Previous results from deep-sea pore fluid data demonstrate that the glacial deep ocean was filled with salty, cold water from the South. This salinity stratification of the ocean allows for the possible accumulation of geothermal heat in the deep-sea and could result in a water column with cold fresh water on top of warm salty water and with a corresponding increase in potential energy. For an idealized 4000 dbar two-layer water column, we calculate that there are ~106 J/m2 (~0.2 J/kg) of potential energy available when a 0.4 psu salinity contrast is balanced by a ~2°C temperature difference. This salt-based storage of heat at depth is analogous to Convectively Available Potential Energy (CAPE) in the atmosphere. The ‘‘thermobaric effect’’ in the seawater equation of state can cause this potential energy to be released catastrophically. Because deep ocean stratification was dominated by salinity at the Last Glacial Maximum (LGM), the glacial climate is more sensitive to charging this ‘‘thermobaric capacitor’’ and can plausibly explain many aspects of the record of rapid climate change. Our mechanism could account for the grouping of Dansgaard/Oeschger events into Bond Cycles and for the different patterns of warming observed in ice cores from separate hemispheres.

Adkins, J., Ingersoll, A., Pasquero, C. (2005). Rapid climate change and conditional instability of the glacial deep ocean from the thermobaric effect and geothermal heating. QUATERNARY SCIENCE REVIEWS, 24(5-6), 581-594 [10.1016/j.quascirev.2004.11.005].

Rapid climate change and conditional instability of the glacial deep ocean from the thermobaric effect and geothermal heating

PASQUERO, CLAUDIA
2005

Abstract

Previous results from deep-sea pore fluid data demonstrate that the glacial deep ocean was filled with salty, cold water from the South. This salinity stratification of the ocean allows for the possible accumulation of geothermal heat in the deep-sea and could result in a water column with cold fresh water on top of warm salty water and with a corresponding increase in potential energy. For an idealized 4000 dbar two-layer water column, we calculate that there are ~106 J/m2 (~0.2 J/kg) of potential energy available when a 0.4 psu salinity contrast is balanced by a ~2°C temperature difference. This salt-based storage of heat at depth is analogous to Convectively Available Potential Energy (CAPE) in the atmosphere. The ‘‘thermobaric effect’’ in the seawater equation of state can cause this potential energy to be released catastrophically. Because deep ocean stratification was dominated by salinity at the Last Glacial Maximum (LGM), the glacial climate is more sensitive to charging this ‘‘thermobaric capacitor’’ and can plausibly explain many aspects of the record of rapid climate change. Our mechanism could account for the grouping of Dansgaard/Oeschger events into Bond Cycles and for the different patterns of warming observed in ice cores from separate hemispheres.
Articolo in rivista - Articolo scientifico
paleoclimate, ocean circulation
English
2005
24
5-6
581
594
none
Adkins, J., Ingersoll, A., Pasquero, C. (2005). Rapid climate change and conditional instability of the glacial deep ocean from the thermobaric effect and geothermal heating. QUATERNARY SCIENCE REVIEWS, 24(5-6), 581-594 [10.1016/j.quascirev.2004.11.005].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/26038
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