2021
DOI: 10.3389/feart.2021.607875
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Best Practice for Measuring Permafrost Temperature in Boreholes Based on the Experience in the Swiss Alps

Abstract: Temperature measurements in boreholes are the most common method allowing the quantitative and direct observation of permafrost evolution in the context of climate change. Existing boreholes and monitoring networks often emerged in a scientific context targeting different objectives and with different setups. A standardized, well-planned and robust instrumentation of boreholes for long-term operation is crucial to deliver comparable, high-quality data for scientific analyses and assessments. However, only a li… Show more

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Cited by 34 publications
(26 citation statements)
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“…In the case of the Hoernli hut borehole (Figure 3) increasing positive deviations from 0 • C clearly indicate sensor drift. Duplicate measurements were therefore carried out in the borehole using additional miniature UTL-3 loggers (section "3.1 Ground Temperature Measurements in Boreholes") from 2016 onwards for comparison with the measurements of the installed thermistor string (Figure 3; Noetzli et al, 2021). The UTL-3 loggers measured an active layer thickness of 1.5 to 2.0 m between 2016 and 2019, which is in the range of the active layer thickness observations before 2014 (section "4.2.2.1 Active Layer Thickness").…”
Section: Sensor Driftmentioning
confidence: 99%
“…In the case of the Hoernli hut borehole (Figure 3) increasing positive deviations from 0 • C clearly indicate sensor drift. Duplicate measurements were therefore carried out in the borehole using additional miniature UTL-3 loggers (section "3.1 Ground Temperature Measurements in Boreholes") from 2016 onwards for comparison with the measurements of the installed thermistor string (Figure 3; Noetzli et al, 2021). The UTL-3 loggers measured an active layer thickness of 1.5 to 2.0 m between 2016 and 2019, which is in the range of the active layer thickness observations before 2014 (section "4.2.2.1 Active Layer Thickness").…”
Section: Sensor Driftmentioning
confidence: 99%
“…At lower altitudes (~1800 m asl) on the north-facing slope, geophysical soundings and ground surface measurements confirmed the occurrence of thin isolated, sporadic At lower altitudes (~1800 m asl) on the north-facing slope, geophysical soundings and ground surface measurements confirmed the occurrence of thin isolated, sporadic permafrost lenses at shallow depth down to~20 m [59,60,[73][74][75][76][77] (Figure 2B). Compared to permafrost sites in the periglacial zone (e.g., [78][79][80]), the active layer thickness is relatively shallow (1-3 m) and ground temperatures are just below zero degrees (−0.2 • C at 8 m depth). This subalpine permafrost occurrence is approximately 500 m below the expected lower limit of discontinuous permafrost, frequently represented by rock glaciers at 2300 m asl in the Upper Engadin [57,77,81,82].…”
Section: Study Sitementioning
confidence: 97%
“…First, permafrost monitoring is based on in-situ ground temperatures measured in boreholes (Noetzli et al 2021). Their installation and long-term operation at remote sites in cold climates are challenging.…”
Section: Introductionmentioning
confidence: 99%