Radar attenuation and temperature within the Greenland Ice Sheet

Joseph A MacGregor; Jilu Li; John D Paden; Ginny A Catania; Gary D. Clow; Mark A Fahnestock; Prasad S. Gogineni; Robert E. Grimm; Mathieu Morlighem; Soumyaroop Nandi; Helene Seroussi; David E Stillman

doi:10.1002/2014JF003418

Radar attenuation and temperature within the Greenland Ice Sheet

Journal of Geophysical Research F: Earth Surface

By: Joseph A MacGregor, Jilu Li, John D Paden, Ginny A Catania, Gary D. Clow, Mark A Fahnestock, Prasad S. Gogineni, Robert E. Grimm, Mathieu Morlighem, Soumyaroop Nandi, Helene Seroussi, and David E Stillman

https://doi.org/10.1002/2014JF003418

Metrics

94

Crossref references

Web analytics dashboard Metrics definitions

Links

More information: Publisher Index Page (via DOI)
Open Access Version: External Repository
Download citation as: RIS | Dublin Core

Abstract

The flow of ice is temperature-dependent, but direct measurements of englacial temperature are sparse. The dielectric attenuation of radio waves through ice is also temperature-dependent, and radar sounding of ice sheets is sensitive to this attenuation. Here we estimate depth-averaged radar-attenuation rates within the Greenland Ice Sheet from airborne radar-sounding data and its associated radiostratigraphy. Using existing empirical relationships between temperature, chemistry, and radar attenuation, we then infer the depth-averaged englacial temperature. The dated radiostratigraphy permits a correction for the confounding effect of spatially varying ice chemistry. Where radar transects intersect boreholes, radar-inferred temperature is consistently higher than that measured directly. We attribute this discrepancy to the poorly recognized frequency dependence of the radar-attenuation rate and correct for this effect empirically, resulting in a robust relationship between radar-inferred and borehole-measured depth-averaged temperature. Radar-inferred englacial temperature is often lower than modern surface temperature and that of a steady state ice-sheet model, particularly in southern Greenland. This pattern suggests that past changes in surface boundary conditions (temperature and accumulation rate) affect the ice sheet's present temperature structure over a much larger area than previously recognized. This radar-inferred temperature structure provides a new constraint for thermomechanical models of the Greenland Ice Sheet.

Suggested Citation

MacGregor, J.A., Li, J., Paden, J.D., Catania, G.A., Clow, G.D., Fahnestock, M.A., Gogineni, P.S., Grimm, R.E., Morlighem, M., Nandi, S., Seroussi, H., and Stillman, D.E., 2015, Radar attenuation and temperature within the Greenland Ice Sheet: Journal of Geophysical Research F: Earth Surface, v. 120, no. 4, p. 1-26, https://doi.org/10.1002/2014JF003418.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Radar attenuation and temperature within the Greenland Ice Sheet
Series title	Journal of Geophysical Research F: Earth Surface
DOI	10.1002/2014JF003418
Volume	120
Issue	4
Year Published	2015
Language	English
Publisher	American Geophysical Union
Publisher location	Richmond, VA
Contributing office(s)	Geosciences and Environmental Change Science Center
Description	26 p.
First page	1
Last page	26
Online Only (Y/N)	N
Additional Online Files (Y/N)	N