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This emerging research theme focuses on the causes of climate change and its ecological effects, aiming to provide a scientific basis for global change and understand the changing interactions within the Earth system. The team has a demonstrated record of research excellence and has published high-impact papers in top scientific journals.
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Emerging Strategic Research Theme The Habitable Earth Sun Kwok Faculty of Science Key themes Causes of climate change Ecological effects of climate change Habitable planet in a wider context
Why this theme? • It is perhaps the major challenge scientists face in the 21st century and therefore of tremendous practical importance • It is scientifically interesting • Requires interdisciplinary approaches • Demonstrated record of research excellence
Members • Ecological effects of climate change • David Dudgeon • Clement Dumont • Melissa Hart • Nancy Karraker • Leszek Karczmarski • Kenneth Leung • Vengatesen Rajan • David Thomson • Gray A. Williams • Rudolf Wu • Y.Q. Zong • Causes of climate change • Jonathan Aitchison • Jason Ali • Nathalie Goodkin • Z.H. Liu • G.C. Zhao • Habitable planet in a wider context • Sun Kwok • Man Hoi Lee • Yiliang Li • Kono Lemke • Steve Pointing
Objectives • To provide a sound and rigorous scientific basis for global change • To understand the changing interactions between the physical and biological components of the Earth system • To understand the ecological implications of climate change
Track record of the team (last 5 years) High impact publications • Science: 5 • Nature: 4 • Nature series: 3 • Proceedings of the National Academy of Sciences: 3 median age of the team is: 43
Earth as an integrated system • Atmosphere, hydrosphere, biosphere and geosphere • Interacting physical, chemical and biological processes • Human impacts (e.g., on habitat destruction, biodiversity loss,atmospheric and ocean composition)
Earth as a System Atmosphere Biosphere Solid Earth Oceans
Earth today One of the greatest impact of NASA’s lunar program is the public appreciation of how fragile the Earth is
Climate Change: Past and Present • Global climate evolution • Plate tectonics-climate interaction • Past atmospheric CO2 • Past Asian monsoon variability • HK regional climate change • Asian monsoon-El Nino interaction 34 M yr ago
Influences of assembly and breakup of supercontinents on hydrosphere, atmosphere and biosphere • The assembly of a supercontinent may cause: • Decrease in total land areas • Low-rate oceanic production • Global sea levelsubsidence • Decrease of CO2 in atmosphere • Colder and dry weather- ‘Icehouse’ • Mass Extinction – P/T Boundary Event • The breakup of a supercontinent may cause: • High-rate oceanic production • Global sea levelrise • Increase of CO2 in atmosphere – continental/oceanic rifting • Warmer and wet weather- ‘greenhouse’ • Explosion of life – Cambrian explosion
Life and the Earth Environment • When did the Earth become habitable, and why did life boom in the Cambrian period? • How and when the Asian monsoon was generated? • How has vegetation responded to climate change? • Environmental changes in Hong Kong.
Impact of CO2 emissions • Changes in atmospheric temperature leads to ocean circulation, ocean/atmosphere interactions, evaporation/precipitation patterns • Can the oceans sustain their role as CO2 sinks?
Ecosystems and population processes Impact of environmental change on wildlife demography, population structure, population persistence, invasive species and other multi-species interactions (David Dudgeon, Gray Williams, David Thomson, Kenny Leung, Leszek Karczmarski, Clement Dumont,Nancy Karraker)
Effects on organisms Individual effects of environmental stress: thermal, chemical, osmotic, hypoxic, acidification (Rudolf Wu, Kenneth Leung, Rajan Vengatesan, Gray Williams, David Dudgeon)
Urbanization The urban heat island: analyses of spatial variability and exposure (Melissa Hart) Building energy consumption under a future warming climate (Melissa Hart)
Habitable planet in a wider context • Life in extreme environments: understanding the environmental limits for life on Earth and how geochemical factors determine the limits of life • Origin of life • Earth analogs: we cannot do experiments on Earth. We need to learn from other examples in the Solar System.
Habitable Earth in the Wider Context • Extreme environments on Earth as tractable analogs to inform the search for life on other planets. (Pointing, Li) Polar desert, Earth Polar desert, Mars
Habitable Earth in the Wider Context • Synthesis, stability and concentration of biomolecules in extreme environments on early Earth (Lemke, Li) • The role of fluids in early life processes (Lemke, Li)
Habitable Earth in the Wider Context • How do microbes interact with geo-materials? • Bio-mineralization (Li) Ni-Cr-Fe-C alloy identified from 1600 million years dolomite (Li unpublished data).
Habitable Earth in the Wider Context • How does evolution of the Solar System affect Earth’s Habitablity? (Lee) • Habitable worlds elsewhere in the Solar System and the Universe (Lee) • The delivery of pre-Solar System organics and • their effects of the origin of life on Earth (Sun Kwok)
Extreme Environments Deep Ocean Atacama Desert, Chile Permafrost Area Salty Lake Grand Prismatic Spring (Yellowstone) Acid Mine Drainage
Summary • There has been significant climate change over the history of the Earth due to internal and external perturbations • The Earth is an integrated system • Climate change is a complex subject requiring input from geology, chemistry, physics, biology, and astronomy