Statistical modelling of co-seismic knickpoint formation and river response to fault slip

Steer, Philippe; Croissant, Thomas; Baynes, Edwin; Lague, Dimitri

doi:10.5194/esurf-7-681-2019

Cited by 7 publications

(6 citation statements)

References 99 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A solution with m = 0.24 and n = 1, but considering a non-negligible incision threshold, was found to best explain the geometry of colluvial valleys in the Siwalik Hills of Nepal for drainage area between 7 × 10 −3 and 1 km 2 , representing the thresholds in drainage area between colluvial valleys and hillslopes or rivers, respectively (Lague and Davy, 2003). Below the area transition between colluvial valleys and hillslopes, the power-law scaling for the slope-area relationship becomes flat, due to landsliding and mass wasting processes, or reverts where hilltops are convex (Ijjasz-Vasquez and Bras, 1995;Tarolli and Dalla Fontana, 2009). Once again, this hillslope domain could be geometrically modelled using the SPIM with different m and n, e.g.…”

Section: Solving For River and Hillslope Dynamicsmentioning

confidence: 99%

Short communication: Analytical models for 2D landscape evolution

Steer

2021

Earth Surf. Dynam.

Self Cite

View full text Add to dashboard Cite

Abstract. Numerical modelling offers a unique approach to understand how tectonics, climate and surface processes govern landscape dynamics. However, the efficiency and accuracy of current landscape evolution models remain a certain limitation. Here, I develop a new modelling strategy that relies on the use of 1D analytical solutions to the linear stream power equation to compute the dynamics of landscapes in 2D. This strategy uses the 1D ordering, by a directed acyclic graph, of model nodes based on their location along the water flow path to propagate topographic changes in 2D. This analytical model can be used to compute in a single time step, with an iterative procedure, the steady-state topography of landscapes subjected to river, colluvial and hillslope erosion. This model can also be adapted to compute the dynamic evolution of landscapes under either heterogeneous or time-variable uplift rate. This new model leads to slope–area relationships exactly consistent with predictions and to the exact preservation of knickpoint shape throughout their migration. Moreover, the absence of numerical diffusion or of an upper bound for the time step offers significant advantages compared to numerical models. The main drawback of this novel approach is that it does not guarantee the time continuity of the topography through successive time steps, despite practically having little impact on model behaviour.

show abstract

Section: Solving For River and Hillslope Dynamicsmentioning

confidence: 99%

Short communication: Analytical models for 2D landscape evolution

Steer

2021

Earth Surf. Dynam.

Self Cite

View full text Add to dashboard Cite

show abstract

“…k s has also been interpreted as an indirect expression of base-level change resulting from tectonics (e.g. Hurst et al, 2019;Ouimet et al, 2009;Steer et al, 2019;Wobus, Whipple, Kirby, et al, 2006) or climate driven Neely et al, 2017), where steepened high k s patches migrate upstream. Recent studies (e.g.…”

Section: Channel Steepness Tectonics and Lithologymentioning

confidence: 99%

“…In both these studies, concentrated relative uplift could be caused by deep structures (e.g., midcrustal ramps) under the mountain belt. s k has also been interpreted as an indirect expression of base-level change resulting from tectonics (e.g., Hurst et al, 2019;Ouimet et al, 2009;Steer et al, 2019; or climate driven Neely et al, 2017) As tectonics, climate and stream piracy can affect channel steepness by inducing external forcings to the river channels, intrinsic forcings (e.g., fractures, weathering, lithology) will also affect s k . Amongst these intrinsic forcings, the effect of differential lithology on fluvial morphology has been a recent focus of geomorphological studies (e.g., Bernard et al, 2019;Campforts et al, 2019;Forte et al, 2016;Kirby et al, 2003;Peifer Bezerra, 2018;Seagren & Schoenbohm, 2019;Strong et al, 2019;Thaler & Covington, 2016;Yanites et al, 2017).…”

Section: Channel Steepness Tectonics and Lithologymentioning

confidence: 99%

“…In both these studies, concentrated relative uplift could be caused by deep structures (e.g., midcrustal ramps) under the mountain belt.

k_{s}

has also been interpreted as an indirect expression of base‐level change resulting from tectonics (e.g., Hurst et al., 2019; Ouimet et al., 2009; Royden & Perron, 2013; Steer et al., 2019; Wobus, Whipple, et al., 2006) or climate driven (Crosby & Whipple, 2006; Neely et al., 2017), where steepened high

k_{s}

patches migrate upstream. Recent studies (e.g., Giachetta & Willett, 2018; Seagren & Schoenbohm, 2019) have also highlighted the effect of stream piracy on

k_{s}

, where captured areas disrupt the upstream drainage area, base level and sediment supply balance, affecting the downstream channel steepness.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

See 1 more Smart Citation

Isolating Lithologic Versus Tectonic Signals of River Profiles to Test Orogenic Models for the Eastern and Southeastern Carpathians

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Discrete temporal changes in uplift rates or in base-level elevation can lead to sharp ruptures in the slope of river profiles, generally referred to as knickpoints (e.g., Rosenbloom & Anderson, 1994;Whipple & Tucker, 1999;Steer et al, 2019). Finite difference solutions to the stream power equation inherently lead to a progressive numerical diffusion of knickpoints during their migration, even with = 1, while the algorithm developed here preserves the shape of knickpoints.…”

Section: Time Variable Uplift and Knickpoint Propagationmentioning

confidence: 99%

Short communication: Analytical models for 2D landscape evolution

Steer¹

2021

Preprint

Self Cite

View full text Add to dashboard Cite

Abstract. Numerical modelling offers a unique approach to understand how tectonics, climate and surface processes govern landscape dynamics. However, the efficiency and accuracy of current landscape evolution models remain a certain limitation. Here, I develop a new modelling strategy that relies on the use of 1D analytical solutions to the linear stream power equation to compute in 2D the dynamics of landscapes. This strategy uses the 1D ordering, by a directed acyclic graph, of model nodes based on their location along the water flow path to propagate topographic changes in 2D. I demonstrate that this analytical model can be used to compute in a single time step, with an iterative procedure, the steady-state topography of landscapes subjected to river, colluvial and hillslope erosion. This model can also be adapted to compute the dynamic evolution of landscapes under either heterogeneous or time-variable uplift rate. This new model leads to slope-area relationships exactly consistent with predictions and to the exact preservation of knickpoint shape throughout their migration. Moreover, the absence of numerical diffusion or of an upper bound for the time step offer significant advantages compared to numerical models. The main drawback of this novel approach is that it does not guarantee the time-continuity of the topography through successive time steps, despite practically having little impact on model behaviour.

show abstract

Statistical modelling of co-seismic knickpoint formation and river response to fault slip

Cited by 7 publications

References 99 publications

Short communication: Analytical models for 2D landscape evolution

Short communication: Analytical models for 2D landscape evolution

Isolating Lithologic Versus Tectonic Signals of River Profiles to Test Orogenic Models for the Eastern and Southeastern Carpathians

Short communication: Analytical models for 2D landscape evolution

Contact Info

Product

Resources

About