The Snowball Earth Hypothesis: Where It Came From, Where It’s Going Linda Sohl Center for Climate Systems Research, Columbia University.

Slides:

Advertisements

Similar presentations

CO2 and Long Term Climate GEOL 1130 Spring Earth-Venus contrast Which planet receives more incoming solar radiation? Which planet absorbs more solar.

Advertisements

The syllabus says: Atmosphere and change  Describe the functioning of the atmospheric system in terms of the energy balance between solar and long- wave.

1.Greenhouse Effect 2.The CO 2 Cycle, Long-Term Climate Change 3.Ice Ages and Short-Term Climate Change 4.Human-Induced Climate Change.

Climate over the long term (Ch highlights)

Reading: Chapter 4 Lecture 25. Snowball Earth vs. Slushball Earth..

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.

OXYGEN ISOTOPES B.C. Schreiber U. Washington Dept. Earth & Space Science To be used only for scholarly purposes, consistent with “fair use” as prescribed.

Lecture 17 Tectonic-scale Climate Change Text book: Ch. 4, p64-67, 71-80, Four Main Processes: –Land-ocean spatial configuration: control where.

Fossils, Paleoclimate and Global Climate Change. Global Warming CO 2 levels in the atmosphere rising Average global temperature is rising Polar ice caps.

Climate Forcing and Physical Climate Responses Theory of Climate Climate Change (continued)

Greenhouse Effect. Thermal radiation Objects emit electromagnetic radiation –The hotter they are, the faster the energy output (  T 4 ) –The hotter they.

Snowball Earth Roopa Kamesh Matt Beversdorf Kathy Groome

Paleoproterozoic Snowball Earth: Earth is glaciated to the equator 2

Snowbal l Earth Roopa Kamesh Matt Beversdorf Kathy Groome.

Global Climate Cycles, Global Warming and Anthropogenic Greenhouse Effect.

Future climate (Ch. 19) 1. Enhanced Greenhouse Effect 2. CO 2 sensitivity 3. Projected CO 2 emissions 4. Projected CO 2 atmosphere concentrations 5. What.

Earth Portrait of a Planet Chapter 23 Norton Media Library.

The importance of Antarctic blue ice for understanding the tropical ocean of Snowball Earth Stephen Warren University of Washington Seattle, USA.

Slushball Earth Neoproterozoic ‘snowball Earth’ simulations with a coupled climate/ice-sheet model (Hyde et al. 2000) Nick Cowan February 2006.

Essential Principles Challenge

Part 7 Ocean Acidification, Weather and Melting Permafrost.

Ice Ages and Climate Change Chestnut Ridge, NY Jan 23 in the year 16,004 BC.

Goals for this section 1.EXPLAIN the feedback mechanism believed to have maintained Earth's average temperature within the range of liquid water over 100s.

Pioneers of Climate Change Research Svante Arrhenius Ralph Keeling Roger Revelle.

Unit 18: Natural Climate Change. OBJECTIVES: Explore the origin and nature of climate change Present Earth’s climatic history prior to the industrial.

Long-Term Climate Cycles &the Proterozoic Glaciations(Snowball Earth) Assigned Reading: Stanley, pp , Hoffman & Schrag (2002) Terra Nova,

Chapter 12 Long-Term Climate Regulation Sun about 30% less luminous than today - Ts would have been below freezing - Earth seems to have had liquid water.

To get to journals electronically: -click on letter corresponding to journal name Or

Climate Systems Chapter 15. Clicker Question What is the approximate CO 2 content of the atmosphere? –A % (40 ppm) –B. 0.04% (400 ppm) –C. 0.4%

The Biogeochemical Carbon Cycle: CO 2,the greenhouse effect, & climate feedbacks Assigned Reading: Kump et al. (1999) The Earth System, Chap. 7.

Plate Tectonics and Global Glaciation Tectonic plate motions move the continents and determine the form of the ocean basins. Paleoclimatologists have suggested.

Samayaluca Dune Field, south of Juarez, Chihuahua Global Climate Change.

Global Climate Change Prediction and Feedback mechanisms.

Snowball Earth Hoffman et al. Science Evidence.

Samayaluca Dune Field, south of Juarez, Chihuahua Global Climate Change.

Extreme Climate Change: The late Neoproterozoic “Snowball Earth”

Global connections between aeolian dust, climate and ocean biogeochemistry at the present day and at the last glacial maximum Maher et al., 2010, Earth-Science.

