new citation.
Notification from Internet: in Australia (The University of Western Australia), the paper of Moscow University was cited recently:
The Moscow University paper that was cited:
"Some aspects of water filtering activity of filter-feeders" (author: S.A.Ostroumov, Moscow University)
The University of Western Australia
http://www.sese.uwa.edu.au/__data/assets/pdf_file/0011/2239517/Pranoto-Thesis.pdf
Abstract:
For ecological processes such as vegetative filtration, larval settlement, and filter feeding, there is not sufficient understanding of the mechanisms that control the rate of capture of suspended particles. In addition, despite the fact that most biological collectors exist in arrays, experimental and computational research has focused on predicting capture by a single collector. To address this, experimental runs were conducted to investigate the variation on dominant capture mechanism on a single collector and an array.
During the experimental component of this study, particle capture efficiencies were measured for three different array densities: very low, low and medium densities. For each of the array density, three different array configurations were simulated: square, staggered and random. Additionally, the trend of particle capture rate with respect to flow velocity, represented by collector Reynolds number, was also investigated. Wooden dowel rods were used to simulate the emergent aquatic collectors and pliolite particles were used to model the various suspended particles that can be found in aquatic systems.
Experimental results suggest that the mechanisms that drive particle capture in an array differ from those driving capture by a single collector. The capture efficiencies of square and staggered arrays are roughly three times those of random array, which implies that configuration is an important factor in particle capture. When compared to the capture efficiencies of a single collector, a collector in an array was found to have a lower efficiency, by more than one order of magnitude. This suggests that the dominant capture mechanism that applies to a single cylinder, direct interaction, does not apply to a collector in an array. In an array, diffusional deposition caused by random, turbulent motion of vortex shedding is suggested to be the main capture mechanism. Moreover, this prediction is supported by the fact that the collectors in an array had an even distribution of deposited particles on the front and back faces of the collectors; on the other hand, it was found that most of the particles captured on a single collector were on the front face, which characterises direct interception.
This study has shown that further research is needed to obtain full predictive capability for particle capture in aquatic systems. The next step to be taken in improving the accuracy of particle capture rate predictions is to numerically model particle capture with different array densities, configurations and flow velocities as numerical modelling allows the investigation of local hydrodynamics, especially how individual stem wakes interact with each other.**
Fragment of the text that cited the Moscow University paper:
Filter feeders have a few important roles in the ecosystem, including repairing water quality, maintaining the reliability and stability of the ecosystem, contributing to habitat heterogeneity and accelerating the transport of chemical elements (Ostroumov 2005). As part of those roles, they remove various particles of a broad range of sizes from the water (Ostroumov 2005).
**
Organisms mentioned and discussed:
filter feeding corals
Spartina alterniflora
Section 9 of this thesis:
9. References
Ackerman, JD 2000, 'Abiotic pollen and pollination: Ecological, functional, and evolutionary perspectives', Plant Systematics and Evolution, vol. 222, no. 1-4, pp. 167-185.
Ackerman, JD 2002, 'Diffusivity in a marine macrophyte canopy: implications for submarine pollination and dispersal', American Journal of Botany, vol. 89, no. 7, pp. 1119-1127.
Ayaz, F & Pedley, TJ 1999, 'Flow through and particle interception by an infinite array of closely-spaced circular cylinders', European Journal of Mechanics - B/Fluids, vol. 18, no. 2, pp. 173-196.
Bazante, J, Jacobi, G, Solo-Gabriele, HM, Reed, D, Mitchell-Bruker, S, Childers, DL, Leonard, L & Ross, M 2006, 'Hydrologic measurements and implications for tree island formation within Everglades National Park', Journal of Hydrology, vol. 329, no. 3–4, pp. 606-619.
Beckett, KP, Freer‐Smith, PH & Taylor, G 2001, 'Particulate pollution capture by urban trees: effect of species and windspeed', Global Change Biology, vol. 6, no. 8, pp. 995-1003.
Boström, C, Jackson, EL & Simenstad, CA 2006, 'Seagrass landscapes and their effects on associated fauna: a review', Estuarine, Coastal and Shelf Science, vol. 68, no. 3-4, pp. 383-403.
