Time scales of tectonic landscapes and their sediment routing systems

Abstract In regions undergoing active tectonics, the coupling between the tectonic displacement field, the overlying landscape and the redistribution of mass at the Earth's surface in the form of sediment routing systems, is particularly marked and variable. Coupling between deformation and surface processes takes place at a range of scales, from the whole orogen to individual extensional fault blocks or contractional anticlines. At the large scale, the attainment of a steady-state between the overlying topography and the prevailing tectonic conditions in active contractional orogens requires an efficient erosional system, with a time scale dependent on the vigour of the erosional system, generally in the range 106–107 years. The catchment–fan systems associated with extensional fault blocks and basins of the western USA are valuable natural examples to study the coupling between tectonic deformation, landscape and sediment routing systems. Even relatively simple coupled systems such as an extensional fault block and its associated basin margin fans have a range of time scales in response to a tectonic perturbation. These response times originate from the development of uniform (steady-state) relief during the accumulation of displacement on a normal fault (c. 106 years), the upstream propagation of a bedrock knickpoint in transverse catchments following a change in tectonic uplift rate (c. 106 years), or the relaxation times of the integrated catchment–fan system in response to changes in climatic and tectonic boundary conditions (105–106 years). The presence of extensive bedrock or alluvial piedmonts increases response times significantly. The sediment efflux of a mountain catchment is a boundary condition for far-field fluvial transport, but the fluvial system is much more than a simple transmitter of the sediment supply signal to a neighbouring depocentre. Fluvial systems appear to act as buffers to incoming sediment supply signals, with a diffusive time scale (c. 105–106 years) dependent on the length of the system and the extent of its floodplains, stream channels and proximal gravel fans. The vocabulary for explaining landscapes would benefit from a greater recognition of the importance of the repeat time and magnitude of perturbations in relation to the response and relaxation times of the landscape and its sediment routing systems. Landscapes are best differentiated as ‘buffered’ or ‘reactive’ depending on the ratio of the response time to the repeat time of the perturbation. Furthermore, landscapes may be regarded as ‘steady’ or ‘transient’ depending on the ratio of the response time to the time elapsed since the most recent change in boundary conditions. The response of tectonically and climatically perturbed landscapes has profound implications for the interpretation of stratigraphic architecture.

[1]  G. Simpson Dynamic interactions between erosion, deposition, and three‐dimensional deformation in compressional fold belt settings , 2004 .

[2]  P. Allen,et al.  Sediment flux from a mountain belt derived by landslide mapping , 1997 .

[3]  F. Schlunegger,et al.  Topographic evolution and morphology of surfaces evolving in response to coupled fluvial and hillslope sediment transport , 2003 .

[4]  C. Paola,et al.  Grain Size Patchiness as a Cause of Selective Deposition and Downstream Fining , 1995 .

[5]  Nicholas Brozovic,et al.  Bedrock incision, rock uplift and threshold hillslopes in the northwestern Himalayas , 1996, Nature.

[6]  William W. Doe,et al.  Landscape erosion and evolution modeling , 2001 .

[7]  G. Fraser,et al.  Geomorphic controls on sediment accumulation at margins of foreland basins , 1992 .

[8]  H. Kooi,et al.  Large‐scale geomorphology: Classical concepts reconciled and integrated with contemporary ideas via a surface processes model , 1996 .

[9]  K. Hodges,et al.  Active out-of-sequence thrust faulting in the central Nepalese Himalaya , 2005, Nature.

[10]  F. Bretherton,et al.  Stability and the conservation of mass in drainage basin evolution , 1972 .

[11]  Kelin X. Whipple,et al.  Topographic outcomes predicted by stream erosion models: Sensitivity analysis and intermodel comparison , 2002 .

[12]  G. Tucker,et al.  Implications of the shear stress river incision model for the timescale of postorogenic decay of topography , 2003 .

[13]  C. Beaumont,et al.  Mechanical model for subduction-collision tectonics of Alpine-type compressional orogens , 1996 .

[14]  D. Craw,et al.  Mechanical links between erosion and metamorphism in Nanga Parbat , 2002 .

[15]  D. Burbank Causes of recent Himalayan uplift deduced from deposited patterns in the Ganges basin , 1992, Nature.

