A fractal fragmentation model for rockfalls

Ruiz-Carulla, Roger; Corominas, Jordi; Mavrouli, Olga

doi:10.1007/s10346-016-0773-8

Cited by 82 publications

(76 citation statements)

References 67 publications

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“…2 As the cliffs of the Mont Blanc massif exceed several hundred metres in height, there are numerous impacts, during falls, both in-between blocks and against the rockwall. The estimation of parameters for such a fractal model (Ruiz-Carulla et al, 2016) is beyond the scope of this paper, but we suggest that this type of model explains why the supraglacial 10 Be concentration is not dependent on clast size. Therefore, the block size distribution on top of the glacier extends over several orders of magnitude (Godon et al, 2013), and the debris mass has fractal properties (Turcotte, 1986).…”

Section: Discussionmentioning

confidence: 97%

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

Sarr

Mugnier

Abrahami

et al. 2019

Earth Surf Processes Landf

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Sidewall erosion because of rockfalls is one of the most efficient erosional processes in the highest parts of mountain ranges; it is therefore important to quantify sidewall erosion to understand the long‐term evolution of mountainous topography. In this study, we analyse how the 10Be concentration of supraglacial debris can be used to quantify sidewall erosion in a glaciated catchment. We first analyse, in a glaciated catchment, the cascade of processes that move a rock from a rockwall to a supraglacial location and propose a quantitative estimate of the number of rockfalls statistically mixed in a supraglacial sand sample. This model incorporates the size of the rockwall, a power law distribution of the size of the rockfalls and the mean glacial transport velocity. In the case of the Bossons glacier catchment (Mont Blanc massif), the 10Be concentrations obtained for supraglacial samples vary from 1.97 ± 0.24 to 23.82 ± 1.68 × 104 atoms g−1. Our analysis suggests that part of the 10Be concentration dispersion is related to an insufficient number of amalgamated rockfalls that does not erase the stochastic nature of the sidewall erosion. In the latter case, the concentration of several collected samples is averaged to increase the number of statistically amalgamated rockfalls. Variable and robust 10Be‐derived rockwall retreat rates are obtained for three distinct rockfall zones in the Bossons catchment and are 0.19 ± 0.08 mm year−1, 0.54 ± 0.1 mm year−1 and 1.08 ± 0.17 mm year−1. The mean 10Be retreat rate for the whole catchment (ca. 0.65 mm year−1) is close to the present‐day erosion rate derived from other methods. © 2019 John Wiley & Sons, Ltd.

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Section: Discussionmentioning

confidence: 97%

“…This transformation leads to a fractal distribution of the debris deposited in a supraglacial location from sand to boulders (adapted fromRuiz-Carulla et al, 2016). The rockfall event can be considered as a transformation from the block size distribution in the rockwall to the resulting block size distribution in the rockfall.…”

mentioning

confidence: 99%

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

Sarr

Mugnier

Abrahami

et al. 2019

Earth Surf Processes Landf

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“…This behavior is observed here, with a threefold reduction in

\overset{V_{R}}{true}

for T int = 1 hr, as compared to T int = 30 days. Conversely, while our monitoring should not alter the assessment of the largest or worst‐case event (Corominas et al, ), an increase in f (V R ) and a reduction in

\overset{V_{R}}{true}

at the point of release is significant for rockfall remediation (Corominas et al, ), for models that predict the ease with which rockfall debris can be remobilized or weathered based on clast volume or surface area (Messenzehl et al, ), and for interpretations of rockfall magnitude‐frequency from deposit granulometry (Crosta et al, ; Ruiz‐Carulla et al, ).…”

