34. Dyer, K.R. and Manning, A.J., Observation of the size, settling velocity and effective density of flocs, and their fractal dimensions, Journal of Sea Research 41(1-2), 87-95, 1999.

35. Kranck, K. and Milligan, T.G., Characteristics of suspended particles at an 11-hour anchor station in San Francisco Bay, California, Journal of Geophysical Research 97(C7), 11373-11382, 1992.

36. Fugate, D.C. and Friedrichs, C.T., Controls on suspended aggregate size in partially mixed estuaries, Estuarine Coastal and ShelfScience 58(2), 389-404, 2003.

37. Cronin, W.B., Volumetric, Areal, and Tidal Statistics of the Chesapeake Bay Estuary and Its Tributaries, The Chesapeake Bay Institute of the Johns Hopkins University, Baltimore, MD, 1971.

38. Browne, D.R. and Fisher, C.W., Tide andTidal Currents in the Chesapeake Bay NOAA, Rockville, MD, 1988.

39. Elliott, A.J., Wang, D.P., and Pritchard, D.W., The circulation near the head of Chesapeake Bay, 36(4), 643-655, 1978.

40. North, E.W., Chao, S.-Y., Sanford, L.P., and Hood, R.R., The Influence of Wind and River Pulses on an Estuarine Turbidity Maximum: Numerical Studies and Field Observations, Estuaries 27(1), 132-146, 2004.

41. Biggs, R.B., Sources and distribution of suspended sediment in Northern Chesapeake Bay, Marine Geology 9(3), 187-201, 1970.

42. Cronin, T.M., Sanford, L.P., Langland, M.L., Willard, D., and Saenger, C., Chapter 6: Estuarine sediment transport, deposition, and sedimentation, in A Summary Report of Sediment Processes in Chesapeake Bay and Watershed, Water Resources Investigations Report 03-4123, Cronin, T.M., Langland, M.L., and Phillips, S., Eds, U.S. Geological Survey, New Cumberland, Pennsylvania, pp 129-160, 2003.

43. Officer, C.B., Lynch, D.R., Setlock, G.H., and Helz, G.R., Recent sedimentation rates in Chesapeake Bay, in The Estuary as a Filter, Kennedy, V.S. Ed., Academic Press, pp 131-157, 1984.

44. Schubel, J.R., Sedimentation in the upper reaches of the Chesapeake Bay, in Estuaries and Estuarine Sedimentation American Geological Institute, Washington, DC, pp VII1-29, 1971.

45. Yochum, S.E., Report No. Water Resources Investigations Report 00-4156, 2000.

46. Agrawal, Y.C. and Pottsmith, H.C., Instruments for particle size and settling velocity observations in sediment transport, Marine Geology 168(1-4), 89-114, 2000.

47. Owen, M.W., Determination of the Settling Velocities of Cohesive Muds, Hydraulics Research, Wallingford, 1976.

48. Komar, P.D. and Cui, B., The analysis of grain-size measurements by sieving and settling tube techniques, Journal of Sedimentary Petrology 54, 603-614, 1984.

49. Dearnaley, M.P., Direct measurement of settling velocities in the Owen Tube: a comparison with gravimetric analysis, in Cohesive Sediments, Parker, W.R., Parker, R., and Watts, J. Eds, John Wiley & Sons, New York, pp 75-85, 1997.

50. Jones, S.E. and Jago, C.F., Determination of settling velocity in the Elbe estuary using QUISSET tubes, Journal of Sea Research 36(1-2), 63-67, 1996.

51. Hill, P.S. and Milligan, T.G., Suspicions about settling columns, in Coastal Ocean Processes Symposium: A Tribute to William D. Grant, Woods Hole Oceanographic Institute, Woods Hole, MA, WH0I-99-04, pp 107-110, 1998.

52. Gartner, J.W., Cheng, R.T., Wang, P.F., and Richter, K., Laboratory and field evaluations of the LISST-100 instrument for suspended particle size determinations, Marine Geology 175(1-4), 199-219, 2001.

53. Traykovski, P., Latter, R.J., and Irish, J.D., A laboratory evaluation of the laser in situ scattering and transmissometry instrument using natural sediments, Marine Geology 159(1-4), 355-367, 1999.

54. Hill, P.S. and McCave, I.N., Suspended Particle Transport In Benthic Boundary Layers, in The Bentic Boundary Layer, Boudreau, B.P.J., Bo Barker Oxford University Press, New York, pp. 78-103.

55. Terray, E.A., Donelan, M.A., Agrawal, Y.C., Drennan, W.M., Kahma, K.K., Williams, I.I.I., AJ, Hwang, P.A., and Kitaigorodskii, S.A., Estimates of kinetic energy dissipation under breaking waves, Journal ofPhysical Oceanography 26(5), 792-807, 1996.

56. Sanford, L.P., Turbulent mixing in experimental ecosystems, Marine Ecology Progress Series 161, 265-293, 1997.

57. Gross, T.F., Williams, A.J., and Terray, E.A., Bottom boundary layer spectral dissipation estimates in the presence of wave motions, Continental Shelf Research 14 (10/11), 1239-1256, 1994.

58. Gust, G. and Mueller, V., Interfacial hydrodynamics and entrainment functions of currently used erosion devices, in Cohesive Sediments, Burt, N., Parker, W.R., and Watts, J. Eds, John Wiley & Sons, New York, pp 149-174, 1997.

59. Sanford, L.P. and Maa, J.P.-Y., A unified erosion formulation for fine sediments, Marine Geology 179(1-2), 9-23, 2001.

60. Gardner, W.D., Biscaye, P.E., Zaneveld, R.V., and Richardson, M.J., Calibration and comparison of the LDGO nephelometer and the OSU transmissometer on the Nova Scotian Rise, Marine Geology 66(1-4), 323-344, 1985.

61. Winterwerp, J.C., On the flocculation and settling velocity of estuarine mud, Continental Shelf Research 22(9), 1339-1360, 2002.

62. Burt, T.N., Field settling velocities of estuary muds, in Estuarine Cohesive Sediment Dynamics, Mehta, A.J. Ed., Springer-Verlag, Berlin, Heidelberg, New York, Tokyo, pp 126-150, 1986.

63. Manning, A.J. and Dyer, K.R., A laboratory examination of floc characteristics with regard to turbulent shearing, Marine Geology 160(1-2), 147-170, 1999.

64. Winterwerp, J.C., A simple model for turbulence induced flocculation of cohesive sediment, Journal of Hydraulic Research 36(3), 309-326, 1998.

65. Jackson, G.A., Using fractal scaling and two-dimensional particle size spectra to calculate coagulation rates for heterogeneous systems, Journal of Colloid and Interface Science 202(1), 20-29, 1998.

66. Thomsen, L. and Gust, G., Sediment erosion thresholds and characteristics of resus-pended aggregates on the Western European continental margin, Deep-Sea Research Part I-Oceanographic Research Papers 47(10), 1881-1897, 2000.

67. Dellapenna, T.M., Kuehl, S.A., and Schaffner, L.C., Sea-bed mixing and particle residence times in biologically and physically dominated estuarine systems: a comparison of lower Chesapeake Bay and the York River subestuary, Estuarine Coastal and Shelf Science 46(6), 777-795, 1998.

Organic Rich Aggregates in the Ocean: Formation, Transport Behavior, and Biochemical Composition

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