Cd. Matthaei et al., Patchy surface stone movement during disturbance in a New Zealand stream and its potential significance for the fauna, LIMN OCEAN, 44(4), 1999, pp. 1091-1102
A patchy movement of surface stones during disturbance in streams has been
proposed from held observations, but few attempts have been made to quantif
y this phenomenon. If spates produce a mosaic of stable and disturbed areas
, the former could serve as refugia for benthic invertebrates. We monitored
the stability of surface stones at three geomorphically contrasting sites
in a river with an unstable bed during three spates and one large flood. St
ones were marked in situ by drilling holes in them or by scraping them with
a chisel. For each stone, we determined visible surface area, embeddedness
in the substratum, water depth, size of surrounding stones, and presence o
r absence of large stones upstream. During the first monitoring period, whi
ch covered one spate and the large flood, we marked 400 stones at each 20-m
-long site in a systematic grid with 40 to 60 cm between stones. Stones wer
e relocated after each disturbance, but each stone set was used to monitor
both subsequent events. After the large flood, few marked stones were left.
Therefore, additional sets of 200 stones were marked for a second monitori
ng period covering the remaining two spates; these stones were located at t
he same sites, but the distance between transects was doubled. Patchy bed m
ovement occurred during all four disturbances, especially during the three
smaller ones, which moved only 33 to 72% of marked stones. Stability of ind
ividual stones was mainly influenced by their size and embeddedness and som
etimes by the water depth above the stone. Larger-scale parameters (e.g., t
he position of the stone across the transect) were less important. Whole-si
te stability differed little among sites. During the three smaller events,
many stable surface stones were available as potential invertebrate refugia
. In contrast, invertebrate refugia may have been restricted to the hyporhe
ic zone and inundated hood-plain gravels during the large flood. Because pa
tchy stone movement was observed in a river with an unstable bed, it is lik
ely to be a feature of most rivers. Therefore, small-scale experiments may
be able to simulate the effects of disturbance on the benthic community mor
e effectively than previously thought.