Evolution of the Earth David Spergel. Evolution of Earth’s Atmosphere  Earth lost its early atmosphere in major collisions (first Myr)  Subsequent.

Chapter 11 Orbital-Scale Changes in Carbon Dioxide and Methane Reporter : Yu-Ching Chen Date : May 22, 2003 (Thursday)

Late Proterozoic Snowball Earth Brian Morgan Colby College December 3, 2012.

Evidence of Global Warming and Consequences

Snowball oceanography. What is Snowball Earth? Most extreme climate event in Earth history. Characteristics: Occurred at least twice between Ma.

Methane in the atmosphere; direct and indirect climate effects Gunnar Myhre Cicero.

The Faint Young Sun Problem. Systems Notation = system component = positive coupling = negative coupling.

CO 2 and Climate Change. Lisiecki & Raymo,

SC.912.E.7.2: Analyze the causes of the various kinds of surface and deep water motion within the oceans and their impacts on the transfer of energy between.

“SNOWBALL EARTH”: IMPLICATIONS FOR THE EVOLUTION OF COMPLEX LIFE AND EXOPLANET HABITABILITY Jonathan Chin 1, Sadchla Mathieu 2, Jayanthi Ramaswamy 3, and.

Willie Soon. Introduction 1. The relationship between atmospheric CO2 and CH4 concentrations, temperature, and ice-sheet volume 2. Atmospheric CO2 radiative.

16-1 Environmental Geology James Reichard Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Ice Ages. From the Last class, this implies a change of /160 = 4% change in the incoming solar constant – this is too small of variation.

The Greenhouse Climate. We Know the Last 100 Myr Pretty Well… Why? Know –Continental Positon –Shape of the Ocean Basins –Temperature –Sea Levels.

Glacial Landscapes.

i) Oxygen isotopes and climate /Kepler’s laws

How’s it going to end? Climate evolution on Mars and Venus and its bearing on the very long term fate of the Earth’s climate system.

Snowball Earth History of Glaciation. Main Periods of Glaciation Huronian glaciations billion years ago Late Proterozoic glaciations million.

The Surface of the Ice-Age Earth

Damian Gosch, Kyle Brown, and Jennifer McIntosh Department of Hydrology and Water Resources University of Arizona Outburst Flooding of Proglacial Lake.

Habitability: Making a habitable planet 26 January 2016.

Schematic framework of anthropogenic climate change drivers, impacts and responses to climate change, and their linkages (IPCC, 2007).

Long-Term Climate Cycles & The Proterozoic Glaciations (‘Snowball Earth’) Assigned Reading: Hoffman & Schrag (2002) Terra Nova, Vol. 14(3): Lubick.

Earth’s Climate History. Climate v. Weather Climate: The meteorological conditions, including temperature, precipitation, and wind, that characteristically.

A snowball Earth versus a slushball Earth: Results from Neoproterozoic climate modeling sensitivity experiments Micheels and Montenari (2008) By: Madeline.

Our water planet and our water hemisphere

A snowball Earth versus a slushball Earth:

Snowball Earth vs. Slushball Earth..

Introduction to Ecology

Modelling Ancient Earth Climates Manchester Geologist Association

Overview of “Snowball Earth”

Snowball Earth! Hot House Earth!

Presentation transcript:

The Snowball Earth Hypothesis: Where It Came From, Where It’s Going Linda Sohl Center for Climate Systems Research, Columbia University

Low-Latitude Glaciation in the Neoproterozoic: The World’s Most Severe Ice Age?

Media Blitz!

A step back in time

Signs of cold climates…

… followed by rapid warming?

Distribution of Neoproterozoic glacial deposits (Evans, 2000)

And so the debates begin… Harland (1964) proposes the existence of a “great Infracambrian glaciation” The community disagrees - vehemently!

