IntroductionClearly defined hydrologic response units (HRUs) that incorporate unifying concepts in hydrology-the complete hydrologic cycle and conservation of mass (Dooge, 1986)-are required to direct and integrate local, regional and continental scales of hydrologic research and management. The topographically defined watershed or catchment has been championed as the basic HRU (Dooge, 1968). However, catchment studies reveal large complexity and heterogeneity of runoff behaviour, resulting in a multitude of conceptual and numerical model structures. Recent reviews argue that a broad-scale classification of catchments is required to generalize dominant hydrologic processes, direct field methodologies, and apply hydrologic model structure (Sivapalan, 2003; McDonnell and Woods, 2004). However, protocols on defining such areas are presently lacking.Traditionally, researchers have disregarded large portions of the landscape in favour of areas amenable to 'hydrologic study', by relying on catchments where hydrologic boundaries can be easily defined. These catchments are often small and homogeneous, to 'control' for climatic and geologic features, which may have misled non-catchment-hydrologists (or up-and-coming hydrologists and managers) to believe that the first variable to consider in predicting hydrologic response is topography. This approach may provide a false sense of security about the effectiveness of topographically defined catchments as an approach to conduct research, assess regional hydrology, and generalize results to broad landscape scales. Recent reviews clearly illustrate the need for a thorough integration of surface water and groundwater processes (Winter, with respect to dominant hydrologic cycling and mass balance. We believe that asserting the topographically defined catchment as a standard hydrologic unit, or by assuming that the water table conforms to topography, is a methodological approach that has been overstated in importance for regional to national scales of water management.2001a
Effective Delineation of a Catchment Using Dominant HRUs: a Boreal Plain ExampleThe impetus for this commentary comes from an interest in understanding hydrology on the subhumid glaciated plains of the western Boreal Forest, and our realization that traditional approaches for hydrologic research may actually serve to limit insights into hydrologic function in this region. Ongoing research at our Utikuma Research Study Area (URSA), Alberta, Canada, reveals that glaciated regions, such as the Boreal Plain, with deep glaciated substrates arguably result in some of the most complex surface and groundwater interactions (e.g. Winter, 1999Winter, , 2001a The difference in a hydrologist's perception of the effective catchment area determined by first considering topography, rather than climate and geology, is illustrated in the example in Figure 1 (Mink Lake, Alberta). From the data provided and the scale of the example, similar runoff contribution per unit area would often be assumed, and the hydrologic response time...