Bourget, E 1988, 'Barnacle larval settlement: the perception of cues at different spatial scales', NATO ASI Series A, Life Sciences, vol. 151, pp. 153-172.
Bridgham, SD, Megonigal, JP, Keller, JK, Bliss, NB & Trettin, C 2006, 'The carbon balance of North American wetlands', Wetlands, vol. 26, no. 4, pp. 889-916.
Christiansen, T, Wiberg, PL & Milligan, TG 2000, 'Flow and Sediment Transport on a Tidal Salt Marsh Surface', Estuarine, Coastal and Shelf Science, vol. 50, no. 3, pp. 315-331.
Coma, R, Gili, JM, Hughes, RN & Ribes, M 2001, 'The ultimate opportunists: consumers of seston', Marine Ecology Progress Series, vol. 308, pp. 305-308.
Crimaldi, JP, Thompson, JK, Rosman, JH, Lowe, RJ & Koseff, JR 2002, 'Hydrodynamics of Larval Settlement: The Influence of Turbulent Stress Events at Potential Recruitment Sites', Limnology and Oceanography, vol. 47, no. 4, pp. 1137-1151.
Augustina Prita Pranoto References
[54]
Dai, T & Wiegert, RG 1996, 'Ramet population dynamics and net aerial primary productivity of Spartina alterniflora', Ecology, pp. 276-288.
Duarte, CM 2002, 'The future of seagrass meadows', Environmental Conservation, vol. 29, no. 02, pp. 192-206.
Edler, C & Georgian, T 2004, 'Field Measurements of Particle-Capture Efficiency and Size Selection by Caddisfly Nets and Larvae', Journal of the North American Benthological Society, vol. 23, no. 4, pp. 756-770.
Espinosa, A, Ghisalberti, M, Ivey, G & Jones, N 2010, 'Numerical Simulation of Particle Capture by Circular Cylinders'.
Freer-Smith, PH, El-Khatib, AA & Taylor, G 2004, 'Capture of particulate pollution by trees: a comparison of species typical of semi-arid areas (Ficus nitida and Eucalyptus globulus) with European and North American species', Water, Air, & Soil Pollution, vol. 155, no. 1, pp. 173-187.
Gacia, E, Granata, TC & Duarte, CM 1999, 'An approach to measurement of particle flux and sediment retention within seagrass (Posidonia oceanica) meadows', Aquatic Botany, vol. 65, no. 1–4, pp. 255-268.
Green, EP & Short, FT 2003, World atlas of seagrasses, Univ of California Pr.
Harvey, JW & Odum, WE 1999, 'The influence of tidal marshes on upland groundwater discharge to estuaries', Biodegradation, vol. 10, no. 3, pp. 217-236.
Harvey, M, Bourget, E & Ingram, RG 1995, 'Experimental evidence of passive accumulation of marine bivalve larvae on filamentous epibenthic structures', Limnology and Oceanography, pp. 94-104.
Hemminga, MA & Duarte, CM 2000, Seagrass ecology, Cambridge University Press.
Hirano, A, Madden, M & Welch, R 2003, 'Hyperspectral image data for mapping wetland vegetation', Wetlands, vol. 23, no. 2, pp. 436-448.
Huang, YH, Saiers, JE, Harvey, JW, Noe, GB & Mylon, S 2008, 'Advection, dispersion, and filtration of fine particles within emergent vegetation of the Florida Everglades', Water Resour. Res., vol. 44, no. 4, p. W04408.
Augustina Prita Pranoto References
[55]
Jeschke, JM, Kopp, M & Tollrian, R 2004, 'Consumer-food systems: why type I functional responses are exclusive to filter feeders', Biological Reviews, vol. 79, no. 2, pp. 337-349.
Kneib, RT 1997, 'The role of tidal marshes in the ecology of estuarine nekton', Oceanography and Marine Biology, vol. 35, pp. 163-220.
Koch, DL & Ladd, AJC 1997, 'Moderate Reynolds number flows through periodic and random arrays of aligned cylinders', Journal of Fluid Mechanics, vol. 349, pp. 31-66. [1997].
Kundu, PK 1990, 'Fluid Mechanics, 638 pp', Academic, Calif.
Kundu, PK & Cohen, IM 2002, Fluid Mechancis 2ND, Elservier.