[16]  Pinxian Wang,et al.  Continent-Ocean Interactions Within East Asian Marginal Seas , 2004 .

[17]  Philip Allen,et al.  Striking a chord , 2005, Nature.

[18]  Peter B. Flemings,et al.  A synthetic stratigraphic model of foreland basin development , 1989 .

[19]  P. Pinet,et al.  Continental erosion and large‐scale relief , 1988 .

[20]  P. Allen,et al.  Vertical versus horizontal motions in the Alpine orogenic wedge: stratigraphic response in the foreland basin , 1992 .

[21]  J. Underhill,et al.  The propagation and linkage of normal faults: insights from the Strathspey–Brent–Statfjord fault array, northern North Sea , 2000 .

[22]  C. Denny Alluvial fans in the Death Valley region, California and Nevada , 1965 .

[23]  William E. Dietrich,et al.  Modeling fluvial erosion on regional to continental scales , 1994 .

[24]  W. Dade,et al.  Grain‐Size, Sediment‐Transport Regime, and Channel Slope in Alluvial Rivers , 1998, The Journal of Geology.

[25]  Métivier,et al.  Stability of output fluxes of large rivers in South and East Asia during the last 2 million years: implications on floodplain processes , 1999 .

[26]  G. Tucker,et al.  Dynamics of the stream‐power river incision model: Implications for height limits of mountain ranges, landscape response timescales, and research needs , 1999 .

[27]  M. Summerfield Tectonic geomorphology , 1991 .

[28]  Robert S. Anderson,et al.  Evolution of the Santa Cruz Mountains, California, through tectonic growth and geomorphic decay , 1994 .

[29]  Patience A. Cowie,et al.  Displacement-length scaling relationship for faults: data synthesis and discussion , 1992 .

[30]  F. Schlunegger,et al.  Messinian climate change and erosional destruction of the central European Alps , 2006 .

[31]  Peizhen Zhang,et al.  Increased sedimentation rates and grain sizes 2–4 Myr ago due to the influence of climate change on erosion rates , 2001, Nature.

[32]  Michael A. Ellis,et al.  Landsliding and the evolution of normal‐fault‐bounded mountains , 1998 .

[33]  C. Scholz,et al.  Growth of normal faults: Displacement-length scaling , 1993 .

[34]  P. Allen,et al.  Basin Analysis: Principles and Applications , 1990 .

[35]  J. Underhill,et al.  A mechanism to explain rift-basin subsidence and stratigraphic patterns through fault-array evolution , 1998 .

[36]  C. Morley Patterns of Displacement Along Large Normal Faults: Implications for Basin Evolution and Fault Propagation, Based on Examples from East Africa , 1999 .

[37]  R. Gawthorpe,et al.  Normal fault growth, displacement localisation and the evolution of normal fault populations: the Hammam Faraun fault block, Suez rift, Egypt , 2003 .

[38]  C. Paola Quantitative models of sedimentary basin filling , 2000 .

[39]  Ralf Hetzel,et al.  Slip rate variations on normal faults during glacial–interglacial changes in surface loads , 2005, Nature.

[40]  Patience A. Cowie,et al.  A healing–reloading feedback control on the growth rate of seismogenic faults , 1998 .

[41]  A. Densmore,et al.  What sets topographic relief in extensional footwalls , 2005 .

[42]  P. Heller,et al.  Evaluating major controls on basinal stratigraphy, Pine Valley, Nevada: Implications for syntectonic deposition , 1993 .

[43]  Patience A. Cowie,et al.  Implications of fault array evolution for synrift depocentre development: insights from a numerical fault growth model , 2000 .

[44]  K. Whipple,et al.  Tectonic control of fan size: the importance of spatially variable subsidence rates , 1996 .

[45]  Michel Klein,et al.  MASS ACCUMULATION RATES IN ASIA DURING THE CENOZOIC , 2002 .

[46]  D. Montgomery Slope Distributions, Threshold Hillslopes, and Steady-state Topography , 2001 .

[47]  J. Hutchinson,et al.  Hillslope Form and Process , 1973 .

[48]  G. Simpson Role of river incision in enhancing deformation , 2004 .

[49]  G. Tucker,et al.  Importance of a stochastic distribution of floods and erosion thresholds in the bedrock river incision problem , 2003 .

