2. Climate Change: Impacts and Responses Topic 2: The Earth's Climate System 1

3. 2 Image: NASA Earth Observatory Outline 1.Definitions 2.Components of Earth’s climate system 3.Drivers of Earth’s climate system (internal and external forcings and feedback mechanisms) 4.Earth's energy balance and the greenhouse effect 5.Biogeochemical cycles and links to the climate system

4. 3 Image Credit: Fred Kulpers Learning Outcomes for this topic  Understand the main components of the Earth’s climate system and how they interact  Understand what drives the Earth’s climate system  Describe the Earth’s energy balance and how it relates to the greenhouse effect  Understand how biogeochemical cycles influence Earth’s climate

5. 4 Section 1: Definitions

6. 5  Earth’s climate system  Radiative forcing  Climate Feedbacks Outline: Definitions

7. 6 The climate system is defined by the dynamics and interactions of its five major components:  Atmosphere (air)  Hydrosphere (liquid water)  Cryosphere (frozen water)  Geosphere (earth – unloving physical)  Biosphere (life) Climate system dynamics are driven by both internal and external radiative forcings. Earth’s climate system

8. 7 Radiative forcing relates to the amount of energy which Earth receives from the sun, and how much Earth then radiates back into space.  Types of radiative forcing: external forcings are those attributable to changes in the amount of energy that arrives at Earth in the first place, internal forcings are all those factors that determine how much energy is reflected or radiated by Earth. Radiative Forcing  What can affect radiative forcing? changes to the amount of incoming radiation changes to the amount of solar radiation that is reflected away from the Earth, or changes in the amount of energy that is radiated away from Earth.

9. 8 IPCC 2014 Climate feedbacks Feedbacks occur when an internal or external forcing results in changes to the climate system which further impact on climate system dynamics in a feedback loop.  A positive feedback operates to increasingly impact on climate.  A negative feedback is self-limiting, and offsets or reduces the prevailing change. An example of a positive climate feedback is atmospheric water vapour.

10. 9 Section 2: Components of the Earth's climate system

11. 10  Components  Interactions amongst components Outline: Components of the Earth’s Climate System

12. 11 Components of Earth’s Climate System

13. 12 Image: www.noaa.gov The Atmosphere The atmosphere is mostly nitrogen (78.1%) and oxygen (20.9%), with trace gases including argon and helium, as well as radiatively active greenhouse gases such as carbon dioxide (0.035%) and ozone. The atmosphere is layered into troposphere, stratosphere, mesosphere and thermosphere, each with varying temperatures and with different properties in terms of the gases they contain.

14. 13 Schematic view of components of the climate system and its interactions Image: IPCC 2007

15. 14 Section 3: Drivers of the Earth’s climate system

16. 15  Drivers of climate change  External climate forcings  Internal climate forcings  Feedbacks Outline: Drivers of the Earth’s Climate System

17. 16 Drivers of climate change IPCC 2014

18. 17 External Forcings:  Solar variation  Milankovitch cycles Internal Forcings:  Greenhouse gases  Tropospheric aerosols  Stratospheric ozone  Land surface changes  Ocean circulation changes  Volcanoes Climate Forcings

19. 18 Image created by Robert A. Rohde / Global Warming Art Solar Variation  Periodic and aperiodic fluctuations  Solar variation and volcanic activity account for some climate change within prehistory  Solar variations alone do not explain the currently observed changes.

20. 19 IPCC 2007 Milankovitch Cycles  Eccentricity (a cycle of around 100,000 years)  Tilt or Obliquity (a cycle of around 41,000 years)  Precession (a cycle of around 24,000 years) Image: Robert A. Rhodes, Global Warming Art

21. 20 Image: www.climate.nasa.gov Greenhouse Gases Greenhouse gases absorb and emit radiation within the thermal infrared range Greenhouse gases include:  water vapour,  carbon dioxide,  methane,  nitrous oxide,  ozone,  CFCs …and others

22. 21 Image: www.nasa.gov Tropospheric Aerosols Aerosols:  Scatter and absorb radiation, bringing about complex interactions with climate  Play a role in cloud formation  Create positive and negative forcing: Sulphate aerosols persist over time and reflect energy from the sun resulting in cooling Black carbon particles settle on Earth and reduce albedo which causes warming

23. 22 Image: www.nasa.gov Stratospheric Ozone The ozone layer is thinning due to effects of chlorine and bromine released from manmade CFCs Holes have formed over the poles as a result of the effects of seasonal stratospheric cloud formation Stratospheric ozone has complex direct and indirect interactions with climate Image of the largest Antarctic ozone hole ever recorded (September 2006), over the Southern pole

24. 23 Image: NOAA Ocean Circulation Changes

25. 24 Image: www.nasa.gov Land Surface Changes

26. 25 Image: NASA Volcanos A volcano is a rupture in the Earth’s crust from which magma, ash and gases can escape. They have far-reaching atmospheric effects.

27. 26 IPCC 2014 Estimates of radiative forcing in 2011 relative to 1750

28. IPCC 2014 Positive and Negative Feedback Mechanisms 27

29. 28  Well-understood: Water vapour (positive feedback) Albedo (positive feedback)  Less-well understood: Land carbon cycle (currently negative feedback) Clouds (positive and negative feedback)  Feedbacks not included in climate models: Methane hydrates (positive feedbacks) Permafrost methane (positive feedback) Our understanding of these feedbacks

30. 29 Section 4: Earth’s energy balance and the greenhouse effect

31. 30  What is the greenhouse effect?  Earth’s energy balance Outline

32. 31 What is the greenhouse effect? Image: www.nps.gov

33. 32 Earth’s energy budget Image: IPCC 2013  Global annual energy flows are shown in Watts/m 2  TOA stands for Top of Atmosphere

34. 33 Section 5: Biogeochemical cycles and links to the climate system

35. 34  What are biogeochemical cycles?  The carbon cycle  The nitrogen cycle Outline

36. 35  Transfer and transport of matter within the biosphere, hydrosphere, geosphere and atmosphere  Gaseous cycles (carbon, nitrogen, oxygen, water)  Sedimentary cycles (phosphorus, sulphur) What are biogeochemical cycles?

37. 36 The carbon cycle

38. 37 IPCC 2014 The nitrogen cycle Nitrogen is the most important element for plant growth Nitrogen availability affects the rate of key eco-system processes Human activities - fossil fuel combustion, the use of inorganic nitrogen fertilizers, and release of nitrogen in wastewater have altered the global Nitrogen cycle IPCC 2014

39. 38  Components of the climate system  Radiative forcing External forcings Internal forcings  Climate feedbacks  The greenhouse effect  Earth’s energy budget  Biogeochemical cycles Summary

40. End of Topic 2: The Earth’s Climate System Next Topic: Climate Change in the Distant Past 39