Leonard, LA, Hine, AC & Luther, ME 1995, 'Surficial sediment transport and deposition processes in a Juncus roemerianus marsh, west-central Florida', Journal of Coastal Research, pp. 322-336.
Leonard, LA & Luther, ME 1995, 'Flow hydrodynamics in tidal marsh canopies', Limnology and Oceanography, vol. 40, no. 8, pp. 1474-1484.
Leonard, LA, Wren, PA & Beavers, RL 2002, 'Flow dynamics and sedimentation in Spartina alterniflora and Phragmites australis marshes of the Chesapeake Bay', Wetlands, vol. 22, no. 2, pp. 415-424.
Lightbody, AF & Nepf, HM 2006, 'Prediction of velocity profiles and longitudinal dispersion in emergent salt marsh vegetation', Limnology and Oceanography, pp. 218-228.
Nepf, HM 1999, 'Drag, turbulence, and diffusion in flow through emergent vegetation', Water resources research, vol. 35, no. 2, pp. 479-489.
Nepf, HM 2004, 'Vegetated flow dynamics', Ecogeomorphology of tidal marshes. Coastal Estuar. Monogr. Ser, vol. 59, pp. 1735-1745.
Nepf, HM 2012, 'Flow and Transport in Regions with Aquatic Vegetation', Annual Review of Fluid Mechanics, vol. 44, no. 1, pp. 123-142.
Neumeier, U 2005, 'Quantification of vertical density variations of salt-marsh vegetation', Estuarine, Coastal and Shelf Science, vol. 63, no. 4, pp. 489-496.
Neumeier, URS & Amos, CL 2006, 'The influence of vegetation on turbulence and flow velocities in European salt-marshes', Sedimentology, vol. 53, no. 2, pp. 259-277.
Augustina Prita Pranoto References
[56]
Newell, RIE & Koch, EW 2004, 'Modeling seagrass density and distribution in response to changes in turbidity stemming from bivalve filtration and seagrass sediment stabilization', Estuaries and Coasts, vol. 27, no. 5, pp. 793-806.
Oldham, CE & Sturman, JJ 2001, 'The effect of emergent vegetation on convective flushing in shallow wetlands: Scaling and experiments', Limnology and Oceanography, pp. 1486-1493.
Ostroumov, SA 2005, 'Some aspects of water filtering activity of filter-feeders', Hydrobiologia, vol. 542, no. 1, pp. 275-286.
Palmer, MR, Nepf, HM, Pettersson, TJR & Ackerman, JD 2004, 'Observations of particle capture on a cylindrical collector: Implications for particle accumulation and removal in aquatic systems', Limnology and Oceanography, vol. 49, no. 1, pp. 76-85.
Panagiotaki, P & Geffen, AJ 2006, 'Parental effects on size variation in fish larvae', Journal of Fish Biology, vol. 41, no. sB, pp. 37-42.
Peralta, G, Duren, LA, Morris, EP & Bouma, TJ 2008, 'Consequences of shoot density and stiffness for ecosystem engineering by benthic macrophytes in flow dominated areas: a hydrodynamic flume study', Marine Ecology Progress Series, vol. 368.
Purich, A 2006, 'The capture of suspended particles by aquatic vegetation', Environmental Engineering Project Dissertation, School of Environmental Systems Engineering, The University of Western Australia.
Ramsey Iii, EW & Rangoonwala, A 2004, 'Remote sensing and the optical properties of the narrow cylindrical leaves of Juncus Roemerianus', Geoscience and Remote Sensing, IEEE Transactions on, vol. 42, no. 5, pp. 1064-1075.
Rasse, DP, Peresta, G & Drake, BG 2005, 'Seventeen years of elevated CO2 exposure in a Chesapeake Bay Wetland: sustained but contrasting responses of plant growth and CO2 uptake', Global Change Biology, vol. 11, no. 3, pp. 369-377.
Rea, N & Ganf, GG 1994, 'How emergent plants experience water regime in a Mediterranean-type wetland', Aquatic Botany, vol. 49, no. 2, pp. 117-136.
Shimeta, J & Jumars, PA 1991, 'Physical mechanisms and rates of particle capture by suspension feeders', Oceanogr. Mar. Biol. Annu. Rev, vol. 29, no. 19, pp. l-257.
