There are considerable concerns about how rising atmospheric CO2 will affect Earth's climate and marine biogeochemistry in the future. Computer simulations are used to predict future climate changes, but these projections remain very uncertain and the capacity of climate models to reproduce long-term change needs to be thoroughly tested. The only way to do this is by testing model performance against geological archives of past climate changes.

This course examines how geoscientists reconstruct climate changes in the past combining data from the oceans, atmosphere, ice sheets, land surfaces, and vegetation, and how these relate to reconstructed changes in energy supply from the sun. One important topic that we will cover, for example, concerns the reasons for past atmospheric CO2 changes, and how these influenced the global climate.

The course covers the essential aspects needed for understanding the Earth's climate system such as Earth's energy balance; climate sensitivity; sea level and ice sheet changes; ocean circulation changes; nutrient cycling and atmospheric CO2 variations. Students will learn how the geochemistry of natural palaeoclimate archives and numerical models are used to reconstruct the history of the climate system and identify the causes of climate change.  Geochemical tools and proxies used to reconstruct climate changes through Earth's history will be explained. You will learn how to use box models to understand nutrient cycling and atmospheric CO2 changes. We will look in more detail at: the nature of, and relationships between, high-resolution ice-core records from Greenland and Antarctica; abrupt climate changes; the factors that affect short-term climate variability in Australia and how these are currently changing; and the science related to common misconceptions in climate change discussions. A key outcome of this course will be a firm understanding of the physical, chemical, and biological processes that control Earth's climate, and how they may interact to modulate climate change in the future.

In addition to research-based lectures and practicals, journal articles of greater conceptual difficulty will be made available for students who wish to explore their personal interests in climate change. The teaching material is focused around areas of active palaeoclimate research and presents students with an overview of the latest international scientific understanding of past climate changes and their relevance to the future.

NOTE: Honours students attend joint classes with undergraduate students and graduate students but are assessed separately.