Presentation is loading. Please wait.

Presentation is loading. Please wait.

PTYS 214 – Spring 2011  Next week is Spring Break – NO CLASSES  Class website: /

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "PTYS 214 – Spring 2011  Next week is Spring Break – NO CLASSES  Class website: /"— Presentation transcript:

1 PTYS 214 – Spring 2011  Next week is Spring Break – NO CLASSES  Class website: http://www.lpl.arizona.edu/undergrad/classes/spring2011/Pierazzo_214 /  Useful Reading: class website  “Reading Material” http://www.pnas.org/content/96/20/10955.full http://en.wikipedia.org/wiki/Mass-independent_fractionation http://en.wikipedia.org/wiki/Fossil_record_of_fire http://en.wikipedia.org/wiki/Great_Oxygenation_Event Announcements

2 Midterm  Total Students: 30  Class Average: 72.6  Low: 35  High: 103 Midterm is worth 20% of the grade

3 Early Life Summary Evidence of the earliest life on Earth is difficult to prove: –Isotopic evidence seems to date it back to about 3.5 Gyr (Pilbara craton, Australia) –Oldest stromatolites are about 3.46 Gryr old –Earliest microfossils (accepted) date back to about 2.55 Gyr (Transvaal Supergroup, South Africa) –Earliest molecular biomarkers date back to about 2.5-2.7 Gyr old rocks (Pilbara, Australia)

4 Atmospheric Oxygen All terrestrial life requires energy, carbon and nutrients, and liquid water Why is atmospheric oxygen important for life? 1.All terrestrial multicellular life requires high O 2 CH 2 O + O 2 → H 2 O + CO 2 + energy 2.Almost all terrestrial life requires some protection from UV

5 Ozone: the Good and the Bad 90% 10%

6 Stratospheric Ozone Most of the ozone is in the stratosphere (above 15 km) Production: O 2 + (UV radiation < 240 nm) → 2 O O + O 2 → O 3 Destruction: O 3 + (UV radiation 240-310 nm) → O 2 + O O 3 + O → 2O 2 The Good Stratospheric ozone absorbs part of the UV spectrum (<310 nm) where other gases do not absorb  That’s why ozone in stratosphere is good for us UV-C UV-B UV-C

7 Tropospheric Ozone In the troposphere ozone is the result of pollution: OH + CO pollution → H + CO 2 H + O 2 → HO 2 HO 2 + NO pollution → OH + NO 2 NO 2 + hν → NO + O O + O 2 → O 3 Net reaction: CO + 2O 2 → CO 2 + O 3 The Bad Ozone is a very chemically active gas and can cause eye and respiratory problems

8 Both O 2 and O 3 are important to the biosphere but O 3 cannot form without O 2 What are natural sources of O 2 ?  Volcanoes: NO Major volcanic gases are H 2 O, CO 2, SO 2 etc., but no O 2  Today the major source of O 2 is LIFE H 2 O + CO 2 → CH 2 O + O 2 Atmospheric Oxygen! Mt. Pinatubo eruption, 1991

9 Oxygen Sources CO 2 +H 2 O  O 2 + CH 2 O 2H 2 O+hν  O 2 + 4H Space Ocean Atmosphere Hydrogen escape Organic carbon burial Photosynthesis Water dissociation (minor)

10 Oxygen Sinks Oxidation of reduced gases O + H 2 O  H 2 O 2 SO 2 + H 2 O 2  H 2 SO 4 Oxidative weathering of rocks Fe 2+  Fe 3+ (FeO  Fe 2 O 3 ) Atmospheric O 2 Outgassing (volcanoes) SO 2, H 2 S, H 2 Aerobic Respiration CH 2 O+O 2  CO 2 + H 2 O Methane Oxidation CH 4 + O 2  CO 2 + 2H 2 Ocean Land

11 Changes in Oxygen Abundance Oxygen abundance in the atmosphere is a result of the balance between sources and sinks The atmosphere does not have much mass  Any lack of balance in sources vs. sinks results in the immediate changes of the atmospheric oxygen

12 When did life start to produce O 2 ? Molecular biomarkers  Earliest biomarkers for cyanobacteria and eukaryotes: ~ 2.5 -2.7 Gyr ago Maybe some photosynthetic O 2 flux occurred 2.7 Gyr ago Geologic Evidence  Atmosphere with low oxygen until about 2.3 Gyr ago: –BIFs (Banded Iron Formations) –Detrital Uraninite and Pyrite –Paleosols and Redbeds –Sulfur Isotope Ratios

13 2.47 Gyr old Brockman Iron Formation, Western Australia Alternating iron-rich layers and iron- poor shale or chert layers Iron-rich: include iron oxides (Fe 3 O 4 or Fe 2 O 3 ) formed in the oceans by combining oxygen with dissolved iron Iron-poor: deep ocean should have been anoxic, causing deposition of shales and cherts BIFs Varying O 2 amount