Augustina Prita Pranoto References
[57]
Smith, WH 1977, 'Removal of atmospheric particulates by urban vegetation: implications for human and vegetative health', The Yale Journal of Biology and Medicine, vol. 50, no. 2, p. 185.
Stumpf, RP 1983, 'The process of sedimentation on the surface of a salt marsh', Estuarine, Coastal and Shelf Science, vol. 17, no. 5, pp. 495-508.
Tanino, Y & Nepf, H 2008, 'Laboratory Investigation of Mean Drag in a Random Array of Rigid, Emergent Cylinders', Journal of Hydraulic Engineering, vol. 134, no. 1, pp. 34-41.
Van der Valk, AG, Squires, L & Welling, CH 1994, 'Assessing the impacts of an increase in water level on wetland vegetation', Ecological Applications, pp. 525-534.
Van Katwijk, MM, Bos, AR, Hermus, DCR & Suykerbuyk, W 2010, 'Sediment modification by seagrass beds: Muddification and sandification induced by plant cover and environmental conditions', Estuarine, Coastal and Shelf Science, vol. 89, no. 2, pp. 175-181.
Whiles, MR & Dodds, WK 2002, 'Relationships between Stream Size, Suspended Particles, and Filter-Feeding Macroinvertebrates in a Great Plains Drainage Network', J. Environ. Qual., vol. 31, no. 5, pp. 1589-1600.
White, BL & Nepf, HM 2003, 'Scalar transport in random cylinder arrays at moderate Reynolds number', Journal of Fluid Mechanics, vol. 487, pp. 43-79. [2003].
Worcester, SE 1995, 'Effects of eelgrass beds on advection and turbulent mixing in low current and low shoot density environments', Marine Ecology-Progress Series, vol. 126, pp. 223-223.
This is a Notification from Google.
Notification from Internet: in Australia (The University of Western Australia), the paper of Moscow University was cited recently:
The Moscow University paper that was cited:
"Some aspects of water filtering activity of filter-feeders" (author: S.A.Ostroumov, Moscow University)
**
http://5bio5.blogspot.com/2012/12/new-citation-notification-from-internet.html
**
**
The Australian paper which cited:
[PDF] Particle Capture in Aquatic Systems: Investigating the Difference between a Single Collector and an Array
AP Pranoto - 2012
Augustina Prita PranotoAbstract: For ecological processes such as vegetative filtration, larval settlement, and filter
feeding, there is not sufficient understanding of the mechanisms that control the rate of
capture of suspended particles. In addition, despite the fact that most biological collectors ...
feeding, there is not sufficient understanding of the mechanisms that control the rate of
capture of suspended particles. In addition, despite the fact that most biological collectors ...
Abstract:
For ecological processes such as vegetative filtration, larval settlement, and filter feeding, there is not sufficient understanding of the mechanisms that control the rate of capture of suspended particles. In addition, despite the fact that most biological collectors exist in arrays, experimental and computational research has focused on predicting capture by a single collector. To address this, experimental runs were conducted to investigate the variation on dominant capture mechanism on a single collector and an array.
During the experimental component of this study, particle capture efficiencies were measured for three different array densities: very low, low and medium densities. For each of the array density, three different array configurations were simulated: square, staggered and random. Additionally, the trend of particle capture rate with respect to flow velocity, represented by collector Reynolds number, was also investigated. Wooden dowel rods were used to simulate the emergent aquatic collectors and pliolite particles were used to model the various suspended particles that can be found in aquatic systems.
Experimental results suggest that the mechanisms that drive particle capture in an array differ from those driving capture by a single collector. The capture efficiencies of square and staggered arrays are roughly three times those of random array, which implies that configuration is an important factor in particle capture. When compared to the capture efficiencies of a single collector, a collector in an array was found to have a lower efficiency, by more than one order of magnitude. This suggests that the dominant capture mechanism that applies to a single cylinder, direct interaction, does not apply to a collector in an array. In an array, diffusional deposition caused by random, turbulent motion of vortex shedding is suggested to be the main capture mechanism. Moreover, this prediction is supported by the fact that the collectors in an array had an even distribution of deposited particles on the front and back faces of the collectors; on the other hand, it was found that most of the particles captured on a single collector were on the front face, which characterises direct interception.
