基于扩散方程的陡坎形貌测年方法进展

doi:10.3969/j.issn.0253-4967.2023.04.001

摘要/Abstract

摘要：

陡坎是一种自然界常见的台阶状地貌, 但其形成年龄通常很难直接测定。发育在松散堆积物中的陡坎经过初期短暂的重力垮塌之后, 将经历漫长的低能退化过程。如果陡坎剖面形态的演化可基于扩散方程来模拟, 且扩散系数可独立标定, 即可利用陡坎地形剖面估算其年龄, 这种方法被称为形貌测年。文中简要回顾了陡坎形貌测年的研究历史, 介绍并讨论了陡坎退化的概念模型与扩散模型, 特别是非线性扩散模型的建立及求解、参数在扩散模型中所起的作用、最佳陡坎形貌年龄的确定流程等, 分析了陡坎上、下地貌面坡度对陡坎退化的影响, 编制了非线性扩散模型的年龄图版, 给出了图版的应用实例, 验证了形貌测年方法的有效性。线性扩散模型和非线性扩散模型均可用于单次事件陡坎的退化分析, 但对于年轻的单次事件陡坎推荐使用非线性扩散模型。断层重复活动形成的陡坎的退化分析则需要谨慎对待, 恒定滑动速率陡坎的非线性扩散模型适用于模拟年龄<10ka、活动速率高的断层陡坎的演化; 多次事件陡坎模型(包括线性扩散和非线性扩散)需要仔细评估每次事件在陡坎剖面上的断错位置及其位移量。尽管陡坎形貌测年方法存在很多假设条件, 但目前快速获取一定范围内的高分辨率地形数据已成为现实, 从这些数据中可以沿着同一陡坎提取大量剖面进行分析, 继而得到具有统计意义的结果, 这为陡坎退化分析和形貌测年方法提供了广阔的应用前景。

关键词: 陡坎, 陡坎退化, 扩散模型, 形貌测年, 断层陡坎

Abstract:

A scarp is a common step-like landform in nature, which consists of a gently sloping plane connected to the upper and lower geomorphic surfaces of differing elevations. Common scarps include fault scarps, terrace scarps, lake shoreline scarps, shoreline scarps, volcanic ash cinder cones, etc. Scarps are often used as strain markers because of their linear characteristics and are favored in the study of active tectonics. However, it is difficult to directly constrain their ages. Instead, they are usually constrained by the ages of the upper and lower geomorphic surfaces. The scarp developed in loose deposits is controlled by a long process of low-energy degradation after a short collapse. This process can be modeled by the diffusion equation because the process can be considered as a slope process under the transport-limited condition. Under this condition, the slope can provide enough loose material for transport, that is, the material transport capacity is less than the material supply capacity. If process assumptions are sufficiently valid and rate constraints can be calibrated independently, the true age of scarps can be obtained. This method is called morphologic dating. This method has been included in many textbooks published overseas, but there have very little research on this method in China. Both linear and nonlinear models have been developed to describe scarp degradation. Linear diffusion models assume that the diffusion coefficient is a constant, whereas nonlinear transport models generally define the diffusion coefficient as a nonlinear function related to the topographic gradient. Compared to the linear transport models, nonlinear transport models can better explain the phenomenon of rapidly increasing deposition flux as the gradient approaches a critical value. In this paper, we review the study history of scarp degradation analysis and the concept model of scarp degradation. We focus on the establishment of the nonlinear model, the role of the different parameters in profile evolution, determining the best-fit age using a full-scarp nonlinear modeling procedure, and so on. Furthermore, we introduce the model of the nonlinear age chart, including the effect of far-field slope on morphologic dating of scarp-like landforms and two examples of the application of the chart, which shows that this method can correctly evaluate the ages of single-event scarps. Finally, we discuss the extension of the concept and method of the scarp degradation model, the applicability of the model, and repeated fault scarp morphological analysis. For nonlinear diffusion models, in addition to n equal to 2, two parameters (critical gradient (S_c) and diffusion constant (k)) need to be constrained. The critical gradient can be obtained from the young scarps in the study area, which roughly represents the initial state of scarp evolution, typically 0.6 to 0.7(30° to 35°). The diffusion constant needs to be characterized by a known age scarp. The slopes of the upper and lower geomorphic surfaces have an obvious influence on the morphology of a degraded scarp. These discussions indicate that both linear and nonlinear models can be used for the degradation analysis of single-event scarps, but a nonlinear diffusion model is recommended for young single-event scarps. The constant slip rate nonlinear model can be used to simulate the evolution history of<10ka high-slip rate active fault scarp. The multiple-event scarp model requires careful evaluation of the fault location and the amount of displacement per event. There are several assumptions in the scarp topography diffusion modeling, which require practice to verify its reliability. With advances in surveying technology, it is now possible to rapidly obtain high-resolution terrain data over broad areas from which numerous topographic profiles can be efficiently extracted. This provides a broad application prospect for scarp degradation analysis and morphologic dating.

