Nowell, A. R. M. & Church, M. (1979). Turbulent
flow in a depth-limited boundary layer.
Journal of Geophysical Research, 84 , 4816–4824.
Nowell, A. R. M. & Jumars, P. A. (1984). Flow
environments of aquatic benthos.Annual
Review of Ecology and Systematics, 15 , 303–328.
Okamura, B. (1984). The effects of ambient flow
velocity, colony size, and upstream colonies
on the feeding success of bryozoa: I.Bugula
stolonifera(Ryland), an arborescent species.
Journal of Experimental Marine Biology and
Ecology, 83 , 179–193.
Okamura, B. (1985). The effects of ambient flow
velocity, colony size, and upstream colonies
on the feeding success of bryozoa: II.
Conopeum reticulum(Linnaeus), an encrusting
species.Journal of Experimental Marine Biology
and Ecology, 89 , 69–80.
Okamura, B. (1988). The influence of neighbors
on the feeding of an epifaunal bryozoan.
Journal of Experimental Marine Biology and
Ecology, 120 , 105–123.
Okamura, B., Harmelin, J.-G. & Jackson, J.B. C.
(2001). Refuges revisited: enemies versus
flow and feeding as determinants of sessile
animal distribution and form. InEvolutionary
Patterns: Growth, Form, and Tempo in the Fossil
Record, ed. J. B.C. Jackson, S. Lidgard &
F. K. McKinney. Chicago: University of
Chicago Press, pp. 61–93.
Palumbi, S. R. (1986). How body plans limit
acclimation: responses of a Demosponge to
wave force.Ecology, 67 , 208–214.
Pawlik, J. R., Butman, C.A. & Starczak, V.R.
(1991). Hydrodynamic facilitation of
gregarious settlement of a reef-building
tube worm.Science, 251 , 421–424.
Peters, R.H. (1983).The Ecological Implications of Body
Size. Cambridge: Cambridge University Press.
Petersen, R. C.J., Petersen, B.M. & Wallace, J.B.
(1984). Influence of velocity and food
availability on catchnet dimensions of
Neureclipsis bimaculata(Trichoptera:
Polycentropodidae).Holarctic Ecology, 7 ,
380–389.
Pratt, M. C. (2004). Effect of zooid spacing on
bryozoan feeding success: is competition or
facilitation more important?Biological
Bulletin, 207 , 17–27.
Rex, A., Montebon, F. & Yap, H.T. (1995).
Metabolic responses of the scleractinian
coralPorites cylindricaDana to water
motion. I. Oxygen flux studies.Journal of
Experimental Marine Biology and Ecology, 186 ,
33–52.
Rubenstein, D. I. & Koehl, M. A. R. (1977). The
mechanisms of filter feeding: some
theoretical considerations.American
Naturalist, 111 , 981–994.
Ruppert, E. E. & Barnes, R. D. (1994).Invertebrate
Zoology. Fort Worth: Saunders College
Publishing.
Schmidt-Nielsen, K. (1984).Scaling: Why is Animal
Size so Important?Cambridge: Cambridge
University Press.
Sebens, K. P. (1982). The limits to indeterminate
growth: an optimal size model applied to
passive suspension feeders.Ecology, 63 ,
209–222.
Sebens, K.P. (1987). The ecology of indeterminate
growth in animals.Annual Review of Ecology
and Systematics, 18 , 371–407.
Shimeta, J. & Jumars, P. A. (1991). Physical
mechanisms and rates of particle capture by
suspension feeders.Oceanography and Marine
Biology Annual Review, 29 , 191–257.
Shimeta, J. & Koehl, M. A. R. (1997). Mechanisms of
particle selection by tentaculate suspension
feeders during encounter, retention, and
handling.Journal of Experimental Marine Biology
and Ecology, 209 , 47–73.
Silvester, N.R. (1983). Some hydrodynamic aspects
of filter feeding with rectangular-mesh nets.
Journal of Theoretical Biology, 103 , 265–286.
Turner, J. S. (2000).The Extended Organism: the
Physiology of Animal-Built Structures.
Cambridge, MA: Harvard University Press.
Vanderploeg, H.A. (1994). Zooplankton particle
selection and feeding mechanisms. InThe
Biology of Particles in Aquatic Systems, ed.BODY SIZE AND SUSPENSION FEEDING 31