<span class='italic'>In situ</span> measurement techniques: land ice

doi:10.1017/CBO9780511535659.004

2 - In situ measurement techniques: land ice

Published online by Cambridge University Press: 16 October 2009

Jon Ove Hagen and

Niels Reeh

Edited by

Jonathan L. Bamber and

Antony J. Payne

Foreword by

John Houghton

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Jon Ove Hagen: Affiliation:
Department of Physical Geography, Faculty of Mathematics and Natural Sciences, University of Oslo
Niels Reeh: Affiliation:
Ørsted-DTU, Electromagnetic Systems, Technical University of Denmark
Jonathan L. Bamber: Affiliation:
University of Bristol
Antony J. Payne: Affiliation:
University of Bristol

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Summary

Introduction

Measurement of the mass balance of larger glaciers, ice sheets, ice caps and ice fields requires different field techniques than for the smaller valley glaciers. These larger glaciers are an integral part of the Earth's interactive ice–ocean–land–atmosphere system, and may also provide valuable insight into the cause of changes of the Earth's climate system (Meier, 1998).

In this chapter, we deal with in situ measurement techniques. However, we include measurements based on aerial photography, since such measurements for more than half a century have been used in combination with field studies. Modern, mainly satellite-based, remote-sensing techniques for measuring glacier mass balance are presented in Chapter 4.

Mass balance equations

In glacier context, the term ‘mass balance’ is traditionally used in two ways with different meanings. At a specific point of the glacier, the local mass balance designates the sum of accumulation (supply of mass mainly by snow deposition) and ablation (loss of mass mainly by melting of snow/ice). The local (specific) mass balance may be positive or negative depending on whether accumulation or ablation dominates. However, the sign of the specific mass balance does not say anything about the local change of ice thickness or the local change of mass in a vertical column through the glacier. This is because the specific mass balance may be compensated for, or even be overruled by, mass input/loss due to a gradient of the horizontal ice flux.

Type: Chapter
Information: Mass Balance of the Cryosphere
Observations and Modelling of Contemporary and Future Changes
, pp. 11 - 42

DOI: https://doi.org/10.1017/CBO9780511535659.004 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2004

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