2020
DOI: 10.1002/esp.4810
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Glaciers, rock avalanches and the ‘buzzsaw’ in cirque development: Why mountain cirques are of mainly glacial origin

Abstract: It has been proposed that most cirques are source‐area depressions of large, deep‐seated rock‐slope failures. Yet the close relation between cirques and climate is convincing evidence of the dominance of glacial erosion, rather than rock‐slope failure, in mountain cirque development and distribution. Cirque floor altitudes have a lower limit that varies with snowfall by 1000 m or more between windward and leeward sides of mountain systems. Glaciation levels and equilibrium line altitudes implied by cirques var… Show more

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Cited by 35 publications
(8 citation statements)
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References 154 publications
(307 reference statements)
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“…5.1 and 5.2. Our measurements/observations suggest sustained freezing and ample water supply inside the Randkluft at the same time (during summer) -two key requirements for ice segregation (and thus for frost cracking) (see also analyses of Sanders et al 2012, Alley et al 2019, Evans et al 2020 who all assume enhanced frost cracking inside the Randkluft). We feel that some confusion was arising from our use of the term "subcritical fracture propagation" (which results from ice segregation).…”
Section: Interactive Commentmentioning
confidence: 69%
“…5.1 and 5.2. Our measurements/observations suggest sustained freezing and ample water supply inside the Randkluft at the same time (during summer) -two key requirements for ice segregation (and thus for frost cracking) (see also analyses of Sanders et al 2012, Alley et al 2019, Evans et al 2020 who all assume enhanced frost cracking inside the Randkluft). We feel that some confusion was arising from our use of the term "subcritical fracture propagation" (which results from ice segregation).…”
Section: Interactive Commentmentioning
confidence: 69%
“…Whereas in limestone-dominated areas glacier forefields are plateau-shaped (broad and flat with very little relief); in crystalline areas (granite/gneiss) deep steep-walled valleys and at many sites overdeepened basins, e.g., the Rhône glacier and Trift glacier (Figure 1), tend to develop. The formation of overdeepenings is complex and usually a combination of geological (fracture spacing, weak zones, change in lithology) [72][73][74], geographical (glacier confluences) [75,76] and glaciological (near equilibrium line altitude, rates of ice flux) [12,[77][78][79] factors. Recent research at Trift glacier, where there is an exceptionally deep overdeepening, highlighted that the presence of a gorge seems to have a crucial effect on the formation and the apparent depth of an overdeepening [26].…”
Section: Discussionmentioning
confidence: 99%
“…Depressions containing water bodies are common across the WG. These twenty-six bodies of water are either dammed by bedrock (e.g., Lagunas las Arrebiatadas) or a moraine (e.g., Lagunas la Cruz), often coinciding with bedrock steps and smoothed bedrock indicating warmed based glaciers that produced significant glacial erosion with a high discharge of ice and a high mass turnover (MacGregor et al, 2000;Cook and Swift, 2012;Evans, 2021).…”
Section: Western Glacial Cirquesmentioning
confidence: 99%