14 Rounded detrital uraninite from ca. 2.7 Ga Witwatersrand Basin, South Africa Rounded detrital pyrite from ca. 2.6 Ga Black Reef Quartzite, South Africa Uraninite (UO 2 ) and pyrite (FeS 2 ) are unstable under high O 2 levels in the atmosphere  If in contact with the atmosphere (detrital), they can only form in an O 2 -poor atmosphere Detrital Uraninite and Pyrite

15 Hekpoort Paleosol, South Africa (about 2.22 Gyr old) Paleoproterozoic Redbeds, ON, Canada Reddish color is due to hematite (Fe 2 O 3 )  presence of O 2 Oldest Redbeds are about 2.3 Gyr old Paleosols prior to 2.3 Gyr ago lost their iron (no oxygen to form hematite) Paleosols and Redbeds

16 Normally, isotopic ratios of an element follow a standard mass fractionation line (MFL):  33 S  0.515 ×  34 S  Prior to 2.5 Gyr ago the isotope ratios fall off the MFL line!  33 S =  33 S - 0.515 ×  34 S  0 Sulfur Mass-Independent Fractionation Farquhar et al. 2001 3.3 – 3.5 Gyr old samples S-isotopes: 32 S  95% 33 S  <1% 34 S  4 % 36 S  trace  33 S>0.515  34 S  33 S<0.515  34 S

17 Kump (2008) Nature 451, p.277-278  Large Sulfur MIF effects are associated with photochemical reactions (involving UV radiation)  Sulfur MIF can only occur in an oxygen-free atmosphere  33 S =  33 S - 0.515×  34 S Sulfur Mass-Independent Fractionation

18 The O 3 layer should have been absorbing most UV radiation by 2.3 Ga, as soon as O 2 levels began to rise What About Ozone (O 3 )? O 2 rise causes O 3 rise! An O 2 level of 1% PAL is sufficient to create a sufficient ozone screen

19 Oxygen was in the atmosphere by 2 Gyr ago However, life was limited to unicellular organisms or very simple multicellular organisms until ~540 Myr ago The oldest known possible multicellular eukaryote is Grypania (~1.9 Gyr old) Slow Early Evolution…

20 All known complex multicellular organisms need at least 10-20% of the present oxygen Cambrian Explosion About 540 Myr ago there was a seemingly rapid appearance of complex multicellular organisms (all we really know about it comes from two main locations!)

21 Forest Fires and Atmospheric Oxygen CH 2 O + O 2 → CO 2 + H 2 O Fires produce charcoal that is preserved in the geologic record

22 There has been a continuous record of charcoal in sediments younger than 360 million years old  O 2 levels have not been lower than 15% during the past 360 million years Present Atmospheric Level 0% 10% 20% 30% Atmospheric oxygen 21% 15% Fire

23 Summary of the O 2 Constraints (Goldblatt et al., 2006) Great Oxidation Event Low-Fe Paleosols Redbeds Detrital Uraninite Pyrite BIFs Eucaryotes P.A.L. = Present Atmospheric Level

24 Atmospheric Oxygen Summary ~1ppm No O 2 /O 3 A few% 15-35%

25 Major steps in the evolution of life Phanerozoic Eon (542 Myr ago - present) “Visible life” (macroscopic animals and plants) Proterozoic Eon (2.5 – 0.54 Gyr ago) Mostly single-celled and some primitive multicellular organisms Archean Eon (3.5? - 2.5 Gyr ago) Single-celled organisms, prokaryotes (cyanobacteria) and some eukaryotes

26 Phanerozoic Eon Paleozoic Era (250-540 Myr ago) - Cambrian, Ordovician, Silurian, Devonian, Carboniferous, Permian periods - Age of sea life (trilobites) Mesozoic Era (65-250 Myr ago) - Triassic, Jurassic, Cretaceous periods - Age of dinosaurs Cenozoic Era (0-65 Myr ago) - Paleogene, Neogene periods - Age of mammals

27 The fossil record of biodiversity Species: ability to interbreed, producing fertile offsprings similar morphology (body shape) or DNA Species always form and die due to genetic mutations and natural selection

28 On average, 10 - 25 new species originate and become extinct each year Change in number of species = origination rate - extinction rate Logistic Growth Curve

29 No logistic growth curve in the fossil record! Why?

30 Sampling bias! There are much more recent rocks than ancient rocks available to study Possible alternative: Minimize sampling bias by looking at higher taxonomic groups Species Crust Sediments

31 Taxonomy Specie: Homo Sapiens ( all people ) Genus: Homo ( humans and close relatives ) Family: Hominidae ( “great apes”: humans, chimpanzees, gorillas, orangutans ) Order: Primates ( all apes and monkeys ) Class: Mammalia ( mammary and sweat glands ) Phylum(division): Chordates ( vertebrates ) Kingdom: Animalia ( moving consumers ) Domain: Eukarya ( complex cells )

32 Complex Life Earth-like complex life requires not only energy, water, nutrients and carbon but also oxygen and ozone (UV protection) Suppose the environment has everything indicated above (Phanerozoic eon) Does it mean that the animal life will evolve smoothly? No!

