Challenges and solutions for long-term permafrost borehole temperature  monitoring and data interpretation

Luethi, Rachel; Phillips, Marcia

doi:10.5194/gh-71-121-2016

Cited by 18 publications

(19 citation statements)

References 40 publications

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“…Meanwhile, we assume isotropic thermal properties, even though foliation and geological structure may result in anisotropic behavior. However, despite these simplifications and assumptions, our modeled temperature field matches local observations in a borehole (Luethi & Phillips, ), and the predicted amplitudes of seasonal surface displacements fit comfortably within the range of past field measurements (Bakun‐Mazor et al, ; Gischig et al, ).…”

Section: Discussionsupporting

confidence: 71%

“…Gischig et al, 2011b;Moore et al, 2011). The modeled depth of the thermally active layer matches long-term temperature measurements from a nearby 10-m deep borehole at Eggishorn (Luethi & Phillips, 2016). Our thermal properties and model boundary conditions yield a geothermal gradient of Journal of Geophysical Research: Earth Surface ~21°C km À1 (see Figure 5), similar to a reported geothermal gradient of 23°C km À1 in the Aar massif by Rybach & Pfister (1994).…”

Section: Model Approach and Inputssupporting

confidence: 74%

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Thermomechanical Stresses Drive Damage of Alpine Valley Rock Walls During Repeat Glacial Cycles

et al. 2018

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Cycles of glaciation alter the temperature field in proximal alpine valley flanks, driving rock slope damage through thermomechanical stresses. Here we extend simplified assumptions of glacial debuttressing to quantitatively examine how paraglacial bedrock temperature changes, acting in concert with changing ice loads during Late Pleistocene and Holocene glacial cycles, create damage in adjacent rock slopes and prepare future slope instabilities. When in contact with temperate glacier ice, valley walls maintain near isothermal ~0 °C surface temperatures and are shielded from daily and annual cycles. With retreat, rock walls are rapidly exposed to strongly varying temperature boundary conditions, a transition we term “paraglacial thermal shock.” Using detailed, conceptual numerical models based on the Aletsch Glacier in Switzerland, we show that including thermomechanical stresses during simulated glacial cycles creates significantly more rock slope damage than predicted for purely mechanical ice loading and unloading. Glacier advances are especially effective in generating damage as rapid cooling drives contraction of the rock mass reducing joint normal stresses. First time exposure to annual temperature cycles during deglaciation induces a shallow damage front that follows the retreating ice margin, generating damage in a complementary process at shorter time scales. Acting on a reduced strength rock mass, modeled thermomechanical cycles enhance the development of a slope instability with similar attributes as observed in our study area. Our results demonstrate that thermomechanical stresses acting in conjunction with changing ice loads are capable of generating considerable rock slope damage with spatial and temporal patterns controlled by glacier extents.

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Section: Discussionsupporting

confidence: 71%

Section: Model Approach and Inputssupporting

confidence: 74%

Thermomechanical Stresses Drive Damage of Alpine Valley Rock Walls During Repeat Glacial Cycles

et al. 2018

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“…According to Holmberg et al [1997], drift is a temporal shift of sensor response under constant physical and chemical conditions. These conditions are typically induced by water damage to the sensors or water fluxes within the ground, which could affect the interpretation of data to be seen as measurement errors [Luethi and Phillips 2016]. Luethi and Phillips [2016] discussed the challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation.…”

Section: Sensor Drift and Calibrationmentioning

confidence: 99%

“…These conditions are typically induced by water damage to the sensors or water fluxes within the ground, which could affect the interpretation of data to be seen as measurement errors [Luethi and Phillips 2016]. Luethi and Phillips [2016] discussed the challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation. Utilizing WSN for WQM requires sensors to detect certain parameters in real time, which comes with technology-related limitations known as sensor drift.…”

Section: Sensor Drift and Calibrationmentioning

confidence: 99%

Water Quality Monitoring Using Wireless Sensor Networks

Adu-Manu

Tapparello

Heinzelman

et al. 2017

ACM Trans. Sen. Netw.

224

128

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Water is essential for human survival. Although approximately 71% of the world is covered in water, only 2.5% of this is fresh water; hence, fresh water is a valuable resource that must be carefully monitored and maintained. In developing countries, 80% of people are without access to potable water. Cholera is still reported in more than 50 countries. In Africa, 75% of the drinking water comes from underground sources, which makes water monitoring an issue of key concern, as water monitoring can be used to track water quality changes over time, identify existing or emerging problems, and design effective intervention programs to remedy water pollution. It is important to have detailed knowledge of potable water quality to enable proper treatment and also prevent contamination. In this article, we review methods for water quality monitoring (WQM) from traditional manual methods to more technologically advanced methods employing wireless sensor networks (WSNs) for in situ WQM. In particular, we highlight recent developments in the sensor devices, data acquisition procedures, communication and network architectures, and power management schemes to maintain a long-lived operational WQM system. Finally, we discuss open issues that need to be addressed to further advance automatic WQM using WSNs.

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“…To the best of our knowledge, in the entire European Alps only the Aiguille du Midi site (Chamonix, France, 3842 m a.s.l.) (Ravanel and Deline, 2011;Magnin et al, 2015), the permafrost borehole on the Jungfraujoch (Grindelwald, Switzerland, 3700 m a.s.l.) (Wegmann, 1997(Wegmann, , 1998Noetzli et al, 2019), the geothermal profiles on Stockhorn (Gruber et al, 2004c) and two simple ground surface temperature sensors located on the summit of the Matterhorn (4478 m a.s.l.)…”

Section: Introductionmentioning

confidence: 99%

A decade of detailed observations (2008–2018) in steep bedrock permafrost at the Matterhorn Hörnligrat (Zermatt, CH)

Weber

Beutel

Forno

et al. 2019

Earth Syst. Sci. Data

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Abstract. The PermaSense project is an ongoing interdisciplinary effort between geo-science and engineering disciplines and started in 2006 with the goals of realizing observations that previously have not been possible. Specifically, the aims are to obtain measurements in unprecedented quantity and quality based on technological advances. This paper describes a unique >10-year data record obtained from in situ measurements in steep bedrock permafrost in an Alpine environment on the Matterhorn Hörnligrat, Zermatt, Switzerland, at 3500 ma.s.l. Through the utilization of state-of-the-art wireless sensor technology it was possible to obtain more data of higher quality, make these data available in near real time and tightly monitor and control the running experiments. This data set (https://doi.org/10.1594/PANGAEA.897640, Weber et al., 2019a) constitutes the longest, densest and most diverse data record in the history of mountain permafrost research worldwide with 17 different sensor types used at 29 distinct sensor locations consisting of over 114.5 million data points captured over a period of 10 or more years. By documenting and sharing these data in this form we contribute to making our past research reproducible and facilitate future research based on these data, e.g., in the areas of analysis methodology, comparative studies, assessment of change in the environment, natural hazard warning and the development of process models. Finally, the cross-validation of four different data types clearly indicates the dominance of thawing-related kinematics.

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Challenges and solutions for long-term permafrost borehole temperature monitoring and data interpretation

Cited by 18 publications

References 40 publications

Thermomechanical Stresses Drive Damage of Alpine Valley Rock Walls During Repeat Glacial Cycles

Thermomechanical Stresses Drive Damage of Alpine Valley Rock Walls During Repeat Glacial Cycles

Water Quality Monitoring Using Wireless Sensor Networks

A decade of detailed observations (2008–2018) in steep bedrock permafrost at the Matterhorn Hörnligrat (Zermatt, CH)

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