INTRODUCTIONAppreciation of the imp

INTRODUCTION
Appreciation of the importance of fluid and particle motions to aquatic organisms
is a precept of limnology and biological oceanography. The incentives to
understand the details of these motions near sea, river, and lake beds, as well as
around particles settling through the water column, are growing steadily. The
recruitment of microbes and invertebrate larvae to surfaces of all kinds is
controlled or strongly modulated by boundary-layer flow dynamics (18, 21,
30). The fluxes of dissolved nutrients and wastes to and from attached algae
depend on the details of the flow regime (55, 134). The survival and growth of
suspension feeders hinge upon the near-bottom horizontal as well as vertical-flux
of particles; less obviously, the same is true of many kinds of deposit
feeders (80). The ability to track scents (60, 140) or detect vibrations (53, 91)
also depends upon the details of near-bed fluid motions. Furthermore, any
organism protruding above the bed must withstand forces whose magnitudes
and directions depend on the details of the local flow (131, 132).
The scales of these ecological phenomena range from that occupied by a
single individual to that inhabited by a small population. On the smaller end of
the scales we will treat, viscous flows predominate, and progress is being
made, for example, in studying the important details of the flow around feeding
appendages (2). On the larger end, there is a voluminous literature on geophysical
flows (98). It is especially difficult, however, to find literature relevant to
the intermediate scales and to extract those parts with strong ecological implications.
The need to do so is critical for both designing and interpreting
manipulative laboratory and field experiments-including those with microbes-which
are largely conducted on an intermediate scale.