Key words: scarp, scarp degradation, diffusion model, morphologic dating, fault scarp

许建红, 陈杰, 魏占玉, 李涛. 基于扩散方程的陡坎形貌测年方法进展[J]. 地震地质, 2023, 45(4): 811-832.

XU Jian-hong, CHEN Jie, WEI Zhan-yu, LI Tao. MORPHOLOGIC DATING OF SCARP MORPHOLOGY BASED ON DIFFUSION EQUATION: A REVIEW[J]. SEISMOLOGY AND GEOLOGY, 2023, 45(4): 811-832.

图/表 9

图 1 单次事件断层陡坎的剖面形态随时间的演化(Wallace, 1977) 红色虚线代表前一个状态下的剖面形态

Fig. 1 Sequence of single-event fault scarp degradation(Wallace, 1977).

图 2 陡坎地形梯度和沉积通量之间的理论关系(Xu et al., 2021) a 线性关系(黑色细实线)(Hanks et al., 1984); b 经典非线性关系(蓝色点划线)(Roering et al., 1999)。当地形梯度接近临界梯度时, 沉积通量趋于无限大, 超过临界梯度时, 沉积通量变为负值; c Pelletier(2008)改进的非线性关系(在其公式中取Cmax=40, 红色虚线), 可避免无限通量, 但没有解决负值的问题; d de' Michieli Vitturi等(2013)改进的非线性关系(在其公式中取Cmax=20, 绿色点线), 虽可同时避免无限通量和负值, 但指数曲线段偏离了经典的非线性关系; e 适用于数值计算的非线性关系(灰色粗实线)(Xu et al., 2021)

Fig. 2 Relationship between hillslope gradient and sediment flux(Xu et al., 2021).

图 3 扩散模型中的参数变化对模型输出的影响(Xu et al., 2021) a 对于非线性扩散模型, 随着临界梯度增大, 沉积通量由小变大的转换位置对应的梯度也会增大; b 对于线性扩散模型, 侵蚀和堆积分别集中在陡坎的肩部和坡脚。当陡坎年龄t<4ka, 陡坎最大坡度几乎没有变化, 随着陡坎年龄增加至t>4ka, 其最大坡度才逐渐变小; c 对于非线性扩散模型, 侵蚀和堆积仍分别集中在陡坎的肩部和坡脚, 其最大坡度从一开始就随时间逐渐变小; d 对于不同的扩散常数k, 经过相同的演化时间之后, 更大的k值对应更明显的陡坎肩部侵蚀和坡脚堆积。然而,如果k·t的值相等, 陡坎剖面的最终形态相同, 与k和t各自的大小无关

Fig. 3 The influence of parameter changes on scarp evolution within diffusion models(Xu et al., 2021).

Fig. 4 基于DEM提取的条带状剖面确定陡坎年龄的流程(Wei et al., 2015) The scheme for exploiting DEM to conduct swath profile-based morphologic dating(Wei et al., 2015).a DEM栅影图可用于识别陡坎和确定陡坎剖面的位置。黑线代表条带状剖面的中线, 图中标记的为6m宽的DEM条带; b 从DEM数据中提取的条带状剖面的三维视图。将条带内所有栅格点投影到黑色中线上; c 实测陡坎距离-高度剖面和不同时间节点模拟得到的陡坎距离-高度剖面。黑色点代表的剖面对应图b中的条带状DEM剖面。黑色和红色细线代表不同时间节点的模拟剖面, 其中红线代表了最佳模拟剖面; d 在时间为t的范围内模拟陡坎的梯度剖面, 与图c中的剖面对应, 红色的梯度剖面代表最佳拟合结果; e 实测梯度剖面与模拟梯度剖面之间的均方根误差。中间的竖线代表由最小RMSE2确定的最佳年龄t(实际年龄(ka)或形貌年龄(m2)), 两侧的竖线则代表了由卡方分布确定的1个标准差

