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Climate Records from Ice Cores Major Points • Ice cores have provided the best record of climate change over the last 700K years. • The most important climate characteristics recovered from ice cores are air temperature, atmospheric CO2 and CH4 concentrations and dust. • One key unanswered question is the cause of the atmospheric CO2 shifts between glacial and interglacial periods. • Another key question, still not completely answered, is the sequence of events that occur that cause the earth to shift from glacial to interglacial periods. 1 Ice Core Drilling Depths 2 Dome C, Antarctica 3 Tools of the Trade L L L L L 4 Ice Core Drill 5 Ice Core Recovery 6 Ice Cores from Greenland Firn Ice Compact Ice Bedrock 7 Antarctica Drilling Sites 60 °S 70 Dronning Maud Land °S Berkner Island Dom e F °S 80 Byrd Vostok Law Dom e Dom e C Siple Dom e Taylor Dom e 0km 1,000km 2,000km 8 Ice Cores and Ice Sheet Flow 9 Age of Ice: annual layers (Greenland) and ice flow models (Antarctica) ΔTemp/Δd18O = ~1.4ºC / 1‰ d18O (‰) d18O of Today’s Precipitation vs Air Temperature ΔTemp/ΔdD = ~0.2ºC / 1‰ 10 Effect of Condensation on the d18O (and dD) of Precipitation 11 Borehole Temperature Record in Ice Cores Scientists measure the temperature of an ice sheet directly by lowering a thermometer into the borehole that was drilled to retrieve the ice core. Like an insulated thermos, snow and ice preserve the temperature of each successive layer of snow, which reflects general atmospheric temperatures when the layer accumulated. 12 d18O versus Borehole Paleothermometry a controversy in Greenland Ice Cores (DTemp/Dd18O= 1.5 ºC / ‰) Current Precipitation DTemp/Dd18O= 3 ºC / ‰ Borehole Temps Climate scientists favor the borehole temperature changes. 13 Greenland Drilling Sites 14 Greenland Ice Core d18O and Temperature Record Using borehole temperature vs d18O 15 calibration Temperature Swings between Glacial and Interglacial Conditions ΔT* 36 24 21 *BH corr’n ΔTemp/Δd18O about equal for borehole and precipitation in Antarctica 16 Reconstructing Atmospheric Gas Concentrations from Ice Cores • Use trapped air bubbles as preserved samples of atmosphere. • Measure the concentration of important (greenhouse) atmospheric gases on the trapped air bubbles (e.g., CO2, CH4, N2O) 17 Trapping Air Bubbles in Ice Snow Accumulation Rates Greenland = 0.5 m/yr Antarctica = 0.05 m/yr 18 How does age of air bubbles compare to age of ice? • Determine the age of the ice (annual layer or flow model). • Determine the age of the trapped air bubble. -bubble age doesn’t equal ice age, it’s younger. • How long does it take for the ice to seal? - ~50 meters divided by snow accumulation rate - 50m / 0.5 m/yr = ~100 yrs in Greenland - 50m / 0.05 m/yr = ~1000 yrs in Antarctica • Why is this lag between ice and bubble ages important? 19 Industrial Era Changes in Atmospheric CH4 and CO2 Extending the record of industrial era change Test of accuracy of ice core gas measurements 20 Atmospheric Methane (CH4) • A greenhouse gas and climate indicator. • Natural (pre-anthropogenic) CH4 sources are dominated by emissions from wetlands (swamps, tundra, bogs, etc.). • Biogenic methane is produced by microbes under anoxic (no oxygen) conditions. CO2 + H2 CH4 + H2O CH2COOH CH4 + CO2 • Methane Hydrates (?) 21 Atmospheric Methane • The primary sink for atmospheric CH4 is reaction with OH radicals in the atmosphere. CH4 + OH• CO2 + H2O • Currently, CH4 has a ~10 year lifetime in atmosphere. • Methane is a reactive gas in the atmosphere, in contrast to CO2 which is a non-reactive gas. 22 Methane as Climate Indicator • Source strength depends on extent of wet soil conditions (opposite of aridity) • Extent of wet soils controlled primarily by precipitation rates and patterns (climate). • In cold (tundra) regions, temperature likely has major role on CH4 emission strength. • The ocean has small role in the CH4 cycle (in contrast to CO2). 