Depth-dependent soil mixing persists across climate zones

Gray, Harrison J.; Keen‐Zebert, Amanda; Furbish, David Jon; Tucker, G. E.; Mahan, Shannon A.

doi:10.1073/pnas.1914140117

Cited by 36 publications

(33 citation statements)

References 72 publications

(104 reference statements)

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“…For example, the ability to create a small version of a river reach in a laboratory and then measure long time series of bed load flux in order to fully characterize the fluctuations and ensembleaveraged behavior of such series in relation to bedform dynamics (Dhont and Ancey, 2018;Ancey and Pascal, 2020) is simply not a possibility in studies of natural soil creep and its long-term consequences. Indeed, we have only recently achieved the ability to measure small particle motions involved in soil creep (Deshpande et al, 2021), yet the particle residence times of soil mantled hillslopes may be 10 000 years or more, thus requiring indirect measures of particle behavior such as tracer particle mixing (Furbish et al, 2018c;Gray et al, 2020).…”

Section: Uncertainty With Growing Scalesmentioning

confidence: 99%

Rarefied particle motions on hillslopes – Part 4: Philosophy

Furbish

Doane

2021

Earth Surf. Dynam.

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Abstract. Theoretical and experimental work (Furbish et al., 2021a, b, c) indicates that the travel distances of rarefied particle motions on rough hillslope surfaces are described by a generalized Pareto distribution. The form of this distribution varies with the balance between gravitational heating due to conversion of potential to kinetic energy and frictional cooling by particle–surface collisions. The generalized Pareto distribution in this problem is a maximum entropy distribution constrained by a fixed energetic “cost” – the total cumulative energy extracted by collisional friction per unit kinetic energy available during particle motions. The analyses leading to these results provide an ideal case study for highlighting three key elements of a statistical mechanics framework for describing sediment particle motions and transport: the merits of probabilistic versus deterministic descriptions of sediment motions, the implications of rarefied versus continuum transport conditions, and the consequences of increasing uncertainty in descriptions of sediment motions and transport that accompany increasing length scales and timescales. We use the analyses of particle energy extraction, the spatial evolution of particle energy states, and the maximum entropy method applied to the generalized Pareto distribution as examples to illustrate the mechanistic yet probabilistic nature of the approach. These examples highlight the idea that the endeavor is not simply about adopting theory or methods of statistical mechanics “off the shelf” but rather involves appealing to the style of thinking of statistical mechanics while tailoring the analysis to the process and scale of interest. Under rarefied conditions, descriptions of the particle flux and its divergence pertain to ensemble conditions involving a distribution of possible outcomes, each realization being compatible with the controlling factors. When these factors change over time, individual outcomes reflect a legacy of earlier conditions that depends on the rate of change in the controlling factors relative to the intermittency of particle motions. The implication is that landform configurations and associated particle fluxes reflect an inherent variability (“weather”) that is just as important as the expected (“climate”) conditions in characterizing system behavior.

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Section: Uncertainty With Growing Scalesmentioning

confidence: 99%

Rarefied particle motions on hillslopes – Part 4: Philosophy

Furbish

Doane

2021

Earth Surf. Dynam.

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“…The hypothesized grain motions in Culling's model, however, are inconsistent with known granular mechanics (Supplementary Note 1); moreover, these motions have never been experimentally examined. Researchers have begun to recognize the need to understand grain-scale dynamics, in order to derive physically informed models of soil mixing and transport on hillslopes 18,19 . Decades of tracer measurements have produced coarse profiles of soil displacement on hillslopes 5 that are generally exponential 5,20,21 (Fig.…”

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confidence: 99%

The perpetual fragility of creeping hillslopes

et al. 2021

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Soil creeps imperceptibly but relentlessly downhill, shaping landscapes and the human and ecological communities that live within them. What causes this granular material to ‘flow’ at angles well below repose? The unchallenged dogma is churning of soil by (bio)physical disturbances. Here we experimentally render slow creep dynamics down to micron scale, in a laboratory hillslope where disturbances can be tuned. Surprisingly, we find that even an undisturbed sandpile creeps indefinitely, with rates and styles comparable to natural hillslopes. Creep progressively slows as the initially fragile pile relaxes into a lower energy state. This slowing can be enhanced or reversed with different imposed disturbances. Our observations suggest a new model for soil as a creeping glass, wherein environmental disturbances maintain soil in a perpetually fragile state.

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“…Richardson et al, 2019) and converting this range into mobile regolith disturbance rate following equations in Tucker et al (2018). To obtain a range for mobile regolith production rate, we note that the Peclet Number, a measure of the relative magnitude of mobile regolith disturbance versus production, appears to fall into a range of 0.1-1 in global compilations, meaning that the orders of magnitude are roughly comparable (Gray et al, 2020). As such, we test the parameter space over a similar range as the mobile regolith disturbance rate.…”

Section: Continuous Time Stochastic Cellular Automata Modellingmentioning

confidence: 99%

“…For example, the debris facies in the model can form either due to the lack of internal cohesion of the parent material (high rates of lateral collapse), or due to mobile regolith forming processes acting on the exposed free-face, similar to interpretations by Wallace (1977). Such mobile regolith forming/disturbing processes could involve burrowing mammals, root growth, shrink-swell, and freeze-thaw cycles among many others (Gray et al, 2020). Another example is the field-observed effect of microclimate on scarp degradation where aspect-controlled water contents affect the degradation rate (e.g.…”

Section: Sensitivity To Geomorphic Parametersmentioning

confidence: 99%

A geomorphic-process-based cellular automata model of colluvial wedge morphology and stratigraphy

Gray

DuRoss

Nicovich

et al. 2021

Preprint

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Abstract. The development of colluvial wedges at the base of fault scarps following normal-faulting earthquakes serves as a sedimentary record of paleoearthquakes and is thus crucial in assessing seismic hazard. Although there is a large body of observations of colluvial wedge development, connecting this knowledge to the physics of sediment transport can open new frontiers in our understanding. To explore theoretical colluvial wedge evolution, we develop a cellular automata model driven by the production and disturbance (e.g. bioturbative reworking) of mobile regolith and fault scarp collapse. We consider both 90° and 60° dipping faults and allow the colluvial wedges to develop over 2,000 model years. By tracking sediment transport time, velocity, and provenance, we classify cells into analogs for the debris and wash sedimentary facies commonly described in paleoseismic studies. High values of mobile regolith production and disturbance rates produce relatively larger and more wash facies dominated wedges, whereas lower values produced relatively smaller, debris facies dominated wedges. Higher lateral collapse rates lead to more debris facies relative to wash facies. Many of the modelled colluvial wedges fully developed within 2000 model years after the earthquake with many being much faster when process rates are high. Finally, for scenarios with the same amount of vertical displacement, different size colluvial wedges developed depending on the rates of geomorphic processes and fault dip. A change in these variables, say by environmental change such as precipitation rates, could theoretically result in different colluvial wedge facies assemblages for the same characteristic earthquake rupture scenario. Finally, the stochastic nature of collapse events, when coupled with high disturbance, illustrate that multiple phases of colluvial deposition are theoretically possible for a single earthquake event.

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Depth-dependent soil mixing persists across climate zones

Cited by 36 publications

References 72 publications

Rarefied particle motions on hillslopes – Part 4: Philosophy

Rarefied particle motions on hillslopes – Part 4: Philosophy

The perpetual fragility of creeping hillslopes

A geomorphic-process-based cellular automata model of colluvial wedge morphology and stratigraphy

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