图 5 用于识别数据丛集的累积概率密度(CPD)方法 a 沿陡坎不同距离上的剖面(通常间距数米至几十米)限定的陡坎年龄(实际年龄(ka)或形貌年龄(m2))的概率密度分布, 带误差棒的红色圆点代表了陡坎年龄和1个标准差; b 叠加陡坎年龄的概率密度分布可以得到累积概率密度分布图, 从中可以确定具有统计意义的陡坎年龄, 即概率最大值和标准差, 标准差可以反映数据的集中度。右侧的颜色棒(Color bar)中标示了不同概率对应的颜色, 1个标准差大体对应由蓝色向黄色转变的位置

Fig. 5 Identifying clusters of data using the Cumulative Probability Density(CPD)method.

图 6 陡坎上、下地貌面的坡度对陡坎退化的影响左侧为初始状态下的陡坎高度(a)和坡度剖面(b), 右侧为退化一定时间后的陡坎高度(c)和坡度剖面(d)。与上、下地貌面水平的剖面(标准)相比, 当上、下地貌面的坡向与陡坎倾向一致时, 会整体抬高陡坎坡度值(正倾); 当上、下地貌面的坡向与陡坎倾向相反时, 会整体降低坡度值(反倾); 上、下地貌面倾斜程度不同的剖面(异形),坡度变化的幅度约等于上、下地貌面坡度的平均值

Fig. 6 Effect of far-field slope on scarp degradation.

图 7 陡坎非线性扩散模型的年龄图版 a 高度-最大坡度图版; b 年龄-最大坡度图版。使用非线性扩散模型制作图版, 模型参数分别为:临界梯度Sc=tan33°, 非线性指数n=2, 扩散常数k=1m2/ka

Fig. 7 Scarp age pattern of nonlinear diffusion model.

Fig. 8 示例已有研究成果 Examples of existing research results.a 中国西部帕米尔高原木吉盆地内齐姆干河出山口处阶地陡坎的数据, 图版完全可以区分2级高度不同的阶地陡坎; b 美国博纳维尔(Bonneville)湖岸线陡坎的数据, 沿同一陡坎不同高度的陡坎剖面限定的形貌年龄很好地集中在15~20m2。图中实心圆和空心圆分别代表沿陡坎不同位置的陡坎高度和最大坡度值(图b考虑了陡坎上、下地貌面的坡度)

表 1 重复活动断层陡坎的“形貌年龄”与实际年龄对比

Table 1 Comparison of morphologic age and the actual age of repeated active fault scarps<br

断错次数	Δh=0.2m, Δt=2ka, θ_f=2°					Δh=0.5m, Δt=2.5ka, θ_f=2°
	H	R_age	M_age	M_φ	Ratio	H	R_age	M_age	M_φ	Ratio
1	0.2	2	2	4.3	1.0	0.5	2.5	2.5	5.9	1.0
2	0.4	4	3.1	5.7	0.8	1	5	3.5	8.7	0.7
3	0.6	6	4.2	6.7	0.7	1.5	7.5	4.4	10.7	0.6
4	0.8	8	5	7.5	0.6	2	10	5.1	12.4	0.5
5	1	10	5.8	8.3	0.6	2.5	12.5	6	13.6	0.5
8	1.6	16	8.2	10.0	0.5	4	20	8.2	16.4	0.4
10	2	20	9.7	10.9	0.5	5	25	9.6	17.6	0.4
16	3.2	32	14.2	12.9	0.4	8	40	13.6	20.2	0.3

