Proxies for climate reconstructions Geological observations Large fossil indicators of past climates Geochemical indicator Relative abundance of stable.

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Presentation transcript:

Proxies for climate reconstructions Geological observations Large fossil indicators of past climates Geochemical indicator Relative abundance of stable isotopes Concentration of Mg in fossils Concentrations of organic compounds in fossils Microfossils as indicators of past climate Foraminifera Pollen CaCO 3 precipitates from caves Ice cores

Geomorphic indicators of past climates: Moraines (rock pile at maximum extent of glacier) Younger Dryas Waiho Loop Moraine, New Zealand Alaskan Moraine 19th century expedition

Geomorphic indicators of past climates: stream deposits Proglacial stream, New Zealand Proglacial braided streams, Alaska Outwash clasts, Iceland

Diamictite – rock fragments of all different sizes, with up to 25% of the mass > 2mm in size. Diamictites are often glacial debris but may also form from stream deposits–

Geomorphic indicators of past climates: Dropstones in Neoproterozoic sediments Note coin for scale Note person for scale

Geomorphic indicators of past climates: Loess and paleosols Loess (windblown dust deposit, signifying aridity) Loess (depositional) and paleosols (darker layers signifying weathering and organic depostion during wetter period)

Fossil indicators of past climates Vegetation – Plants have obvious preferences for mean annual temperature, mean annual precip, and seasonality of both properties Pollen important for recent times – Plants adapt to environmental change (higher CO2 = fewer stomates) Animals have temperature requirements – Particularly cold blooded animals Plant and animal microfossils in the oceans have temperature preferences and tolerances

Isotopes that are indicators of past climates Hydrogen – 1 H, 2 H (0.02%); 2 H is also known as “deuterium” –  D (or  2 H) = [(D/H) sample / (D/H) ref -1] x 1000 Oxygen – 16 O, 17 O (0.04 %), 18 O (0.20 %) –  18 O = [( 18 O/ 16 O) sample / ( 18 O/ 16 OH) ref -1] x 1000 Carbon – 12 C, 13 C (1.1 %) –   C = [( 13 C/ 12 C) sample / ( 13 C/ 12 C) ref -1] x 1000

Nature of isotope effects Physical isotope effects – Evaporation and precipitation (  18 O gas =  18 O water - 7 ‰) – Diffusion (gases of light isotopes diffuse faster than gases of heavy isotopes) Chemical equilibrium isotope effects – Example: fractionation of O isotopes between H 2 O and CO 3 2- – H 2 16 O + C 16 O 2 18 O 2- = H 2 18 O + C 16 O 3 2- – K = [H 2 18 O] [C 16 O 3 2- ] / [H 2 16 O] [C 16 O 2 18 O 2- ] – K is a function of temperature Chemical kinetic isotope effects – Example: CO 2 assimilation during photosynthesis – 12 CO 2 + H 2 O --> 12 CH 2 O + O 2 – 13 CO 2 + H 2 O --> 13 CH 2 O + O 2 – k( 13 CO 2 ) / k ( 12 CO 2 ) ~ for C3 photosynthesis (trees, flowering plants, some grasses

Paleotemperatures using  18 O of CaCO 3 K = [H 2 18 O] [C 16 O 3 2- ] / [H 2 16 O] [C 16 O 2 18 O 2- ] = function of temperature Paleotemperature equation: – T(˚C) = *(  calcite -  water ) *(  calcite -  water ) 2 At 16.9˚, dT/d  ~ ; d  /dT ~ ‰ /˚C. Standards: – Water: SMOW (Standard Mean Ocean Water) – Calcite: PDB-1 (Pee Dee formation Belemnite -1) Complication: One needs to know  water. – Modern ocean:  water varies with salinity by ~ 1 ‰ (evaporation increases  water ) – Pleistocene ocean:  water varies with ice volume (~ 1 ‰ higher during glacial maximum) – Pre-Cenozoic ocean:  water is not known; may been ~ 0.5 ‰ less than today – Freshwater environments: very hard to know  water – Hydrologic fractionations: Discrimination against 18 O during evaporation Discrimination favoring 18 O during precipitation Problem: diagenesis – CaCO 3 recrystalizes: CaCO 3 + H 2 O --> Ca HCO > CaCO 3 + H 2 O –  18 O calcite depends on recrystalization temperature and  18 O of pore-space waters – For forams, recrystalization becomes important after 10’s of millions of years

Mg/Ca in forams and paleotemperatures Basic evidence for temperature dependence: one experiment – Collect sinking forams in sediment traps to get temperature range – Measure temperature of the water – Measure Mg/Ca and compare with growth temperature – Derive curves of Mg/Ca vs. temperature for each species Mg/Ca + xe 0.090T Cross section of a foraminifera shell

Paleotemperatures from the uk’37 index of alkenone undersaturation Alkenones are hydrocarbon compounds with long chains of carbon atoms (37 in this case) Most of the carbon atoms are linked by single bonds (they are saturated, each bonding with enough H atoms to fill up the valence state) Some of the C atoms are linked by double bonds (undersaturated) Coccolithofoids produce these alkenones (coccolithoforids are phytoplankton that make CaCO 3 shells) The position of double bonds changes as a function of temperature to regulate the viscosity of the cell fluid In chemical notation, numbers indicate the position of double bonds

Uk’37 in surface seawater samples vs. collection temperature For core top samples there is a compact relationship between Uk’37 and temperature Trends are similar for all oceans Sensitivity is poor above 25˚C and below 6˚C Conte et al 2006

Faunal reconstructions of past temperatures: an example based on the modern analog technique All foraminifera have temperature preferences and tolerances The species composition of a fossil foram assemblage depends on temperature The reconstructed temperature will be most accurate if we look at the abundance of all the forams species in the sample) The temperature dependence of modern assemblages is the reference The temperature of a fossil assemblage is the temperature of the most similar modern assemblage

Illustration of temperature dependences of forams: menardii likes warmer waters than pachyderma Pachyderma abundance vs. water temp. Menardii + tumida abundance vs. water temp.

Climate reconstructions from pollen Most pollen records come from lake sediments Also some records from nearshore ocean sediment cores Fossil species assemblages record the presence or absence of fossils in past times Pollen abundance depends on – Proximity of biomes (trees that are abundant near the lake are overrepresented) – Production – Atmospheric transport – Removal processes (precipitation, dry fallout) Gajewski,2008

Modern pollen database serves to calibrate fossil assemblage paleotemperatures

Climate records from CaCO 3 precipitates in caves

19 Temperature, CH 4, and CO 2 records from the Vostok ice core 0 ka200 ka400 ka800 ka  18 O of CaCO 3 (‰) (colder, more ice) CO 2 CH 4 Isotopic temp of ice Foram  18 O 600 ka