33 Mass Extinction Sharp decrease in the number of species in a relatively short period of time 1)It must be a rapid event (from less than 10,000 to 100,000 years) 2)A significant part of all life on Earth became extinct (use of families is more reliable than species; for example extinction of 18% of all families corresponds to about 40% of all genera and 70% of all species) 3)Extinct life forms must have came from different phyla, lived in different habitats, spread out over the whole world

Download ppt "PTYS 214 – Spring 2011  Next week is Spring Break – NO CLASSES  Class website: /"

Similar presentations

Concept 25.3: Key events in life’s history include the origins of single-celled and multicelled organisms and the colonization of land The geologic record.

Concept 25.3: Key events in life’s history include the origins of single-celled and multicelled organisms and the colonization of land The geologic record.
Geologic Time Jeopardy $100 $200 $300 $400 $500 $100$100$100 $200 $300 $400 $500 The Dating Game Mass Extinctions Time. Period. Fossils Wild Card FINAL.

Geologic Time Jeopardy $100 $200 $300 $400 $500 $100$100$100 $200 $300 $400 $500 The Dating Game Mass Extinctions Time. Period. Fossils Wild Card FINAL.
Earth Systems and Resources

Earth Systems and Resources
Copyright Pearson Prentice Hall

Copyright Pearson Prentice Hall
Unit 2 Review: History of Life on Earth

Unit 2 Review: History of Life on Earth
Precambrian Era (put these events in order) Photosynthetic Cyanobacteria (blue-green algae) create oxygen gas which began to form our atmosphere Oceans.

Precambrian Era (put these events in order) Photosynthetic Cyanobacteria (blue-green algae) create oxygen gas which began to form our atmosphere Oceans.
The Cladogram The cladogram is used to show evolutionary relationships between organisms, NOT ancestry. The human shares more DNA with the Chimpanzee than.

The Cladogram The cladogram is used to show evolutionary relationships between organisms, NOT ancestry. The human shares more DNA with the Chimpanzee than.
Fossils and Earth’s History Notes

Fossils and Earth’s History Notes
Monday December 9,2013 Do Now: Iron oxides are chemicals composed of iron and oxygen. Scientist found that sedimentary rocks prior to 3.5 billion years.

Monday December 9,2013 Do Now: Iron oxides are chemicals composed of iron and oxygen. Scientist found that sedimentary rocks prior to 3.5 billion years.
3.2 Fossils and the Evolution of life  Major stages in evolution of life  The changing atmosphere  Other ideas about origins of life.

3.2 Fossils and the Evolution of life  Major stages in evolution of life  The changing atmosphere  Other ideas about origins of life.
The Early history of Earth! After the Earth formed…about 4.6 Billion years ago… …The Earth melted and differentiated into Core, Mantle, and Crust.

The Early history of Earth! After the Earth formed…about 4.6 Billion years ago… …The Earth melted and differentiated into Core, Mantle, and Crust.
Chapter 11 Effect of Life on the Atmosphere: The Rise of Oxygen and Ozone.

Chapter 11 Effect of Life on the Atmosphere: The Rise of Oxygen and Ozone.
Evolution of the Atmosphere, Oceans, Continents. Evolution of Atmosphere, Ocean, & Life We will address the following topics.... Evolution of Earth’s.

Evolution of the Atmosphere, Oceans, Continents. Evolution of Atmosphere, Ocean, & Life We will address the following topics.... Evolution of Earth’s.
Astronomy190 - Topics in Astronomy Astronomy and Astrobiology Lecture 13 : Life’s History Ty Robinson.

Astronomy190 - Topics in Astronomy Astronomy and Astrobiology Lecture 13 : Life’s History Ty Robinson.
Geologic Timescale.

Geologic Timescale.
CLIMATE CHANGE THE GREAT DEBATE Session 2. EARTH HISTORY 4567 Ma to 2.5 Ma No rocks are left that date back to the beginning of the Earth. Oldest known.

CLIMATE CHANGE THE GREAT DEBATE Session 2. EARTH HISTORY 4567 Ma to 2.5 Ma No rocks are left that date back to the beginning of the Earth. Oldest known.
Tree of Evolution Conditions of Early Earth (greater radiation and igneous activity) lead to the synthesis of abiotic (non-living) molecules – nucleic.

Tree of Evolution Conditions of Early Earth (greater radiation and igneous activity) lead to the synthesis of abiotic (non-living) molecules – nucleic.
Copyright © 2014 All rights reserved, Government of Newfoundland and Labrador Earth Systems 3209 Unit: 2 Historical Geology Reference: Chapters 6, 8; Appendix.

Copyright © 2014 All rights reserved, Government of Newfoundland and Labrador Earth Systems 3209 Unit: 2 Historical Geology Reference: Chapters 6, 8; Appendix.
Origins of the Atmosphere

Origins of the Atmosphere
Chapter 19 The History of Life.

Chapter 19 The History of Life.

Similar presentations

Ads by Google