Abstract
A new ice core paleothermometer is introduced based on the temperature
dependent diffusion of the stable water isotopes in the firn. A new
parameter called differential diffusion length is defined as the
difference between the diffusion length of the two stable water
isotopologues 2H1H16O and
1H218O. A model treatment of the
diffusion process of the firn and the ice is presented along with a
method of retrieving the diffusion signal from the ice core record of
water isotopes using spectral methods. The model shows how the diffusion
process is highly dependent on the inter-annual variations in the
surface temperatures. It results in a diffusion length longer than if
the firn was isothermal. The longer diffusion length can be explained by
the strong nonlinearly behaviour of the saturation pressure over ice in
the range of the surface temperature fluctuations. The
method has been tested on d18O and dD
measurements, spanning the transition from the last glacial to the
holocene, from the NorthGRIP ice core. The surface temperature
reconstruction based on the differential diffusion resembles other
temperature reconstructions for the NorthGRIP ice core. However, the
Allerød warming is seen to be significantly warmer than observed
in other ice core based temperature reconstructions. The mechanisms
behind this behaviour are not fully understood. The method
shows the need of an expansion of high resolution stable water isotope
datasets from ice cores. However, the new ice core paleothermometer
presented here will give valuable insight into past climate, through the
physical process of isotope diffusion in the firn column of ice sheets.
Original language | English |
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Journal | Climate of the Past |
Volume | 7 |
Issue number | 4 |
Pages (from-to) | 1327-1335 |
ISSN | 1814-9324 |
Publication status | Published - 1 Dec 2011 |