Sidewall erosion: Insights from <i>in situ</i>‐produced <sup>10</sup>Be concentrations measured on supraglacial clasts (Mont Blanc massif, France)

Sarr, Anta‐Clarisse; Mugnier, Jean‐Louis; Abrahami, Rachel; Carcaillet, Julien; Ravanel, Ludovic

doi:10.1002/esp.4620

Cited by 9 publications

(22 citation statements)

References 75 publications

(173 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…inherited 10 Be concentration produced during the last glacial cycle) was an overestimation. This higher rockfall frequency is also confirmed by 10 Be measurements in supra-glacial clasts collected in Bossons and Argentière glacier areas (MBM), revealing significant rockfall erosion in glacier sidewalls (Sarr et al, 2019). We thus consider that the inherited 10 Be content in our collected samples is non-significant for exposure age computation.…”

Section: Sample Processingsupporting

confidence: 79%

Climatic and structural controls on Late‐glacial and Holocene rockfall occurrence in high‐elevated rock walls of the Mont Blanc massif (Western Alps)

Carcaillet

Ravanel

Deline

et al. 2020

Earth Surf Processes Landf

View full text Add to dashboard Cite

In the Mont Blanc massif (European Western Alps), rockfalls are one of the main natural hazards for alpinists and infrastructure. Rockfall activity after the Little Ice Age is well documented. An increase in frequency during the last three decades is related to permafrost degradation caused by rising air temperatures. In order to understand whether climate exerts a long-term control on rockfall occurrence, a selection of paleo-rockfall scars was dated in the Glacier du Géant basin [>3200m above sea level (a.s.l.)] using terrestrial cosmogenic nuclides. Rockfall occurrence was compared to different climatic and glacial proxies. This study presents 55 new samples (including replicates) and 25 previously-published ages from nine sampling sites. In total, 62 dated rockfall events display ages ranging from 0.03 ± 0.02ka to 88.40 ± 7.60ka. Holocene ages and their uncertainties were used to perform a Kernel density function into a continuous dataset displaying rockfall probability per 100years. Results highlight four Holocene periods of enhanced rockfall occurrence: (i) c. 7-5.7ka, related to the Holocene Warm Periods; (ii) c. 4.5-4ka, related to the Sub-boreal Warm Period; (iii) c. 2.3-1.6ka, related to the Roman Warm Period; and (iv) c. 0.9-0.3ka, related to the Medieval Warm Period and beginning of the Little Ice Age. Laser and photogrammetric three-dimensional (3D) models of the rock walls were produced to reconstruct the detached volumes from the best-preserved rockfall scars (≤0.91 ± 0.12ka). A structural study was carried out at the scale of the Glacier du Géant basin using aerial photographs, and at the scale of four selected rock walls using the 3D models. Two main vertical and one horizontal fracture sets were identified. They correspond respectively to alpine shear zones and veins opened-up during long-term exhumation of the Mont Blanc massif. Our study confirms that climate primarily controls rockfall occurrence, and that structural settings, coincident at both the massif and the rock wall scales, control the rock-wall shapes as well as the geometry and volume of the rockfall events.

show abstract

Section: Sample Processingsupporting

confidence: 79%

Climatic and structural controls on Late‐glacial and Holocene rockfall occurrence in high‐elevated rock walls of the Mont Blanc massif (Western Alps)

Carcaillet

Ravanel

Deline

et al. 2020

Earth Surf Processes Landf

View full text Add to dashboard Cite

show abstract

“…The benefit of this approach is that (1) the estimated erosion rates represent values that are spatially and temporally averaged across relatively large headwall areas; (2) the source areas of the debris can be reconstructed, e.g., from remote‐sensing images; and (3) the sampling procedure is relatively straightforward. However, despite a promising initial application (Ward & Anderson, 2011), this approach has rarely been employed (e.g., Guillon et al, 2015; Sarr et al, 2019), and its applicability in different settings remains to be tested. Here we present headwall erosion rates derived from 10 Be concentrations in the ablation‐dominated medial moraine of the Chhota Shigri Glacier, Indian Himalaya.…”

Section: Introductionmentioning

confidence: 99%

Production and Transport of Supraglacial Debris: Insights From Cosmogenic ¹⁰Be and Numerical Modeling, Chhota Shigri Glacier, Indian Himalaya

Scherler

Egholm

2020

JGR Earth Surface

View full text Add to dashboard Cite

Many mountain glaciers carry some amount of rocky debris on them, which modifies surface ablation rates. The debris is typically derived from erosion of the surrounding topography and its supraglacial extent is predominantly controlled by the relative accumulation rates of debris versus snow. Because Global Warming results in shrinking glaciers as well as thawing permafrost worldwide, changes in both rates will most likely affect the evolution of supraglacial debris cover and thus the response of glaciers to climate change. Here we report 10 Be concentrations measured in five amalgamated debris samples collected from the main medial moraine of the Chhota Shigri Glacier, India. Results suggest headwall erosion rates that are~0.5-1 mm year −1 , and apparently increasing (10 Be concentrations are decreasing) toward the present. We employed a numerical ice flow model that we combined with a new Lagrangian particle tracing routine to explore the impact of spatial and temporal variability in erosion rates and source areas on 10 Be concentrations in the medial moraine. Our modeling results show that neither changes in source areas, related to the transient response of the glacier to ongoing climate change, nor four different scenarios of spatial and temporal variability in erosion rates could explain the observed trend in 10 Be concentrations. Although not accounted for in our modeling explicitly, we suggest that the observed trend could be due to transiently enhanced erosion of recently deglaciated areas, or to greater spatial variability in erosion rates than explored in our models. Plain Language Summary High and steep mountain ranges are currently undergoing changes due to increasing temperatures. These changes include rapidly shrinking glaciers as well as thawing permafrost, which together destabilize rock walls that surround valley glaciers. In consequence, slope failures and thus erosion rates in these environments are expected to increase. However, quantifying rock wall erosion in alpine landscapes is difficult and estimates of background erosion rates that are unaffected by Global Warming are rare. Here we estimate rock wall erosion rates above the Chhota Shigri Glacier, Indian Himalaya, by studying rocky debris from the glacier surface. This debris is sourced from the surrounding topography and we use geochemical tools to measure its residence time at the Earth surface. We combine our geochemical observations with a computer model of the glacier that allows us to explore the effect of Global Warming on the evolution of the glacier and the debris on its surface. Our results suggest recent changes in rock wall erosion rates that may be related to glacier retreat and an increase in the erosion of rock walls that were previously ice covered.