Distribution of climate-sensitive sediments

The debates continue… Numerous debates over veracity of the glacial nature of sediments Astrophysicists and geophysicists weigh in Improvements in paleomagnetic techniques lead to many tests of “low-latitude glaciation”

Father of the Snowball Earth

The Original Snowball Earth Hypothesis (Kirschvink, 1992) Concentration of continental land masses at low to mid-latitudes led to global cooling by impacting planetary albedo Widespread pack ice led to ocean stagnation, resulting in the return appearance of banded iron formations for the first time in > 1 billion years

Paleomagnetic Data – Trezona Bore Section, Flinders Ranges (Sohl et al., 1999)

Summary of Paleomagnetic Results from the Elatina Formation, Central Flinders Ranges, South Australia A) B) A) For 58 sites: In situTilt-Corrected Dm = 213.9˚Dm = 212.1˚ Im = -20.6˚Im = -16.9˚ k = 7.1k = 9.9  95 = 7.6˚  95 = 6.2˚ B) For 3 sections: In situTilt-Corrected Dm = 223.1˚Dm = 214.9˚ Im = -17.9˚Im = -14.7˚ k = 11.5k = 94.9  95 = 38.1˚  95 = 12.7˚ In situTilt-Corrected (Sohl et al., 1999)

Paleolatitude of Australia During the Marinoan Glaciation Location of glacial deposits (Sohl et al., 1999)

Founder of the “new” snowball Earth

The New Snowball Earth Hypothesis (Hoffman et al., 1998) Primarily intended to account for carbon isotopic data (  13 C = 0 to -5‰) in cap carbonates Suggests that carbon isotopic values reflect mantle values in an ocean isolated from the atmosphere

The Snowball Earth (Hoffman and Schrag, 2000)

Snowball Earth Hypothesis: Freezing Phase Primary productivity in surface ocean ceases Surface ocean entirely frozen over (runaway ice albedo feedback; suggested by energy balance models) Atmospheric CO 2 increases to ~120,000 ppm owing to virtual shut-down of hydrological cycle and silicate weathering

Snowball Earth Hypothesis: Melting Phase Catastrophic melting of ice driven by greenhouse effect Renewed silicate weathering draws down atmospheric CO 2, and delivers needed alkalinity and base cations to ocean. Precipitates Carbonate. Cap carbonate records transfer of excess atmospheric CO 2 to the oceans Trend of increasing carbon isotopic depletion upwards in the cap carbonates is due to Rayleigh distillation

Problems with the new Snowball Earth Necessary continental configuration not applicable to both glacial intervals Estimate of duration of glacial interval based upon incorrect basin subsidence calculations No evidence for mass extinctions Glacial sediments cannot be created in absence of hydrologic cycle, and are too voluminous to be created solely at the end stage of glaciation Iron formations are limited in occurrence

Is a “hard” Snowball Earth really necessary? One alternative explanation for carbon isotope excursions - the methane clathrate hypothesis - negates the need for a totally frozen surface ocean

Methane hydrate (Mahajan, 2007)

(Courtesy USGS)

Methane Hydrate Hypothesis (Kennedy et al., 2001) Methane hydrates may have been more abundant during the Proterozoic ice ages than any other time in Earth history –Coldest intervals in Earth history –Abundant area available for permafrost development –Rapid flooding of continental basins and shelves

Modern Cold Seep Features Recovered secondary hydrates from the Cascadia Margin (Bohrmann et al., 1998)

Cold Seep Facies in Cap Carbonates Brecciation Cement-lined cavities Internal sediment fill Deep water depositional setting 10 cm

Isotopic Evidence from the Congo Craton Values indicate a rapid excursion and long-term recovery Cap carbonate deposition occurred over a brief interval (likely <10 k.y.) Time ModelStratigraphic Section

Isotopic Evidence for Clathrate Destabilization Predictions: Rapid release of depleted  13 C (~- 60‰) produces an instantaneous drop in marine  13 C Return to normal values takes several residence times of C (>100,000y) (Kump, 1991)

But wait - there’s more! New paleomagnetic data from cap carbonate in Australia presents a different time scale for the end of glaciation New age dates suggest that there may be only one true Neoproterozoic snowball glaciation Climate models present a range of possible environmental conditions, depending on the model and starting assumptions

Using the GISS GCM to simulate Neoproterozoic climates Forcings investigated include decrease in solar luminosity, continental configuration, atmospheric CO2 levels, and ocean heat transports

GISS GCM Simulation results Only most extreme combination of forcings permits the growth of ice sheets on land; surface ocean does not freeze over

Summary The “hard” Snowball Earth hypothesis (Hoffman et al., 1998; Hoffman and Schrag, 2000) is incorrect on key points A “slushball” Earth likely presents a better portrait of the environment circa 640 million years ago