23 Atmospheric Methane from Antarctic Ice Cores CH4 concentration doubles between glacial and interglacial conditions CH4 changes correlate strongly with temperature changes 24 Methane as Climate Indicator • During interglacial times, the earth was generally wetter (higher precipitation) than during glacial times, which increased the spatial extent of flooded soils and in turn the biogenic production rate of methane and its concentration in the atmosphere. • Currently unclear whether this increase in precipitation was global or regionally specific (e.g., role of monsoons?). Where did increased methane production occur (tropics, temperate, polar latitudes)? • Methane concentration in atmosphere contributes to greenhouse gas warming effect. 25 Atmospheric Carbon Dioxide (CO2) • Dominant greenhouse gas that has played a key role in changing the earth’s climate in the past (e.g., Snowball Earth, Cretaceous Hothouse). • What can we learn about our future climate change, in a world of high atmospheric CO2 levels, from climate changes over the last 700K years when atmospheric CO2 levels oscillated by ~40%? 26 Atmospheric CO2 and Temperature from an Antarctic Ice Core Atmospheric CO2 levels increase by 40% between glacial and interglacial times. Strong correlation between CO2 and temperature changes. 27 Atmospheric CO2 and Ice Volume Records - CO2 from Ice Cores - Ice Volume from d18O of marine CaCO3 - What is implication of strong correlation? 28 What causes the Glacial-Interglacial shifts in atmospheric CO2? • No clear answer yet. (one of the Holy Grails) • Involves a change in the earth’s carbon cycle. • Very likely that changes in the ocean are involved. 29 Carbon Reservoir Changes and Exchange Rates Changes in Reservoir Sizes (Pg, %) Interglacial to Glacial Carbon Exchange Rates (Pg/yr) Deep Ocean accumulates the carbon lost from the atmosphere and land biota during glacial times. 30 Ocean- Atmosphere CO2 System • There is much more CO2 in the ocean (38,000 Pg C) compared to the atmosphere (600 Pg C). • Thus the concentration of CO2 in the ocean controls the concentration of CO2 in the atmosphere. (CO3= + CO2 + H2O 2HCO3-) • Air-sea CO2 gas exchange is the process that links the CO2 concentrations in the atmosphere and ocean. 31 d13C as a Tracer of Changes in the Earth’s Carbon Cycle Size and d13C of C Reservoirs d18O and d13C in CaCO3 Sediments d13C (‰)= [(13C/12C)sample/(13C/12C)standard – 1)*1000 32 (Standard = PDB carbonate) Correlation between d13C and d18O changes in CaCO3 Record Benthic = open circle Pelagic = filled circle d13C is lower during Glacial versus Interglacial conditions 33 Using d13C as a Carbon Cycle Tracer • Changes in the d13C of the ocean CaCO3 record indicate that there was a significant change in the earth’s carbon cycle during Glacial vs Interglacial times. • The d13C of CaCO3 in benthic forams decreased by ~ -0.3 to -0.4 ‰ (avg. Ruddiman) during glacial times. • If this glacial ocean d13C decrease was the result of a transfer of terrestrial organic carbon to the ocean, we can calculate how much carbon was transferred using d13C. (How was it transferred?) 34 Quantify the Amount of Terrestrial Carbon Transferred to Ocean • Carbon Mass and Isotope Budget Interglacial Ocean Carbon + Terr Carbon Added = Glacial Ocean Carbon (38,000 PgC) (0 ‰) + ( Terr C added) (-25 ‰) = (38000+ Terr C added)(-0.35 ‰) • Terrestrial Carbon added = 524 Pg C • This estimate roughly agrees with estimates based on the loss of vegetation and soils during the growth of continental ice sheets. 