参考文献 65

[1]	邓起东, 尤惠川. 1985. 断层崖研究与地震危险性估计: 以贺兰山东麓断层崖为例[J]. 西北地震学报, 7(1): 29-38.
	DENG Qi-dong, YOU Hui-chuan. 1985. Fault scarps research and earthquake risk estimation: Example in eastern Holanshan fault scarps[J]. Northwestern Seismological Journal, 7(1): 29-38 (in Chinese).
[2]	侯康明, 韩有珍, 张守杰. 1995. 断层崖形成年代的数学模拟计算[J]. 西北地震学报, 17(2): 68-75, 81.
	HOU Kang-ming, HAN You-zhen, ZHANG Shou-jie. 1995. Mathematical model calculation of fault scarp age[J]. Northwestern Seismological Journal, 17(2): 68-75, 81 (in Chinese).
[3]	黄昭. 1987. 贺兰山东麓断层崖的形态与年代测定方法[G]//国家地震局地质研究所编. 现代地壳运动研究(3). 北京: 地震出版社: 63-82.
	HUANG Zhao. 1987. Morphology and dating method of fault scarps on the eastern front of the Helan Shan Mountains [G]//Institute of Geology, State Seismology Bureau(Eds). Research on Recent Crustal Movement(3). Seismological Press, Beijing: 63-82 (in Chinese).
[4]	邱祝礼, 李有利, 南峰. 2005. 断层陡崖、沟谷演化模型及三维可视化[J]. 水土保持研究, 12(4): 35-38, 84.
	QIU Zhu-li, LI You-li, NAN Feng. 2005. Research on the evolutional model of scarps and valleys along faults and visualization[J]. Research of Soil and Water Conservation, 12(4): 35-38, 84 (in Chinese).
[5]	闫计明, 魏占玉, 何宏林. 2013. 黄土地区坡面侵蚀率的实验研究[J]. 地震地质, 35(4): 793-804. doi: 10.3969/j.issn.0253-4967.2013.04.009. DOI
	YAN Ji-ming, WEI Zhan-yu, HE Hong-lin. 2013. Experimental study on erosion rate of man-made slopes in loess area[J]. Seismology and Geology, 35(4): 793-804 (in Chinese).
[6]	尤惠川, 邓起东, 冉勇康. 2004. 断层崖演化与古地震研究[J]. 地震地质, 26(1): 33-45.
	YOU Hui-chuan, DENG Qi-dong, RAN Yong-kang. 2004. Degradation of fault scarp and paleoearthquake research[J]. Seismology and Geology, 26(1): 33-45 (in Chinese).
[7]	张培震, 李传友, 毛凤英. 2008. 河流阶地演化与走滑断裂滑动速率[J]. 地震地质, 30(1): 44-57.
	ZHANG Pei-zhen, LI Chuan-you, MAO Feng-ying. 2008. Strath terrace formation and strike-slip faulting[J]. Seismology and Geology, 30(1): 44-57 (in Chinese).
[8]	Andrews D J, Bucknam R C. 1987. Fitting degradation of shoreline scarps by a nonlinear diffusion model[J]. Journal of Geophysical Research, 92(B12): 12857-12867. doi: 10.1029/JB092iB12p12857. DOI URL
[9]	Andrews D J, o T C. 1985. Scarp degraded by linear diffusion: Inverse solution for age[J]. Journal of Geophysical Research, 90(B12): 10193-10208. doi: 10.1029/jb090ib12p10193. DOI URL
[10]	Arrowsmith J R, Pollard D D, Rhodes D D. 1996. Hillslope development in areas of active tectonics[J]. Journal of Geophysical Research: Solid Earth, 101(B3): 6255-6275. doi: 10.1029/95JB02583. DOI
[11]	Arrowsmith J R, Rhodes D D, Pollard D D. 1998. Morphologic dating of scarps formed by repeated slip events along the San Andreas Fault, Carrizo Plain, California[J]. Journal of Geophysical Research: Solid Earth, 103(B5): 10141-10160. doi: 10.1029/98JB00505. DOI
[12]	Avouac J P. 1993. Analysis of scarp profiles: Evaluation of errors in morphologic dating[J]. Journal of Geophysical Research: Solid Earth, 98(B4): 6745-6754. doi: 10.1029/92JB01962. DOI
[13]	Avouac J P, Peltzer G. 1993a. Active tectonics in southern Xinjiang, China: Analysis of terrace riser and normal fault scarp degradation along the Hotan-Qira Fault system[J]. Journal of Geophysical Research, 98(B12): 21773-21807. doi: 10.1029/93JB02172. DOI URL
[14]	Avouac J P, Tapponnier P, Bai M, et al. 1993b. Active thrusting and folding along the northern Tien Shan and Late Cenozoic rotation of the Tarim relative to Dzungaria and Kazakhstan[J]. Journal of Geophysical Research: Solid Earth, 98(B4): 6755-6804. doi: 10.1029/92JB01963. DOI
