The Origin of the Atmosphere

1. The Origin of the Atmosphere Intro to Atmospheric Physics 08/26/15 Dr. Chris Moore cmoore@dri.edu

2. http://www.iup.uni-heidelberg.de/institut/studium/lehre/ Atmosphaerenphysik/WS1011/01_Physics_of_the_Atm-WS2010_Intro_tl.pdf

3. How did our atmosphere develop?

4. Geologic time scales Understanding the evolution of the atmosphere involves looking at the development of Earth and planets in general The development of the Earth’s atmosphere is still a hot topic of research with new breakthroughs happening all the time There are two processes governing the development of Earth and the early atmosphere: 1) Accretion 2) Outgassing http://web.eng.ucsd.edu/~pcabrales/research2.html

5. Accretion Earth formed from the Solar Nebula (swirling disk of interstellar dust and hydrogen surrounding the earliest form of the sun) about 4.6 billion years ago Iron and nickel core forms first due to cooling and they solidify at the highest temperature Then continued collisions and differentiation separates areas due to different densities http://facweb.bhc.edu/academics/science/harwoodr/geog102/study/origin.htm

6. Outgassing Process where gases trapped in interior get released Early oceans of hot magma existed on the surface overturning planetary material Volatile gases released from interior CO2 CO H2 N2 H2O Gases remained trapped in a surface layer by gravity Still occurs today through volcano eruptions http://www.globalchange.umich.edu/gctext/Inquiries/Inquiries_by_Unit/Unit_8.htm

7. Early Atmosphere • The early atmosphere was devoid of oxygen (reducing) • There is still debate about when the current oxidizing atmospheric composition developed • Traditionally this was thought to have occurred around 400 million years ago driven entirely by O2 produced from photosynthetic activity

8. Recent developments Atmosphere as we know it (oxidizing) may have actually started forming 4 billion years ago This has large implications for our understanding of the development of life as the current understanding is that life developed during the reducing atmospheric conditions Very interesting area of on-going research…

9. Evolution of Carbon http://butane.chem.uiuc.edu/pshapley/Environmental/L29/2.html

10. Biological Evolution The evolution of the current atmosphere is strongly linked to the evolution of plants to produce the oxygen http://www.snowballearth.org/week13.html

11. http://www.iup.uni-heidelberg.de/institut/ studium/lehre/Atmosphaerenphysik/WS1011/ 01_Physics_of_the_Atm-WS2010_Intro_tl.pdf

12. http://www.iup.uni-heidelberg.de/institut/ studium/lehre/Atmosphaerenphysik/WS1011/ 01_Physics_of_the_Atm-WS2010_Intro_tl.pdf

13. Atmospheric “Floors” Characteristic temperature profiles in the layers http://www.windows2universe.org/earth/Atmosphere/layers_activity_print.html

15. Tropopause Can be defined by temperature changes Can also be defined chemically Lower stratosphere has higher ozone and lower water vapor

16. hectopascal A

19. Atmospheric Pressures It is often easiest to represent the atmosphere via pressure (isobaric) to make equations either to deal Therefore, it’s good to get used to the approximate pressures at different heights

20. Atmospheric Chemistry

24. No. of Different Species

27. Hg biogeochemical cycle From www.mfe.govt.nz

28. Mercury in the Arctic • Fragile Arctic ecosystems • Methyl mercury is a neurotoxic pollutant and accumulates in living organisms • Piscivorous fish • Polar Bears • Whales • Seals Valera et al. 2012 NeuroToxicology; Tian et al. 2011 Environment International

29. Mercury and Ozone in the Arctic Surface Layer From Steffen et al. 2008 ACP

30. Quiz! • Thanks to Thomas Leisner at IUP (Institute of Environmental Physics) Heidelberg for the many slides