35 Effect on Atmospheric CO2 • What effect will this ocean inorganic carbon increase have on atmospheric CO2 concentrations? -increases CO2 in the atmosphere (~ 2 ppm) • (Remember: ocean CO2 controls atmospheric CO2) • This is opposite to the trend observed in ice cores Interglacial CO2 = 280 ppm Glacial CO2 = 190 ppm • Some other change in Earth’s carbon cycle caused lower CO2 levels during Glacial times. 36 Why did the atmospheric CO2 decrease by 90 ppm during glacial times? • Don’t know yet…. but a lot of smart people are trying to figure it out. • It’s very likely that the mechanism lies in the ocean. • It is likely a combination of physical, biological and chemical changes to the ocean that cause the CO2 level in the ocean (and thus atmosphere) to change. 37 Mechanism: Change CO2 Solubility in Seawater • CO2 gas solubility depends inversely on temperature – Increases by ~4% per 1ºC cooling – Cool surface ocean by 2.5 ºC lowers pCO2 by –22 ppm • CO2 gas solubility depends inversely on salinity – Increase salinity by ~ 1 ppt increases pCO2 by ~11 ppm – Why does ocean salinity increase during Glacial times? Net Effect: – 11 ppm 38 Mechanism: Increase the Ocean’s Photosynthesis Rate during Glacial Times • Photosynthesis consumes CO2 CO2 + H2O CH2O (sugar) + O2 • Currently there are a lot of nutrients in the surface waters of the Southern Ocean that could be utilized • Hypothesis: Increase supply rate of iron to the ocean -iron is a trace nutrient that plankton need and is thought to limit photosynthesis rates in the Southern Ocean “Give me half a tanker of iron, and I’ll give you the next Ice Age” (John Martin, ~1990) 39 Current Distribution of Photosynthesis in the OPPestimated P1 December 10,Data 2000 Ocean from Satellite Falkowski Behrenfeld depth integrated model calculates total euphotic zone productivity to 1% surface irradiance. Primary inputs are PAR, SST, Chlor_a_3. Units gm Carbon/m2/yr. 40 Current Distribution of Nitrate in Surface Pacific Ocean Purple = high nitrate Green = low nitrate Unused nutrients in Southern Ocean 41 Increase in Dust in Ice Cores Prior to Glacial to Interglacial Transition Dust contains iron 42 Current CO2 Level Possible Ocean Photosynthesis effects on Atmospheric CO2 43 Mechanism: Make the Surface Ocean More Alkaline during Glacial Times • Key Reaction: CO2 + H2O + CO3= 2 HCO3-an increase in CO3= concentration will decrease CO2 • Change CO3= by changing the ratio of biological organic carbon (CH2O) to CaCO3 production and sedimentation -if diatoms were favored over forams during glacial times there would be less CaCO3(s) production and an increase in CO3= concentration (iron supply favors diatoms) • Change CO3= by increasing supply of CO3= ion to the surface of Southern Ocean by a change in ocean circulation rates and/or pathways 44 Possible Ocean Mechanisms to Reduce Atmospheric CO2 45 d13C as a tracer of Ocean Photosynthesis 46 Record of d13C depth gradient in the Ocean d13C of pelagic CaCO3 minus d13C of benthic CaCO3 Some evidence for increased ocean productivity during glacial times. 47 What effect would these ocean changes have on atmospheric pCO2? pCO2 (Glacial) = 190ppm (Qualitative) pCO2 (Interglacial) = 280 ppm 48 Where do we stand? • Currently, model calculations that attempt to simulate the biological, chemical and physical changes in the ocean during the LGM cannot reproduce the glacial concentrations of atmospheric CO2 found in ice cores and independent evidence of ocean change. • Thus our current understanding of the processes controlling the earth’s carbon (CO2) cycle on glacial to interglacial time scales is incomplete. 