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Lecture 22: Carbon Isotopes and Orbital Changes in Deep Water Chapter 10 (p. 179-187); Appendix II: p. 363-364.

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Presentation on theme: "Lecture 22: Carbon Isotopes and Orbital Changes in Deep Water Chapter 10 (p. 179-187); Appendix II: p. 363-364."— Presentation transcript:

1 Lecture 22: Carbon Isotopes and Orbital Changes in Deep Water Chapter 10 (p. 179-187); Appendix II: p. 363-364

2 Temperatures over last 400,000 years Carbon dioxide has varied from ~ 180 – 310 ppmv. 385 ppmv (in 2008) Inferred temperature has varied from ~ 8ºC cooler than present during glacial periods to ~ 4ºC warmer during interglacial periods. Methane has varied from ~ 350 – 800 ppbv; ~ 1790 ppbv (in 2008)

3 How Could CO 2 Vary Over Orbital-Scales? Atmosphere: 30% decrease (90 ppm) Temperature and salinity of surface oceans explains 10% of the reduction. The atmosphere (and other) carbon is stored in deep ocean.

4 Carbon Isotope Ratios Isotopes are forms of a chemical element that have the same atomic number but differ in mass. Carbon is made up of two stable isotopes: carbon 12 (also known as 12 C  6 protons + 6 neutrons; a “light” carbon); The relative amounts are expressed as δ 13 C, which compares 13 C/ 12 C with a laboratory standard. Carbon 13 (aka 13 C  6 protons + 7 neutrons; a “heavy” carbon). 12 and 13 are atomic masses of isotopes 12 C and 13 C. The relative amounts of these two isotopes in a sample of water, air, vegetation is a function of climate/environment 12 C ~99% 13 C ~1% 13 C/ 12 C = 0.01

5 Typical δ 13 C Values in the Climate System δ 13 C values: All land: –25‰ All oceans: 0‰ Enrichment process (isotope fractionation): The lighter 12 C is incorporated in living tissues more easily during photosynthesis.

6 Temperatures over last 400,000 years Carbon dioxide has varied from ~ 180 – 310 ppmv. 385 ppmv (in 2008) Methane has varied from ~ 350 – 800 ppbv; ~ 1790 ppbv (in 2008) Iron Hypothesis: Iron fertilization of ocean biota During glacial periods, more dust  more iron fallout into the oceans  more phytoplankton  more photosynthesis  lower CO 2  colder climate  windier  more dust

7 Feedbacks between dust, climate and CO2

8 Carbon Transfers During Glaciations δ 13 C (carbon transfer) matches δ 18 O (ice volume) cycles. More negative δ 13 C  more positive δ 18 O

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