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- . ~. I\~<'no I"~ ~j .'. r: ~ RESTORATION OF REGULATED RIVERS 403 " the reservoir, the mechanics of water release (surface, bottom or depth selective), the mode of dam operations and the influence of tributaries entering downstream from the dam. If the tributaries are large and unregulated, they may substantially mediate the reset (Stanford and Hauer, 1992). In any case, conditions at some point downstream from the dam will closely approximate conditions elsewhere in the continuum. Thus, upstream or downstream shifts in biophysical conditions mediated by dams manifest as predictable discontinuities in the river continuum. For example, biophysical conditions at some predictable point downstream from a large bottom release (hypolimnial) dam in the montane transition of a temperate latitude river will be very similar to pristine conditions far upstream, because of the cool, clear water released from the reservior, In rivers that are free flowing for long distances downstream from large dams in the montane reaches, the position of the rhithron-potomon transition can be predicted from the operational mode of the dams relative to the influence of tributaries. The predictions of the SDC along the longitudinal dimension have been largely substantiated (Stanford el ai" 1988; Ward and Voelz, 1988; Hauer el aI., 1989; Stanford and Ward, 1989; Ward and Stanford, 1990, 199\; Munn and Brusven, 199\; Sabater et al., in press), although recent incorporation of responses of large floodplains (Ward and Stanford, 1995b) require additional resolution, The main point is that the ecological consequences of specific regulation schemes are largely predictable, and environmental degradation asso- ciated with regulation can be ameliorated. We recognize that uncertainties derive from interactions with pol- lution and the introduction of exotic biota. However, pollution can be curtailed or eliminated, and non- native biota are likely to be substantially less successful as invaders when dams are operated in ways that maximize resets of environmental heterogeneity. .,.... .;.,,:.:. ..:...\ .:;~~:'.(~::..(~;.: :-:"...<:?'(r:.; ..':. :.>.;.~..:. '.. 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RESTORA nON PROTOCOL .........;....... .... ~~i:i;~~<1~ The era of dam building may be over in much of the world because high efficiency and affordable dam sites are already developed, Loss of biodiversity and bioproduction', especially riverine and anadromous fisheries (Frissel1, 1993; We1comme 1995), underscores the need for restoration of regulated rivers and enormously expensive reconstructions are underway or are being planned (Dahm el ai" 1995; Gore and Shields, 1995), Even removal of large dams on large rivers is included in some restoration plans because the costs of damage to fisheries and other attributes of riverine integrity in some instances far exceed the commercial value of the dams, Removal of large dams is obviously problematic in a variety of ways, such as the'mobi- lization of large volumes of fine sediments stored in the reservoir basin, and methods for evaluating removal strategies have been proposed (Shuman, 1995), A variety of approaches exist for restoring small streams with substantial emphasis on engineered structures such as weirs, off-channel ponds, rock gardens (Gore and Shields, 1995) and many other artificial habitat structures (Hunter, 1991). Commercial operations advertise engineering expertise for bulldozing damaged streams back to pre-regulation channel configurations and stories of restored fisheries and improved water quality abound in the popular literature, although scientific, long-term evaluations of such schemes are much less available (Sear, 1994)"Structures placed instream are often washed out, fail to restore biodiversity or produce unanticipated negative responses, such as increased bank erosion or accelerated deposition of fine sediments (Frissell and Nawa, 1992) and increased water tem- peratures (c. Frissell, unpublished data) associated with weirs and rock gardens, Such problems largely derive from lack of attention to the conceptual foundations of river ecology and the first principles of the ecology of regulated streams. -.; .~-. -:" :...... .....-.:.-.. .. '.:,'..: ::.:;~..~. ?!.\~.:<~:: :.:-:>.,... .' ::...~:(.~;><.) ;::~.<;~::::::.:.;: ~~~:;.;~: . . -;,. ;:....;..: :~. ":. Formalize the problem at catchmenl scale Restoration of large, regulated rivers begins with recognition of the river continuum and evaluation of the loss of ecosystem capacity to sustain biodiversity and bioproduction, Biological (e,g. past and present distribution of native biota) and physical (e,g, channel configuration) indices of ecosystem resilience are needed (Frissell el ai" 1993); measures of biological integrity as defined by Angermeier and Karr (1994) may be more useful than biodiversity per se because of the difficulty of accurately determining the distri- bution and abundance of benthos, fish and other river organisms, Habitat requirements for all life history stages and generation times (turnover rates) of native, keystone species (i.e" top carnivores and other ...... ".'. '" .'.; ',' :..1 0,' "'-F .' .. -.. :... .;~. .... .r".. .,.., . .... -'