[15]	Baas A C W. 2013. Quantitative Modeling of Geomorphology[M]. San Diego: Academic Press.
[16]	Bowman D, Gerson R. 1986. Morphology of the latest Quaternary surface-faulting in the Gulf of Elat region, eastern Sinai[J]. Tectonophysics, 128(1-2): 97-119. DOI URL
[17]	Bucknam R C, Anderson R E. 1979. Estimation of fault-scarp ages from a scarp-height-slope-angle relationship[J]. Geology, 7(1): 11-14. DOI URL
[18]	Clarke B A, Burbank D W. 2010. Evaluating hillslope diffusion and terrace riser degradation in New Zealand and Idaho[J]. Journal of Geophysical Research: Earth Surface, 115(F2): F02013. doi: 10.1029/2009jf001279. DOI
[19]	Cowgill E. 2007. Impact of riser reconstructions on estimation of secular variation in rates of strike-slip faulting: Revisiting the Cherchen River site along the Altyn Tagh Fault, NW China[J]. Earth and Planetary Science Letters, 254(3-4): 239-255. doi: 10.1016/j.epsl.2006.09.015. DOI URL
[20]	Crank J, Nicolson P. 1947. A practical method for numerical evaluation of solutions of partial differential equations of the heat-conduction type[J]. Mathematical Proceedings of the Cambridge Philosophical Society, 43(1): 50-67. DOI URL
[21]	Culling W E H. 1960. Analytical theory of erosion[J]. The Journal of Geology, 68(3): 336-344. DOI URL
[22]	Culling W E H. 1963. Soil creep and the development of hillside slopes[J]. The Journal of Geology, 71(2): 127-161. DOI URL
[23]	de' Michieli Vitturi M, Arrowsmith J R. 2013. Two-dimensional nonlinear diffusive numerical simulation of geomorphic modifications to cinder cones[J]. Earth Surface Processes and Landforms, 38(12): 1432-1443. doi: 10.1002/esp. 3423. DOI
[24]	Fagherazzi S, Howard A D, Wiberg P L. 2002. An implicit finite difference method for drainage basin evolution[J]. Water Resources Research, 38(7): 1116. doi: 10.1029/2001WR000721. DOI
[25]	Figueiredo P M, Nash D. 2022. Tectonic Geomorphology of Normal Faults and Their Scarps.[M]//Shroder J F(Eds). Treatise on Geomorphology(Second Edition). Academic Press, Oxford: 404-428.
[26]	Foufoula-Georgiou E, Ganti V, Dietrich W E. 2010. A nonlocal theory of sediment transport on hillslopes[J]. Journal of Geophysical Research: Earth Surface, 115(F2): F00A16. doi: 10.1029/2009JF001280. DOI
[27]	Gabet E J. 2003. Sediment transport by dry ravel[J]. Journal of Geophysical Research: Solid Earth, 108(B1): 2049. doi: 10.1029/2001JB001686. DOI
[28]	Hanks T C. 2000. The age of scarplike landforms from diffusion-equation analysis[M]//Noller J S, Sowers J M, Lettis W R(eds). Quaternary Geochronology: Methods and Applications(Volume 4).American Geophysical Union, Washington: 313-338.
[29]	Hanks T C, Andrews D J. 1989. Effect of far-field slope on morphologic dating of scarplike landforms[J]. Journal of Geophysical Research, 94(B1): 565-573. DOI URL
[30]	Hanks T C, Bucknam R C, Lajoie K R, et al. 1984. Modification of wave-cut and faulting-controlled landforms[J]. Journal of Geophysical Research: Solid Earth, 89(B7): 5771-5790.
[31]	Hanks T C, Wallace R E. 1985. Morphological analysis of the Lake Lahontan shoreline and beachfront fault scarps, Pershing County, Nevada[J]. Bulletin of the Seismological Society of America, 75(3): 835-846.
[32]	Harkins N, Kirby E. 2008. Fluvial terrace riser degradation and determination of slip rates on strike-slip faults: An example from the Kunlun fault, China[J]. Geophysical Research Letters, 35(5): L05406. doi: 10.1029/2007GL033073. DOI
