Abstract
Microwave emissions at the L-band (1–2 GHz) in Antarctica are characterized by a significant contribution of ice layers at great depth, from hundreds to a thousand meters. Brightness temperatures, thus, could provide the internal temperature of the ice sheet. However, there are two difficulties to overcome in developing an accurate retrieval algorithm. First, it is difficult to know precisely from which depths waves are emanating because the ice-absorption coefficient is uncertain at the L-band, despite several formulations proposed in the literature over the past few decades. Second, emissivity potentially varies in Antarctica due to remnant scattering in firn (or ice), even at the Brewster angle, and despite the low frequency, limiting the accuracy of the estimate of the physical temperature. Here, we present a retrieval method able to disentangle the absorption and emissivity effects from brightness temperature over the whole continent. We exploit the fact that scattering and absorption are controlled by different physical parameters and phenomena that can be considered as statistically independent. This independence provides a constraint to the retrieval method, that is then well-conditioned and solvable. Our results show that (1) the retrieved absorption agrees with the permittivity model proposed by Mätzler et al. (2006), and (2) emissivity shows significant variations, up to 6% over the continent, which are correlated with wind speed and accumulation patterns. A possible cause of this latter point is density heterogeneity and sastrugi buried in the firn. These two results are an important step forward for the accurate retrieval of internal temperature using low-frequency microwave radiometers.
Highlights
Observation in the microwave range with space-borne radiometers is a rich source of information on surface and subsurface physical properties in Antarctica
Apparent emissivity η is η = TB/Ts ∼ 0.98. This does not apply to EPICA Dronning Maud Land (EDML), EPICA Dome C (EDC), and Dome Fuji, where temperature significantly increases with depth (T(z) > Ts)
Given that TB observed from Soil Moisture and Ocean Salinity (SMOS) was lower than Ts, the brightness temperature is significantly lower than TE, by at least several kelvins, whatever the value of the absorption coefficient
Summary
Microwave emissions from ice sheets at lower frequencies (1–2 GHz, L-band) is characterized by much lower absorption and scattering effects. This major difference represents a potential to retrieve information on the internal structure of the Antarctic ice sheet. The geothermal flux at the bedrock–ice interface has been estimated either by considering the seismic properties of the crust and upper mantle [15,16], or by assessing the crustal thickness from observations of the magnetic field [17,18] Significant discrepancies between these datasets were shown, reaching several tens of mW m−2, and up to 50 mW m−2 in West Antarctica [18]. The L-band signal contains worthwhile information on the amount of heat dissipated in the Antarctic ice sheet, which is required to build future projections of the Antarctic ice sheet [19]
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