food Webs Changing sea temperatures can have numerous impacts on food webs Ice cover and melting influences light and nutrient levels and phytoplankton growth Phytoplankton blooms fuel zooplankton like krill that feed cetaceans, pinnipeds, fishes, etc. Krill have been influenced by local climate changes
Western Antarctic Peninsula
Global Change in Polar Regions
Global Change and Krill
Global Change in Polar Regions
Climate Change and the California Current Changes in winds and water temperature will affect the food web of the California Current System Upwelling is a critical driver for the pelagic marine food web Upwelled water brings nutrients and fuels higher trophic levels Climate change can influence winds and currents associated with upwelling
Coastal Upwelling
Ekman Transport
Climate Change and the Cal fornia Current Several studies (Sydeman et al and Lee et al. 2007) have documented changes in populations of sea birds Cassin’s auklet is a planktivorous bird that is a good indicator of changes Long-term data link declines in upwelling and warming sea surface temperatures with declining popuaation
Cassin’s Auklet
Cassin’s Auklets
California Current and Cassin’s Auklets
Cassin’s Auklets
Climate Influences
Other Seabirds
Climate Change in Tropics
Impacts on Coral Reefs
Hoegh-Guldberg 1999
Impacts on Coral Reefs
Long-Term Trends
Ocean Acidification Increasing CO2 can lead to changes in the oceans concentration of calcium carbonate Increased CO2 will increase the amount dissolved in ocean water This will increase carbonic acid and lower the ocean’s pH This will reduce the amount of aragonite in the water possibly to below saturation This will make it more difficult for corals and other organisms that use calcium carbonate
Ocean Acidification
Changes in Calcification
Bond et al Millenial Cycles
Decadal Cycles Fligge and Solanki 2001
Decadal Cycles Larsen 2005
Decadal Cycles Larsen 2005
Methane Hydrates Heating of the deep ocean may have released large amounts of methane from methane clathrates Methane hydrates or clathrates are ice compounds filled with methane gas that remains solid at low temperature Typically in moderate depths m and temps near 2 o C At higher temperature they can release lots of methane, which is a much more efficient green house gas
Methane Hydrates Figure 1. Stability field (temperature and pressure) of methane hydrates (Dickens et al., 1995). Note the effect of warming by about 4oC from an initial deep water temperature around 11oC, leading to dissociation of hydrates over an ocean-wide zone of several hundreds of m thick.
Methane Hydrates End of the Paleocene about 60 million years ago, the earth’s ocean suddenly warmed (Late Paleocene Thermal Maximum) Associated with ocean warming of 4-6 degrees C Complete extinction of unicellular eukaryotes like foraminifera The oceans went anoxic
Late Paleocene Thermal Maximum
Methane and Thermal Increase
Ocean Temperatures
Methane Hydrates Figure 2. Sizes of organic carbon reservoirs (Kvenvolden, 1998).
Burning Ice