Section: Discussionmentioning

confidence: 99%

The Importance of Monitoring Interval for Rockfall Magnitude‐Frequency Estimation

et al. 2019

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Rockfalls commonly exhibit power law volume‐frequency distributions, where fewer large events are observed relative to more numerous small events. Within most inventories, the smallest rockfalls are the most difficult to detect and so may not be adequately represented. A primary challenge occurs when neighboring events within a single monitoring interval are recorded as one, producing ambiguity in event location, timing, volume, and frequency. Identifying measurement intervals that minimize these uncertainties is therefore essential. To address this, we use an hourly data set comprising 8,987 3‐D point clouds of a cliff that experiences frequent rockfalls. Multiple rockfall inventories are derived from this data set using change detections for the same 10‐month period, but over different monitoring intervals. The power law describing the probability distribution of rockfall volumes is highly sensitive to monitoring interval. The exponent, β, is stable for intervals >12 hr but increases nonlinearly over progressively short timescales. This change is manifested as an increase in observed rockfall numbers, from 1.4 × 103 (30 day intervals) to 1.4 × 104 (1 hr intervals), and a threefold reduction in mean rockfall volume. When the monitoring interval exceeds 4 hr, the geometry of detected rockfalls becomes increasingly similar to that of blocks defined by rock mass structure. This behavior change reveals a time‐dependent component to rockfall occurrence, where smaller rockfalls (identifiable from more frequent monitoring) are more sensitive to progressive deformation of the rock mass. Acquiring complete inventories and attributing discrete controls over rockfall occurrence may therefore only be achievable with high‐frequency monitoring, dependent upon local lithology.

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“…The first experiment was conducted at Foj quarry (41.361°N, 1.923°E), and the second at Ponderosa quarry (41.163°N, 0.943°E). Both tests were carried out in the framework of the project RockRisk (Corominas et al, ), an important part of which has been dedicated to determining fragmentation of rock masses and its application in fragmentation and propagation models (Matas et al, , ; Ruiz‐Carulla et al, , ). In this study, we concentrated on the emitted seismic energy values and time ( t )‐frequency ( f ) features of recorded signals and compared them to free‐fall kinetics and fragmentation, respectively.…”

Section: Introductionmentioning

confidence: 99%

Seismic Energy Analysis as Generated by Impact and Fragmentation of Single‐Block Experimental Rockfalls

et al. 2018

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The analysis of seismic signals obtained from near‐source triaxial accelerometer recordings of two sets of single‐block rockfall experiments is presented. The tests were carried out under controlled conditions in two quarries in northeastern Spain; in the first test (Foj limestone quarry, Barcelona), 30 blocks were released with masses ranging between 475 and 11,480 kg. The second test (Ponderosa andesite quarry, Tarragona) consisted of the release of 44 blocks with masses from 466 to 13,581 kg. An accelerometer and three high‐speed video cameras were deployed, so that the trajectories, velocities, and block fragmentation could be tracked precisely. These data were used to explore the relationship between seismic energy and rockfall kinetics (the latter obtained from video analysis). We determined absolute and relative values of seismic energy and used them to estimate rockfall volumes. Finally, the seismic signature of block fragmentation was assessed in both the frequency and time domains. The ratios of seismic energy after impact to kinetic energy before impact ranged between 10−7 and 10−4. These variables were weakly correlated. The use of seismic energy relative to impacting kinetic energy was preferred for the estimation of volumes. Block fragmentation impacts were dominated by higher acceleration spectrum centroid frequencies than those of nonfragmentation impacts: 56.62 ± 2.88 and 48.46 ± 4.39 Hz at Foj and 52.84 ± 12.73 and 38.14 ± 4.73 Hz at Ponderosa.

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A fractal fragmentation model for rockfalls

Cited by 82 publications

References 67 publications

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

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

The Importance of Monitoring Interval for Rockfall Magnitude‐Frequency Estimation

Seismic Energy Analysis as Generated by Impact and Fragmentation of Single‐Block Experimental Rockfalls

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A fractal fragmentation model for rockfalls

Cited by 82 publications

References 67 publications

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

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

The Importance of Monitoring Interval for Rockfall Magnitude‐Frequency Estimation

Seismic Energy Analysis as Generated by Impact and Fragmentation of Single‐Block Experimental Rockfalls

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Product

Resources

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

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