This study has shown that further research is needed to obtain full predictive capability for particle capture in aquatic systems. The next step to be taken in improving the accuracy of particle capture rate predictions is to numerically model particle capture with different array densities, configurations and flow velocities as numerical modelling allows the investigation of local hydrodynamics, especially how individual stem wakes interact with each other.
Fragment of the text that cited the Moscow University paper:
Filter feeders have a few important roles in the ecosystem, including repairing water quality, maintaining the reliability and stability of the ecosystem, contributing to habitat heterogeneity and accelerating the transport of chemical elements (Ostroumov 2005). As part of those roles, they remove various particles of a broad range of sizes from the water (Ostroumov 2005).
**
Organisms mentioned and discussed:
filter feeding corals
Spartina alterniflora
Section 9 of this thesis:
9. References
Ackerman, JD 2000, 'Abiotic pollen and pollination: Ecological, functional, and evolutionary perspectives', Plant Systematics and Evolution, vol. 222, no. 1-4, pp. 167-185.
Ackerman, JD 2002, 'Diffusivity in a marine macrophyte canopy: implications for submarine pollination and dispersal', American Journal of Botany, vol. 89, no. 7, pp. 1119-1127.
Ayaz, F & Pedley, TJ 1999, 'Flow through and particle interception by an infinite array of closely-spaced circular cylinders', European Journal of Mechanics - B/Fluids, vol. 18, no. 2, pp. 173-196.
Bazante, J, Jacobi, G, Solo-Gabriele, HM, Reed, D, Mitchell-Bruker, S, Childers, DL, Leonard, L & Ross, M 2006, 'Hydrologic measurements and implications for tree island formation within Everglades National Park', Journal of Hydrology, vol. 329, no. 3–4, pp. 606-619.
Beckett, KP, Freer‐Smith, PH & Taylor, G 2001, 'Particulate pollution capture by urban trees: effect of species and windspeed', Global Change Biology, vol. 6, no. 8, pp. 995-1003.
Boström, C, Jackson, EL & Simenstad, CA 2006, 'Seagrass landscapes and their effects on associated fauna: a review', Estuarine, Coastal and Shelf Science, vol. 68, no. 3-4, pp. 383-403.
Bourget, E 1988, 'Barnacle larval settlement: the perception of cues at different spatial scales', NATO ASI Series A, Life Sciences, vol. 151, pp. 153-172.
Bridgham, SD, Megonigal, JP, Keller, JK, Bliss, NB & Trettin, C 2006, 'The carbon balance of North American wetlands', Wetlands, vol. 26, no. 4, pp. 889-916.
Christiansen, T, Wiberg, PL & Milligan, TG 2000, 'Flow and Sediment Transport on a Tidal Salt Marsh Surface', Estuarine, Coastal and Shelf Science, vol. 50, no. 3, pp. 315-331.
Coma, R, Gili, JM, Hughes, RN & Ribes, M 2001, 'The ultimate opportunists: consumers of seston', Marine Ecology Progress Series, vol. 308, pp. 305-308.
Crimaldi, JP, Thompson, JK, Rosman, JH, Lowe, RJ & Koseff, JR 2002, 'Hydrodynamics of Larval Settlement: The Influence of Turbulent Stress Events at Potential Recruitment Sites', Limnology and Oceanography, vol. 47, no. 4, pp. 1137-1151.
Augustina Prita Pranoto References
[54]
Dai, T & Wiegert, RG 1996, 'Ramet population dynamics and net aerial primary productivity of Spartina alterniflora', Ecology, pp. 276-288.
Duarte, CM 2002, 'The future of seagrass meadows', Environmental Conservation, vol. 29, no. 02, pp. 192-206.
Edler, C & Georgian, T 2004, 'Field Measurements of Particle-Capture Efficiency and Size Selection by Caddisfly Nets and Larvae', Journal of the North American Benthological Society, vol. 23, no. 4, pp. 756-770.
Espinosa, A, Ghisalberti, M, Ivey, G & Jones, N 2010, 'Numerical Simulation of Particle Capture by Circular Cylinders'.
