The palaeo-temperature regime at the surface of an ice sheet represents the temperature history at a location over some period up to the present. The time span of interest depends on the site under investigation but can be up to 100 or 200 ka BP (i.e. to beyond the last hypsithermal at 120 ka BP). Measured temperature-depth profiles can provide information on past surface temperature changes. The detail depends mainly on the time elapsed since the period of interest. Alternatively the measured profile can be used as a sensitive test of the validity of a temperature history reconstructed from proxy data such as measured stable isotope-depth profiles. Such approaches were used by Reference Budd, Young and RobinBudd and Young (1983) in their modelling of the temperature and ice-velocity distributions about several deep bore holes in the Greenland and Antarctic ice sheets.
In calculating the present temperature-depth profile for a given site consideration needs to be given to past surface temperature changes whether they be due to changes in elevation, climatic change, or motion through a temperature field. For thin ice sheets of several hundred metres thickness, and particularly those with high snow accumulation rates, the required historical record covers only the recent few thousand years. For thick ice sheets and low accumulation rates, such as the Vostok and Dome C sites, temperature changes before the last glacial maximum and up to 100 or 200 ka BP must be included. But, because of the diffusive nature of heat transfer processes, short-term variations can be ignored except during the more recent period.
A study was marie of the Dome C temperature profile (Reference Ritz, Lliboutry and RadoRitz and others 1982) to illustrate the various techniques. It was found that with the temperatures measured over only a fraction of the depth it is not possible to distinguish between the effects of different accumulation rates and different rates of surface temperature change. When comparing measured temperatures and a profile calculated with fixed rates of accumulation and surface temperature change, a small (of the order of a few hundredths of a degree) but consistent discrepancy is found at 700 to 900 m depth. At least part of this discrepancy can be explained by the temperature changes deduced from the stable isotope record (Reference Lorius, Merlivat, Jouzel and PourchetLorius and others 1979). But the temperature profile at that depth is dependent on the temperature history far beyond the 30 ka record from Dome C, and past accumulation rate changes.
At present insufficient information exists to resolve the ambiguities found in the Dome C record. The deep drilling at Vostok to a depth of 2 000 m holds the best prospect at present for describing a past climatic temperature with a corresponding chronology.