[33]	Hilley G E, DeLong S, Prentice C, et al. 2010. Morphologic dating of fault scarps using airborne laser swath mapping(ALSM)data[J]. Geophysical Research Letters, 37(4): L04301. doi: 10.1029/2009GL042044. DOI
[34]	Hooper D M, Sheridan M F. 1998. Computer-simulation models of scoria cone degradation[J]. Journal of Volcanology and Geothermal Research, 83(3): 241-267. DOI URL
[35]	Hsu L, Pelletier J D. 2004. Correlation and dating of Quaternary alluvial-fan surfaces using scarp diffusion[J]. Geomorphology, 60(3-4): 319-335. doi: 10.1016/j.geomorph.2003.08.007. DOI URL
[36]	Klinger Y, Etchebes M, Tapponnier P, et al. 2011. Characteristic slip for five great earthquakes along the Fuyun fault in China[J]. Nature Geoscience, 4(6): 389-392. doi: 10.1038/NGEO1158. DOI
[37]	Lu L, Zhou Y, Zhang P, et al. 2022. Modelling fault scarp degradation to determine earthquake history on the Muztagh Ata and Tahman Faults in the Chinese Pamir[J]. Frontiers in Earth Science, 10: 838866. doi: 10.3389/feart.2022.838866. DOI URL
[38]	Martin Y. 2000. Modelling hillslope evolution: linear and nonlinear transport relations[J]. Geomorphology, 34(1-2): 1-21. doi: 10.1016/S0169-555X(99)00127-0. DOI URL
[39]	Mattson A, Bruhn R L. 2001. Fault slip rates and initiation age based on diffusion equation modeling: Wasatch Fault Zone and eastern Great Basin[J]. Journal of Geophysical Research: Solid Earth, 106(B7): 13739-13750. doi: 10.1029/2001JB900003. DOI
[40]	Mayer L. 1984. Dating Quaternary fault scarps formed in alluvium using morphologic parameters[J]. Quaternary Research, 22(3): 300-313. DOI URL
[41]	McCalpin J P. 2009. Paleoseismology(Second Edition)[M]. San Diego: Academic Press.
[42]	Nash D B. 1980. Morphologic dating of degraded normal fault scarps[J]. The Journal of Geology, 88(3): 353-360. DOI URL
[43]	Nash D B. 1984. Morphologic dating of fluvial terrace scarps and fault scarps near West Yellowstone, Montana[J]. Geological Society of America Bulletin, 95(12): 1413-1424. DOI URL
[44]	Nash D B. 2005. A general method for morphologic dating of hillslopes[J]. Geology, 33(8): 693-695. doi: 10.1130/G21479.1. DOI URL
[45]	Pelletier J D. 2008. Quantitative Modeling of Earth Surface Processes[M]. New York: Cambridge University Press.
[46]	Pelletier J D, Cline M L. 2007. Nonlinear slope-dependent sediment transport in cinder cone evolution[J]. Geology, 35(12): 1067-1070. doi: 10.1130/G23992A.1. DOI URL
[47]	Pelletier J D, DeLong S B, Al-Suwaidi A H, et al. 2006. Evolution of the Bonneville shoreline scarp in west-central Utah: Comparison of scarp-analysis methods and implications for the diffusion model of hillslope evolution[J]. Geomorphology, 74(1-4): 257-270. doi: 10.1016/j.geomorph.2005.08.008. DOI URL
[48]	Peltzer G, Brown N D, Mériaux A S B, et al. 2020. Stable rate of slip along the Karakax section of the Altyn Tagh Fault from observation of inter-glacial and post-glacial offset morphology and surface dating[J]. Journal of Geophysical Research: Solid Earth, 125(5): e2019JB018893. doi: 10.1029/2019JB018893. DOI
[49]	Perron J T. 2011. Numerical methods for nonlinear hillslope transport laws[J]. Journal of Geophysical Research: Earth Surface, 116(F2): F02021. doi: 10.1029/2010JF001801. DOI