Freer-Smith, PH, El-Khatib, AA & Taylor, G 2004, 'Capture of particulate pollution by trees: a comparison of species typical of semi-arid areas (Ficus nitida and Eucalyptus globulus) with European and North American species', Water, Air, & Soil Pollution, vol. 155, no. 1, pp. 173-187.
Gacia, E, Granata, TC & Duarte, CM 1999, 'An approach to measurement of particle flux and sediment retention within seagrass (Posidonia oceanica) meadows', Aquatic Botany, vol. 65, no. 1–4, pp. 255-268.
Green, EP & Short, FT 2003, World atlas of seagrasses, Univ of California Pr.
Harvey, JW & Odum, WE 1999, 'The influence of tidal marshes on upland groundwater discharge to estuaries', Biodegradation, vol. 10, no. 3, pp. 217-236.
Harvey, M, Bourget, E & Ingram, RG 1995, 'Experimental evidence of passive accumulation of marine bivalve larvae on filamentous epibenthic structures', Limnology and Oceanography, pp. 94-104.
Hemminga, MA & Duarte, CM 2000, Seagrass ecology, Cambridge University Press.
Hirano, A, Madden, M & Welch, R 2003, 'Hyperspectral image data for mapping wetland vegetation', Wetlands, vol. 23, no. 2, pp. 436-448.
Huang, YH, Saiers, JE, Harvey, JW, Noe, GB & Mylon, S 2008, 'Advection, dispersion, and filtration of fine particles within emergent vegetation of the Florida Everglades', Water Resour. Res., vol. 44, no. 4, p. W04408.
Augustina Prita Pranoto References
[55]
Jeschke, JM, Kopp, M & Tollrian, R 2004, 'Consumer-food systems: why type I functional responses are exclusive to filter feeders', Biological Reviews, vol. 79, no. 2, pp. 337-349.
Kneib, RT 1997, 'The role of tidal marshes in the ecology of estuarine nekton', Oceanography and Marine Biology, vol. 35, pp. 163-220.
Koch, DL & Ladd, AJC 1997, 'Moderate Reynolds number flows through periodic and random arrays of aligned cylinders', Journal of Fluid Mechanics, vol. 349, pp. 31-66. [1997].
Kundu, PK 1990, 'Fluid Mechanics, 638 pp', Academic, Calif.
Kundu, PK & Cohen, IM 2002, Fluid Mechancis 2ND, Elservier.
Leonard, LA, Hine, AC & Luther, ME 1995, 'Surficial sediment transport and deposition processes in a Juncus roemerianus marsh, west-central Florida', Journal of Coastal Research, pp. 322-336.
Leonard, LA & Luther, ME 1995, 'Flow hydrodynamics in tidal marsh canopies', Limnology and Oceanography, vol. 40, no. 8, pp. 1474-1484.
Leonard, LA, Wren, PA & Beavers, RL 2002, 'Flow dynamics and sedimentation in Spartina alterniflora and Phragmites australis marshes of the Chesapeake Bay', Wetlands, vol. 22, no. 2, pp. 415-424.
Lightbody, AF & Nepf, HM 2006, 'Prediction of velocity profiles and longitudinal dispersion in emergent salt marsh vegetation', Limnology and Oceanography, pp. 218-228.
Nepf, HM 1999, 'Drag, turbulence, and diffusion in flow through emergent vegetation', Water resources research, vol. 35, no. 2, pp. 479-489.
Nepf, HM 2004, 'Vegetated flow dynamics', Ecogeomorphology of tidal marshes. Coastal Estuar. Monogr. Ser, vol. 59, pp. 1735-1745.
Nepf, HM 2012, 'Flow and Transport in Regions with Aquatic Vegetation', Annual Review of Fluid Mechanics, vol. 44, no. 1, pp. 123-142.
Neumeier, U 2005, 'Quantification of vertical density variations of salt-marsh vegetation', Estuarine, Coastal and Shelf Science, vol. 63, no. 4, pp. 489-496.
Neumeier, URS & Amos, CL 2006, 'The influence of vegetation on turbulence and flow velocities in European salt-marshes', Sedimentology, vol. 53, no. 2, pp. 259-277.
