Predictability of hydrologic response at the plot and catchment scales: Role of initial conditions

[1] This paper examines the effect of uncertain initial soil moisture on hydrologic response at the plot scale (1 m2) and the catchment scale (3.6 km2) in the presence of threshold transitions between matrix and preferential flow. We adopt the concepts of microstates and macrostates from statistical mechanics. The microstates are the detailed patterns of initial soil moisture that are inherently unknown, while the macrostates are specified by the statistical distributions of initial soil moisture that can be derived from the measurements typically available in field experiments. We use a physically based model and ensure that it closely represents the processes in the Weiherbach catchment, Germany. We then use the model to generate hydrologic response to hypothetical irrigation events and rainfall events for multiple realizations of initial soil moisture microstates that are all consistent with the same macrostate. As the measures of uncertainty at the plot scale we use the coefficient of variation and the scaled range of simulated vertical bromide transport distances between realizations. At the catchment scale we use similar statistics derived from simulated flood peak discharges. The simulations indicate that at both scales the predictability depends on the average initial soil moisture state and is at a minimum around the soil moisture value where the transition from matrix to macropore flow occurs. The predictability increases with rainfall intensity. The predictability increases with scale with maximum absolute errors of 90 and 32% at the plot scale and the catchment scale, respectively. It is argued that even if we assume perfect knowledge on the processes, the level of detail with which one can measure the initial conditions along with the nonlinearity of the system will set limits to the repeatability of experiments and limits to the predictability of models at the plot and catchment scales.

[1]  Keith Beven,et al.  Effects of spatial variability and scale with implications to hydrologic modeling , 1988 .

[2]  Thomas A. McMahon,et al.  Physically based hydrologic modeling: 2. Is the concept realistic? , 1992 .

[3]  Mary P. Anderson,et al.  Simulation of Preferential Flow in Three-Dimensional, Heterogeneous Conductivity Fields with Realistic Internal Architecture , 1996 .

[4]  B. Lennartz,et al.  Time Variance Analysis of Preferential Solute Movement at a Tile-Drained Field Site , 1999 .

[5]  Chin-Fu Tsang,et al.  Tracer transport in a stochastic continuum model of fractured media , 1996 .

[6]  Günter Blöschl,et al.  Spatial Patterns of Catchment Hydrology: Observations and Modelling , 2000 .

[7]  J. Ihringer,et al.  Modeling water flow and mass transport in a loess catchment , 2001 .

[8]  Günter Blöschl,et al.  Spatial variability of soil moisture and its implications for scaling , 2003 .

[9]  G. SCALE ISSUES IN HYDROLOGICAL MODELLING : A REVIEW , 2006 .

[10]  T. Meixner Spatial Patterns in Catchment Hydrology , 2002 .

[11]  Bruno Merz,et al.  Effects of spatial variability on the rainfall runoff process in a small loess catchment , 1998 .

[12]  M. Vafakhah,et al.  Chaos theory in hydrology: important issues and interpretations , 2000 .

[13]  Andrew W. Western,et al.  The Tarrawarra Data Set: Soil moisture patterns, soil characteristics, and hydrological flux measurements , 1998 .

[14]  Markus Flury,et al.  Experimental evidence of transport of pesticides through field soils - a review , 1996 .

[15]  Erwin Zehe,et al.  Slope scale variation of flow patterns in soil profiles , 2001 .

[16]  Kurt Roth,et al.  Transport of conservative chemical through an unsaturated two‐dimensional Miller‐similar medium with steady state flow , 1996 .

[17]  Günter Blöschl,et al.  On the spatial scaling of soil moisture , 1999 .

[18]  Keith Beven,et al.  Uniqueness of place and process representations in hydrological modelling , 2000 .

[19]  Karsten H. Jensen,et al.  Flow and transport processes in a macroporous subsurface-drained glacial till soil I: Field investigations , 1998 .

[20]  Y. Mualem A New Model for Predicting the Hydraulic Conductivity , 1976 .

[21]  Rodger B. Grayson,et al.  Distributed parameter hydrologic modelling using vector elevation data: THALES and TAPES-C. , 1995 .

[22]  Hannes Flühler,et al.  SUSCEPTIBILITY OF SOILS TO PREFERENTIAL FLOW OF WATER : A FIELD STUDY , 1994 .

[23]  R. Grayson,et al.  Scaling of Soil Moisture: A Hydrologic Perspective , 2002 .

[24]  Erwin Zehe,et al.  Preferential transport of isoproturon at a plot scale and a field scale tile-drained site , 2001 .

[25]  K. Jensen,et al.  Flow and transport processes in a macroporous subsurface-drained glacial till soil II. Model analysis , 1998 .

[26]  Ludwig Boltzmann,et al.  Lectures on Gas Theory , 1964 .

[27]  Murugesu Sivapalan,et al.  ON THE REPRESENTATIVE ELEMENTARY AREA (REA) CONCEPT AND ITS UTILITY FOR DISTRIBUTED RAINFALL-RUNOFF MODELLING , 1995 .

[28]  Van Genuchten,et al.  A closed-form equation for predicting the hydraulic conductivity of unsaturated soils , 1980 .

[29]  G. Matheron,et al.  Is transport in porous media always diffusive? A counterexample , 1980 .

[30]  Eric F. Wood,et al.  An analysis of the effects of parameter uncertainty in deterministic hydrologic models , 1976 .

[31]  James C. I. Dooge,et al.  Looking for hydrologic laws , 1986 .

[32]  K. Beven,et al.  A physically based, variable contributing area model of basin hydrology , 1979 .

[33]  Regional Scales of Groundwater Quality Parameters and their Dependence on Geology and Land Use , 1996 .

[34]  Günter Blöschl,et al.  Preferred states in spatial soil moisture patterns: Local and nonlocal controls , 1997 .

[35]  P. Brooker Two-dimensional simulation by turning bands , 1985 .

[36]  Günter Blöschl,et al.  Scaling issues in snow hydrology , 1999 .

[37]  T. Meixner Spatial Patterns in Catchment Hydrology: Observations and Modelling , 2002 .

[38]  D. Russo,et al.  Stochastic analysis of solute transport in partially saturated heterogeneous soil: 2. Prediction of , 1994 .

[39]  R. Grayson,et al.  Toward capturing hydrologically significant connectivity in spatial patterns , 2001 .

[40]  Murugesu Sivapalan,et al.  Spatial Heterogeneity and Scale in the Infiltration Response of Catchments , 1986 .

[41]  Keith Beven,et al.  Changing ideas in hydrology — The case of physically-based models , 1989 .

[42]  D. Russo,et al.  Stochastic analysis of solute transport in partially saturated heterogeneous soil: 1. Numerical experiments , 1994 .

[43]  M. Celia,et al.  A General Mass-Conservative Numerical Solution for the Unsaturated Flow Equation , 1990 .

[44]  G. Weinberg An Introduction to General Systems Thinking , 1975 .

[45]  W. Durner,et al.  Modeling Transient Water and Solute Transport in a Biporous Soil , 1996 .

[46]  R. Tolman,et al.  The Principles of Statistical Mechanics. By R. C. Tolman. Pp. xix, 661. 40s. 1938. International series of monographs on physics. (Oxford) , 1939, The Mathematical Gazette.

[47]  James Gleick,et al.  Chaos, Making a New Science , 1987 .