show abstract

“…(2017; http://calibration.ice-d.org/) and a 10 Be half‐life of 1.387 Ma (Chmeleff 2010; Korschinek 2010). Ward and Anderson (2011) and others have demonstrated that muonic production of 10 Be within amalgamated supraglacial debris sourced from the rockwall is negligible, and for the process timescales of rockwall slope erosion can be omitted from our calculation scheme (Akçar et al., 2014; Braucher et al., 2003; Sarr et al., 2019).…”

Section: Methodsmentioning

confidence: 99%

“…This approach to quantifying rockwall slope erosion accounts only for the spallogenic component of incoming cosmic rays and assumes a negligible loss of 10 Be due to radioactive decay, and steady state erosion and 10 Be production over time (von Blanckenburg, 2005). Further details of this methodology and its assumptions are provided by Supplementary Item 1 and in Ward and Anderson (2011) and Sarr et al (2019).…”

Section: Accepted Articlementioning

confidence: 99%

“…Periglacial weathering processes that are driven by moisture and temperature variability, and include freeze‐thaw, frost cracking and ice wedging, are particularly critical for the detachment and disintegration of rock from rockwalls (Eppes & Keanini, 2017; Heimsath & McGlynn, 2008; McColl & Davies, 2013). This detachment is considered stochastic, and through rockfall and other mass wasting delivers debris to glacier surfaces (Gibson et al., 2017; Sanders et al., 2012; Sarr et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Rockwall Slope Erosion in the Northwestern Himalaya

et al. 2021

View full text Add to dashboard Cite

Rockwall slope erosion is an important component of alpine landscape evolution, yet the role of climate and tectonics in driving this erosion remains unclear. We define the distribution and magnitude of periglacial rockwall slope erosion across 12 catchments in Himachal Pradesh and Jammu and Kashmir in the Himalaya of northern India using cosmogenic 10Be concentrations in sediment from medial moraines. Beryllium‐10 concentrations range from 0.5 ± 0.04 × 104 to 260.0 ± 12.5 × 104 at/g SiO2, which yield erosion rates between 7.6 ± 1.0 and 0.02 ± 0.004 mm/a. Between ∼0.02 and ∼8 m of rockwall slope erosion would be possible in this setting across a single millennium, and >2 km when extrapolated for the Quaternary period. This erosion affects catchment sediment flux and glacier dynamics, and helps to establish the pace of topographic change at the headwaters of catchments. We combine rockwall erosion records from the Himalaya of Himachal Pradesh, Jammu and Kashmir, and Uttarakhand in India and Baltistan in Pakistan to create a regional erosion data set. Rockwall slope erosion rates progressively decrease with distance north from the Main Central Thrust and into the interior of the orogen. The distribution and magnitude of this erosion is most closely associated with records of Himalayan denudation and rock uplift, where the highest rates of change are recorded in the Greater Himalaya sequences. This suggests that tectonically driven uplift, rather than climate, is a first order control on patterns of rockwall slope erosion in the northwestern Himalaya. Precipitation and temperature would therefore come as secondary controls.

show abstract

Sidewall erosion: Insights from in situ‐produced ¹⁰Be concentrations measured on supraglacial clasts (Mont Blanc massif, France)

Cited by 9 publications

References 75 publications

Climatic and structural controls on Late‐glacial and Holocene rockfall occurrence in high‐elevated rock walls of the Mont Blanc massif (Western Alps)

Climatic and structural controls on Late‐glacial and Holocene rockfall occurrence in high‐elevated rock walls of the Mont Blanc massif (Western Alps)

Production and Transport of Supraglacial Debris: Insights From Cosmogenic ¹⁰Be and Numerical Modeling, Chhota Shigri Glacier, Indian Himalaya

Rockwall Slope Erosion in the Northwestern Himalaya

Contact Info

Product

Resources

About

Sidewall erosion: Insights from in situ‐produced 10Be concentrations measured on supraglacial clasts (Mont Blanc massif, France)

Cited by 9 publications

References 75 publications

Climatic and structural controls on Late‐glacial and Holocene rockfall occurrence in high‐elevated rock walls of the Mont Blanc massif (Western Alps)

Climatic and structural controls on Late‐glacial and Holocene rockfall occurrence in high‐elevated rock walls of the Mont Blanc massif (Western Alps)

Production and Transport of Supraglacial Debris: Insights From Cosmogenic 10Be and Numerical Modeling, Chhota Shigri Glacier, Indian Himalaya

Rockwall Slope Erosion in the Northwestern Himalaya

Contact Info

Product

Resources

About

Sidewall erosion: Insights from in situ‐produced ¹⁰Be concentrations measured on supraglacial clasts (Mont Blanc massif, France)

Production and Transport of Supraglacial Debris: Insights From Cosmogenic ¹⁰Be and Numerical Modeling, Chhota Shigri Glacier, Indian Himalaya