Augustina Prita Pranoto References
[56]
Newell, RIE & Koch, EW 2004, 'Modeling seagrass density and distribution in response to changes in turbidity stemming from bivalve filtration and seagrass sediment stabilization', Estuaries and Coasts, vol. 27, no. 5, pp. 793-806.
Oldham, CE & Sturman, JJ 2001, 'The effect of emergent vegetation on convective flushing in shallow wetlands: Scaling and experiments', Limnology and Oceanography, pp. 1486-1493.
Ostroumov, SA 2005, 'Some aspects of water filtering activity of filter-feeders', Hydrobiologia, vol. 542, no. 1, pp. 275-286.
Palmer, MR, Nepf, HM, Pettersson, TJR & Ackerman, JD 2004, 'Observations of particle capture on a cylindrical collector: Implications for particle accumulation and removal in aquatic systems', Limnology and Oceanography, vol. 49, no. 1, pp. 76-85.
Panagiotaki, P & Geffen, AJ 2006, 'Parental effects on size variation in fish larvae', Journal of Fish Biology, vol. 41, no. sB, pp. 37-42.
Peralta, G, Duren, LA, Morris, EP & Bouma, TJ 2008, 'Consequences of shoot density and stiffness for ecosystem engineering by benthic macrophytes in flow dominated areas: a hydrodynamic flume study', Marine Ecology Progress Series, vol. 368.
Purich, A 2006, 'The capture of suspended particles by aquatic vegetation', Environmental Engineering Project Dissertation, School of Environmental Systems Engineering, The University of Western Australia.
Ramsey Iii, EW & Rangoonwala, A 2004, 'Remote sensing and the optical properties of the narrow cylindrical leaves of Juncus Roemerianus', Geoscience and Remote Sensing, IEEE Transactions on, vol. 42, no. 5, pp. 1064-1075.
Rasse, DP, Peresta, G & Drake, BG 2005, 'Seventeen years of elevated CO2 exposure in a Chesapeake Bay Wetland: sustained but contrasting responses of plant growth and CO2 uptake', Global Change Biology, vol. 11, no. 3, pp. 369-377.
Rea, N & Ganf, GG 1994, 'How emergent plants experience water regime in a Mediterranean-type wetland', Aquatic Botany, vol. 49, no. 2, pp. 117-136.
Shimeta, J & Jumars, PA 1991, 'Physical mechanisms and rates of particle capture by suspension feeders', Oceanogr. Mar. Biol. Annu. Rev, vol. 29, no. 19, pp. l-257.
Augustina Prita Pranoto References
[57]
Smith, WH 1977, 'Removal of atmospheric particulates by urban vegetation: implications for human and vegetative health', The Yale Journal of Biology and Medicine, vol. 50, no. 2, p. 185.
Stumpf, RP 1983, 'The process of sedimentation on the surface of a salt marsh', Estuarine, Coastal and Shelf Science, vol. 17, no. 5, pp. 495-508.
Tanino, Y & Nepf, H 2008, 'Laboratory Investigation of Mean Drag in a Random Array of Rigid, Emergent Cylinders', Journal of Hydraulic Engineering, vol. 134, no. 1, pp. 34-41.
Van der Valk, AG, Squires, L & Welling, CH 1994, 'Assessing the impacts of an increase in water level on wetland vegetation', Ecological Applications, pp. 525-534.
Van Katwijk, MM, Bos, AR, Hermus, DCR & Suykerbuyk, W 2010, 'Sediment modification by seagrass beds: Muddification and sandification induced by plant cover and environmental conditions', Estuarine, Coastal and Shelf Science, vol. 89, no. 2, pp. 175-181.
Whiles, MR & Dodds, WK 2002, 'Relationships between Stream Size, Suspended Particles, and Filter-Feeding Macroinvertebrates in a Great Plains Drainage Network', J. Environ. Qual., vol. 31, no. 5, pp. 1589-1600.
White, BL & Nepf, HM 2003, 'Scalar transport in random cylinder arrays at moderate Reynolds number', Journal of Fluid Mechanics, vol. 487, pp. 43-79. [2003].
Worcester, SE 1995, 'Effects of eelgrass beds on advection and turbulent mixing in low current and low shoot density environments', Marine Ecology-Progress Series, vol. 126, pp. 223-223.
This is a Notification from Google.