[50]	Perry F V, Crowe B M, Valentine G A, et al. 1998. Volcanism Studies: Final Report for Yucca Mountain Project[R]. Los Alamos: Los Alamos National Laboratories.
[51]	Pierce K L, Colman S M. 1986. Effect of height and orientation(microclimate)on geomorphic degradation rates and processes, late-glacial terrace scarps in central Idaho[J]. Geological Society of America Bulletin, 97(7): 869-885. DOI URL
[52]	Roering J J, Gerber M. 2005. Fire and the evolution of steep, soil-mantled landscapes[J]. Geology, 33(5): 349-352. doi: 10.1130/G21260.1. DOI URL
[53]	Roering J J, Kirchner J W, Dietrich W E. 1999. Evidence for nonlinear, diffusive sediment transport on hillslopes and implications for landscape morphology[J]. Water Resources Research, 35(3): 853-870. doi: 10.1029/1998WR900090. DOI URL
[54]	Roering J J, Kirchner J W, Dietrich W E. 2001. Hillslope evolution by nonlinear, slope-dependent transport: Steady state morphology and equilibrium adjustment timescales[J]. Journal of Geophysical Research: Solid Earth, 106(B8): 16499-16513. doi: 10.1029/2001JB000323. DOI
[55]	Sare R, Hilley G E, DeLong S B. 2019. Regional-scale detection of fault scarps and other tectonic landforms: Examples from northern California[J]. Journal of Geophysical Research: Solid Earth, 124(1): 1016-1035. doi: 10.1029/2018JB016886. DOI URL
[56]	Schwanghart W, Scherler D. 2014. TopoToolbox 2-MATLAB-based software for topographic analysis and modeling in Earth surface sciences[J]. Earth Surface Dynamics, 2(1): 1-7. doi: 10.5194/esurf-2-1-2014. DOI URL
[57]	Simons D B, Albertson M L. 1960. Uniform water conveyance channels in alluvial material[J]. Journal of the Hydraulics Division, 68(5): 33-71.
[58]	Wallace R E. 1977. Profiles and ages of young fault scarps, north-central Nevada[J]. Geological Society of America Bulletin, 88(9): 1267-1281. DOI URL
[59]	Wallace R E. 1987. Variations in slip rates, migration, and grouping of slip events on faults in the Great Basin Province[J]. Bulletin of Seismological Society of America, 77(6B): 868-876.
[60]	Wei Z, Arrowsmith J R, He H. 2015. Evaluating fluvial terrace riser degradation using LiDAR-derived topography: An example from the northern Tian Shan, China[J]. Journal of Asian Earth Sciences, 105: 430-442. doi: 10.1016/j.jseaes.2015.02.016. DOI URL
[61]	Wei Z, He H, Su P, et al. 2019. Investigating paleoseismicity using fault scarp morphology of the Dushanzi Reverse Fault in the northern Tian Shan, China[J]. Geomorphology, 327: 542-553. doi: 10.1016/j.geomorph.2018.11.025. DOI URL
[62]	Witelski T P, Bowen M. 2003. ADI schemes for higher-order nonlinear diffusion equations[J]. Applied Numerical Mathematics, 45(2-3): 331-351. doi: 10.1016/S0168-9274(02)00194-0. DOI URL
[63]	Xu J, Arrowsmith J R, Chen J, et al. 2021. Evaluating young fluvial terrace riser degradation using a nonlinear transport model: Application to the Kongur Normal Fault in the Pamir, northwest China[J]. Earth Surface Processes and Landforms, 46(1): 280-295. doi: 10.1002/esp. 5022. DOI URL
[64]	Zielke O, Arrowsmith J R, Grant Ludwig L, et al. 2010. Slip in the 1857 and earlier large earthquakes along the Carrizo Plain, San Andreas Fault[J]. Science, 327(5969): 1119-1122. doi: 10.1126/science.1182781. DOI PMID
[65]	Zielke O, Klinger Y, Arrowsmith J R. 2015. Fault slip and earthquake recurrence along strike-slip faults: Contributions of high-resolution geomorphic data[J]. Tectonophysics, 638: 43-62. doi: 10.1016/j.tecto.2014.11.004. DOI URL