49 Ice Core Records over last 750K years • Critical climate record: – air temperature – atmospheric gas concentrations (CO2, CH4, N2O, O2) – Dust (iron supply?) – Marine aerosols • What do ice core records tell us about links between temperature change and forcing? • What do ice core records tell us about sequence of climate events during transition from glacial to interglacial conditions? 50 Ice Core Records from Vostok, Antarctica Repeating ‘sawtooth’ patterns. Why? Consistent limits for temp and gases. Why? (Petit et al., 1999) Petit et al., 1999 51 Termination II at 120K yrs Glacial Terminations What was sequence of climate events that ended glacial eras? What about gas age vs ice age offset? 52 Higher Resolution Record during Termination Does temperature rise in Antarctica precedes global CO2 and CH4 rise? Monnin EPICA Dome C (Science 2001) 53 Timing during Termination I 20 10 5 2 1 -380 260 -400 240 -420 220 -440 dD (‰) CO 2 (ppm) Taylor Dome nss-Ca 2+ flux (ng/cm2/yr) 50 200 180 10000 12000 14000 16000 Age (yr BP) 18000 20000 Does temperature change precede CO2 change? How important is dust? 54 Röthlisberger et al., GRL, 2004 Sequence of Events during Termination • Insolation increase at high latitudes • Dust increases, then Temperature, CO2, CH4 increases • Ice Volume decreases • No single change (e.g., insolation, greenhouse gases, albedo) can account for the observed temperature change. • Several processes must act together to amplify initial climate change trigger. 55 EPICA Antarctic Ice Core (going back to 750K yrs) -360 EPICA Dome C dD / ‰ -400 -440 Vostok -480 0 200 400 600 800 Age / kyr BP 56 Reduced Temperature Cycles >400K yrs dD / ‰ -370 -390 WARM -410 9 C -430 COLD -450 0 200 400 Age / kyr before present 600 Interglacials were less warm at > 400K yrs 800 57 Weak Interglacials have lower CO2 Vostok Siegenthaler et al., Science 2005 (EPICA gas consortium) 58 Weak Interglacials have lower CH4 Spahni et al., Science 2005, EPICA gas consortium 59 CO2 predicted (Mudelsee) Temperature and CO2 are tightly coupled 300 240 CO2 predicted (Mudelsee) 180 300 0 200 400 600 200 400 600 240 180 0 Mudelsee (based only on Vostok data): pCO2 = 922 + 1.646 * δDt-2000 What does ability to accurately predict CO2 from Antarctic temperatures tell us about the role of CO2 in temperature change? 60 Tight Coupling between Temperatures in Antarctica and global CO2 levels • Why are temperature and CO2 so tightly (linearly) coupled when other feedbacks (albedo, ocean heat transfer, etc.) are needed to explain temp change? • Global CO2 levels controlled by ocean. • Unused surface nutrients present in Southern Ocean. • Air temperatures in Antarctica impacted by heat released in Southern Ocean. • Does a change in circulation and productivity in Southern Ocean provide the link between earth’s radiation budget and CO2 cycle? 61 Termination V (450K yrs BP) • CO2 increase precedes temperature and CH4 increase and dust decrease. • Different from 20K termination sequence. • Errors in ice age and bubble age? 62 Where do we stand? • Glacial/Interglacial changes in temperature and atmospheric CO2 and CH4 levels show an extremely tight correlation. • Change sequence looks like Solar Insolation, Dust, Temperature, CO2/CH4 and, finally, Ice Volume (except Termination V at 450K). • Earth’s climate feedback system has keep range in temperatures very consistent over the last 750K yrs. • Increasing evidence that Southern Ocean may be an important feedback factor in controlling global CO2 and temperatures. • What is the implication for future climate change? 63