Application and validation of long-range terrestrial laser scanning to monitor the mass balance of very small glaciers in the Swiss Alps

Abstract. Due to the relative lack of empirical field data, the response of very small glaciers (here defined as being smaller than 0.5 km2) to current atmospheric warming is not fully understood yet. Investigating their mass balance, e.g. using the direct glaciological method, is a prerequisite to fill this knowledge gap. Terrestrial laser scanning (TLS) techniques operating in the near infrared range can be applied for the creation of repeated high-resolution digital elevation models and consecutive derivation of annual geodetic mass balances of very small glaciers. This method is promising, as laborious and potentially dangerous field measurements as well as the inter- and extrapolation of point measurements can be circumvented. However, it still needs to be validated. Here, we present TLS-derived annual surface elevation and geodetic mass changes for five very small glaciers in Switzerland (Glacier de Prapio, Glacier du Sex Rouge, St. Annafirn, Schwarzbachfirn, and Pizolgletscher) and two consecutive years (2013/14–2014/15). The scans were acquired with a long-range Riegl VZ ® -6000 especially designed for surveying snow- and ice-covered terrain. Zonally variable conversion factors for firn and bare ice surfaces were applied to convert geodetic volume to mass changes. We compare the geodetic results to direct glaciological mass balance measurements coinciding with the TLS surveys and assess the uncertainties and errors included in both methods. Average glacier-wide mass balances were negative in both years, showing stronger mass losses in 2014/15 (−1.65 m w.e.) compared to 2013/14 (−0.59 m w.e.). Geodetic mass balances were slightly less negative but in close agreement with the direct glaciological ones (R2 = 0.91). Due to the dense in situ measurements, the uncertainties in the direct glaciological mass balances were small compared to the majority of measured glaciers worldwide (±0.09 m w.e. yr−1 on average), and similar to uncertainties in the TLS-derived geodetic mass balances (±0.13 m w.e. yr−1).

• Publication year

  2016

• Venue

  The Cryosphere

• Publication date

  2016-06-20

• Fields of study

  Geology, Environmental Science

• Identifiers
  DOI 10.5194/TC-10-1279-2016
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar

• Dense field measurements kept the uncertainty in direct glaciological mass balance small and in the same range as the TLS-derived geodetic uncertainty.

  Confidence 0.93

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• Average glacier-wide mass balances were negative in both years, and mass loss was larger in 2014/15 (−1.65 m w.e.) than in 2013/14 (−0.59 m w.e.).

  Confidence 0.97

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• Geodetic mass balances were slightly less negative than direct glaciological mass balance measurements but remained in close agreement, with R2 = 0.91.

  Confidence 0.95

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• TLS-derived annual surface elevation and geodetic mass changes were obtained for five very small Swiss glaciers over the 2013/14 and 2014/15 survey periods.

  Confidence 0.96

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review

• conversion factors for firn and bare ice surfaces

  conversion factor

  Zonal factors applied to convert geodetic volume changes into mass changes for different glacier surface types.

  Aliases: firn and bare ice conversion factors, zonally variable conversion factors

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• direct glaciological mass balance

  measurement method

  A mass-balance measurement obtained from in situ stake and snow/ice observations on the glacier surface.

  Aliases: direct glaciological measurements, direct mass balance

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• geodetic mass balance

  measurement method

  A glacier mass-balance estimate derived from changes in surface elevation or volume between repeated surveys.

  Aliases: geodetic mass changes, geodetic mass balances

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• riegl vz-6000

  instrument

  The long-range terrestrial laser scanner used to acquire the glacier surveys in this study.

  Aliases: Riegl VZ 6000, VZ-6000

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• terrestrial laser scanning

  method

  A long-range laser scanning method used to survey glacier surfaces and derive repeated digital elevation models.

  Aliases: TLS

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review
• very small glaciers

  glacier class

  Glaciers smaller than 0.5 km2, which are the glacier class targeted in the surveys.

  Aliases: small glaciers

  박진우 (dztg5apj7m) extractionB (s683577b42) reviewAK (4715169a40) reviewmexicorea (qjvnbu8xg3) reviewAnonymous (12632b8b5f) review

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