[50]  H. Kooi,et al.  Coupled tectonic-surface process models with applications to rifted margins and collisional orogens. , 2000 .

[51]  K. Whipple,et al.  Alluvial Fans Formed by Channelized Fluvial and Sheet Flow. I: Theory , 1998 .

[52]  C. Paola,et al.  The large-scale dynamics of grain-size variation in alluvial basins, 2: Application to syntectonic conglomerate , 1992 .

[53]  G. Parker Self-formed straight rivers with equilibrium banks and mobile bed. Part 1. The sand-silt river , 1978, Journal of Fluid Mechanics.

[54]  F. Fournier Climat et érosion : la relation entre l'érosion du sol par l'eau et les précipitations atmosphériques , 1960 .

[55]  G. Tucker,et al.  Landscape response to tectonic forcing: Digital elevation model analysis of stream profiles in the Mendocino triple junction region, northern California , 2000 .

[56]  W. Bull,et al.  The alluvial-fan environment , 1977 .

[57]  Andrew J. Pearce,et al.  Effects of earthquake-induced landslides on sediment budget and transport over a 50-yr period , 1986 .

[58]  Rolf V. Ackermann,et al.  Geometry and scaling relations of a population of very small rift-related normal faults , 1996 .

[59]  W. M. Rohrer,et al.  Relative erodibility of source-area rock types, as determined from second-order variations in alluvial-fan size , 1977 .

[60]  Irantzu Lexartza Artza,et al.  Knickpoint recession rate and catchment area: the case of uplifted rivers in Eastern Scotland , 2005 .

[61]  David R. Montgomery,et al.  Geologic constraints on bedrock river incision using the stream power law , 1999 .

[62]  Álvarez Drainage on evolving fold‐thrust belts: a study of transverse canyons in the Apennines , 1999 .

[63]  J. T. Hack Studies of longitudinal stream profiles in Virginia and Maryland , 1957 .

[64]  P. Allen,et al.  Sediment flux from an uplifting fault block , 2000 .

[65]  Sean D. Willett,et al.  Orogeny and orography: The effects of erosion on the structure of mountain belts , 1999 .

[66]  D. Montgomery,et al.  Limits to Relief , 1995, Science.

[67]  William E. Dietrich,et al.  Evidence for nonlinear, diffusive sediment transport on hillslopes and implications for landscape morphology , 1999 .

[68]  Robert S. Anderson,et al.  Hillslope and channel evolution in a marine terraced landscape , 1994 .

[69]  Anderson,et al.  Development of mountainous topography in the Basin Ranges, USA , 1999 .

[70]  E. Leonard Geomorphic and tectonic forcing of late Cenozoic warping of the Colorado piedmont , 2002 .

[71]  David R. Montgomery,et al.  Valley incision and the uplift of mountain peaks , 1994 .

[72]  G. Roberts,et al.  Constraining slip rates and spacings for active normal faults , 2001 .

[73]  S. Castelltort,et al.  How plausible are high-frequency sediment supply driven-cycles in the stratigraphic record ? , 2003 .

[74]  Wolfgang Kuhnt,et al.  Continent-ocean interactions within the East Asian Marginal seas , 2003 .

[75]  Alan D. Howard,et al.  Channel changes in badlands , 1983 .

[76]  P. Allen,et al.  Sediment supply from landslide‐dominated catchments: implications for basin‐margin fans , 1998 .

[77]  G. Parker Self-formed straight rivers with equilibrium banks and mobile bed. Part 2. The gravel river , 1978, Journal of Fluid Mechanics.

[78]  P. Allen,et al.  Timing and patterns of debris flow deposition on Shepherd and Symmes creek fans, Owens Valley, California, deduced from cosmogenic 10Be , 2007 .

[79]  William E. Dietrich,et al.  Hillslope evolution by diffusive processes: The timescale for equilibrium adjustments , 1997 .

[80]  P. Allen,et al.  Simulation of Foreland Basin Stratigraphy using a diffusion model of mountain belt uplift and erosion: An example from the central Alps, Switzerland , 1991 .

[81]  F. Ahnert,et al.  Local relief and the height limits of mountain ranges , 1984 .

