Transience and persistence in the depositional record of continental margins

[1] Continental shelves and coastal plains are large persistent depositional landforms, which are stationary (nonmigrating) at their proximal ends and characterized by relatively steady long-term growth. In detail, however, their surface form and stratigraphic record is built of transient freely migrating landscape elements. We derive the timescales of crossover from transient to persistent topographic forms using empirical scaling relations for mean sediment accumulation as a function of averaging time, based upon tens of thousands of empirical measurements. A stochastic (noisy) diffusion model with drift predicts all the gross features of the empirical data. It satisfies first-order goals of describing both the surface morphology and stratigraphic completeness of depositional systems. The model crossover from noise-dominated to drift-dominated behavior corresponds to the empirical crossover from transport-dominated (autogenic) transient behavior to accommodation-dominated (subsidence) persistent behavior, which begins at timescales of 102–103 years and is complete by scales of 104–105 years. Because the same long-term scaling behavior emerges for off-shelf environments, it is not entirely explicable by steady subsidence. Fluctuations in sediment supply and routing probably have significant influence. At short-term (transient) scales, the exponents of the scaling relations vary with environment, particularly the prevalence of channeled sediment transport. At very small scales, modeling sediment transport as a diffusive process is inappropriate. Our results indicate that some of the timescales of interest for climate interpretation may fall within the transitional interval where neither accommodation nor transport processes are negligible and deconvolution is most challenging.

[1]  V. Voller,et al.  Shoreline response to autogenic processes of sediment storage and release in the fluvial system , 2006 .

[2]  C. Paola,et al.  Experimental Test of Tectonic Controls on Three-Dimensional Alluvial Facies Architecture , 2005 .

[3]  W. Lyons Quantifying channelized submarine depositional systems from bed to basin scale , 2004 .

[4]  W. Schlager Fractal nature of stratigraphic sequences , 2004 .

[5]  P. Cowie,et al.  Basin‐Floor Topography and the Scaling of Turbidites , 2003, The Journal of Geology.

[6]  C. Wunsch,et al.  A Depth-Derived Pleistocene Age-Model: Uncertainty Estimates, Sedimentation Variability, and Nonlinear Climate Change , 2002 .

[7]  Tao Sun,et al.  Fluvial fan deltas: Linking channel processes with large‐scale morphodynamics , 2002 .

[8]  G. Molchan,et al.  A stochastic model of sedimentation: probabilities and multifractality , 2002, European Journal of Applied Mathematics.

[9]  H. Sheets,et al.  Uncorrelated change produces the apparent dependence of evolutionary rate on interval , 2001, Paleobiology.

[10]  V. Voller,et al.  A two‐diffusion model of fluvial stratigraphy in closed depositional basins , 2000 .

[11]  Peter Sheridan Dodds,et al.  Scaling, Universality, and Geomorphology , 2000 .

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

[13]  D. Turcotte,et al.  Synthetic Stratigraphy with a Stochastic Diffusion Model of Fluvial Sedimentation , 1997 .

[14]  A. Deshpande,et al.  Quantifying lateral heterogeneities in fluvio‐deltaic sediments using three‐dimensional reflection seismic data: Offshore Gulf of Mexico , 1997 .

[15]  D. Swift,et al.  Modeling shore-normal large-scale coastal evolution , 1995 .

[16]  C. Paola,et al.  A cellular model of braided rivers , 1994, Nature.

[17]  P. Sadler The expected duration of upward-shallowing peritidal carbonate cycles and their terminal hiatuses , 1994 .

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

[19]  L. Borgman,et al.  Reconstructing random topography from preserved stratification , 1991 .

[20]  A. R. Nowell,et al.  Prologue: Abyssal storms as a global geologic process , 1991 .

[21]  D. J. Strauss,et al.  Estimation of completeness of stratigraphical sections using empirical data and theoretical models , 1990, Journal of the Geological Society.

[22]  C. Shuman,et al.  Geomorphic and tectonic process rates: Effects of measured time interval , 1987 .

[23]  R. Plotnick A Fractal Model for the Distribution of Stratigraphic Hiatuses , 1986, The Journal of Geology.

[24]  P. Gingerich Rates of Evolution: Effects of Time and Temporal Scaling , 1983, Science.

[25]  J. C. Tipper Rates of sedimentation, and stratigraphical completeness , 1983, Nature.

[26]  Bernard C. Kenney,et al.  Beware of spurious self‐correlations! , 1982 .

[27]  S. Edwards,et al.  The surface statistics of a granular aggregate , 1982, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[28]  P. Sadler Sediment Accumulation Rates and the Completeness of Stratigraphic Sections , 1981, The Journal of Geology.

[29]  H. Reineck Über Zeitlücken in Rezenten Flachsee-Sedimenten , 1960 .

[30]  J. Gilluly Distribution of mountain building in geologic time , 1949 .

[31]  R. Bailey,et al.  Quantitative evidence for the fractal nature of the stratigraphie record: results and implications , 2005 .

[32]  P. Sadler The Influence of Hiatuses on Sediment Accumulation Rates , 1999 .

[33]  A. Barabasi,et al.  Fractal Concepts in Surface Growth: Frontmatter , 1995 .

[34]  H. Olson,et al.  Time Scale Dependence of the Rates of Unsteady Geologic Processes , 1993 .

[35]  Gabor Korvin,et al.  Fractal models in the earth sciences , 1992 .

[36]  D. J. Strauss,et al.  Stochastic models for the completeness of stratigraphic sections , 1989 .