[82]  J. Pelletier The influence of piedmont deposition on the time scale of mountain‐belt denudation , 2004 .

[83]  C. Paola,et al.  The large scale dynamics of grain-size variation in alluvial basins , 1992 .

[84]  Paul L. Heller,et al.  Natural oscillations in coupled geomorphic systems: An alternative origin for cyclic sedimentation , 1995 .

[85]  F. Ahnert Functional relationships between denudation, relief, and uplift in large, mid-latitude drainage basins , 1970 .

[86]  Sean D. Willett,et al.  Mechanical model for the tectonics of doubly vergent compressional orogens , 1993 .

[87]  Gregory E. Tucker,et al.  Predicting sediment flux from fold and thrust belts , 1996 .

[88]  J. Driessche,et al.  Influence of piedmont sedimentation on erosion dynamics of an uplifting landscape: An experimental approach , 2005 .

[89]  P. Allen,et al.  Development and response of a coupled catchment fan system under changing tectonic and climatic forcing , 2007 .

[90]  A. Densmore,et al.  Footwall topographic development during continental extension , 2004 .

[91]  M. Sambridge,et al.  Modelling landscape evolution on geological time scales: a new method based on irregular spatial discretization , 1997 .

[92]  Greg . Smith,et al.  The Gravel-Sand Transition Along River Channels , 1995 .

[93]  C. Beaumont,et al.  Preliminary Results from a Planform Kinematic Model of Orogen Evolution, Surface Processes and the Development of Clastic Foreland Basin Stratigraphy , 1995 .

[94]  M. Summerfield,et al.  Natural controls of fluvial denudation rates in major world drainage basins , 1994 .

[95]  William E. Dietrich,et al.  The Problem of Channel Erosion into Bedrock , 1992 .

[96]  H. Kooi,et al.  Escarpment evolution on high‐elevation rifted margins: Insights derived from a surface processes model that combines diffusion, advection, and reaction , 1994 .

[97]  N. Hovius,et al.  Large-scale erosion rates from in situ-produced cosmogenic nuclides in European river sediments , 2001 .

[98]  R. Hooke Steady-state relationships on arid-region alluvial fans in closed basins , 1968 .

[99]  P. Molnar,et al.  Late Cenozoic uplift of mountain ranges and global climate change: chicken or egg? , 1990, Nature.

[100]  F. Fournier Climat et Erosion , 1961 .

[101]  S. Willett Dynamic and kinematic growth and change of a Coulomb wedge , 1992 .

[102]  B. Meade,et al.  Controls on the strength of coupling among climate, erosion, and deformation in two-sided, frictional orogenic wedges at steady state , 2004 .

[103]  A. Nicol,et al.  Progressive localisation of strain during the evolution of a normal fault population , 2002 .

[104]  Nicole M. Gasparini,et al.  The Channel-Hillslope Integrated Landscape Development Model (CHILD) , 2001 .

[105]  S. Willett,et al.  On steady states in mountain belts , 2002 .

[106]  J. Underhill,et al.  The Role of Fault Interaction and Linkage in Controlling Synrift Stratigraphic Sequences: Late Jurassic, Statfjord East Area, Northern North Sea , 2000 .

[107]  James W. Kirchner,et al.  Spatially Averaged Long-Term Erosion Rates Measured from in Situ-Produced Cosmogenic Nuclides in Alluvial Sediment , 1996, The Journal of Geology.

[108]  W. Bull Geomorphology of segmented alluvial fans in western Fresno County, California , 1964 .

[109]  R. Stallard,et al.  Denudation rates determined from the accumulation of in situ-produced 10Be in the luquillo experimental forest, Puerto Rico , 1995 .

[110]  P. Allen,et al.  Transient landscapes at fault tips , 2007 .

[111]  F. Schlunegger,et al.  Messinian climate change and erosional destruction of the central European Alps: COMMENT AND REPLY REPLY , 2007 .

[112]  K. Whipple FLUVIAL LANDSCAPE RESPONSE TIME: HOW PLAUSIBLE IS STEADY-STATE DENUDATION? , 2001 .

[113]  P. O. Koons,et al.  The topographic evolution of collisional mountain belts; a numerical look at the Southern Alps, New Zealand , 1989 .