Sedimentation is the deposition of
sediments.[1] It takes place when
particles in
suspension settle out of the
fluid in which they are
entrained and come to rest against a barrier. This is due to their motion through the fluid in response to the
forces acting on them: these forces can be due to
gravity,
centrifugal acceleration, or
electromagnetism.
Settling is the falling of suspended particles through the liquid, whereas sedimentation is the final result of the settling process.
In
geology, sedimentation is the
deposition of sediments which results in the formation of
sedimentary rock. The term is broadly applied to the entire range of processes that result in the formation of sedimentary rock, from initial
erosion through
sediment transport and settling to the
lithification of the sediments. However, the strict geological definition of sedimentation is the mechanical deposition of sediment particles from an initial suspension in air or water.
Sedimentation may pertain to objects of various sizes, ranging from large rocks in flowing water, to suspensions of dust and pollen particles, to
cellular suspensions, to
solutions of single
molecules such as
proteins and
peptides. Even small molecules supply a sufficiently strong force to produce significant sedimentation.
Settling is the process by which particulates move towards the bottom of a liquid and form a
sediment. Particles that experience a force, either due to gravity or due to
centrifugal motion will tend to move in a uniform manner in the direction exerted by that force. For gravity settling, this means that the particles will tend to fall to the bottom of the vessel, forming
sludge or
slurry at the vessel base.
Settling is an important operation in many applications, such as
mining,
wastewater and
drinking water treatment, biological science,
spacepropellant reignition,[2]
Type 1 sedimentation is characterized by particles that settle discretely at a constant settling velocity, or by the deposition of Iron-Rich minerals to streamlines down to the point source. They settle as individual particles and do not
flocculate (stick to each other) during settling. Example: sand and grit material
Type 2 sedimentation is characterized by particles that flocculate during sedimentation and because of this their size is constantly changing and therefore their settling velocity is changing. Example: alum or iron coagulation
Type 3 sedimentation is also known as zone sedimentation. In this process the particles are at a high concentration (greater than 1000 mg/L) such that the particles tend to settle as a mass and a distinct clear zone and sludge zone are present. Zone settling occurs in lime-softening, sedimentation, active sludge sedimentation and sludge thickeners.
When particles settling from a suspension reach a hard boundary, the concentration of particles at the boundary is opposed by the
diffusion of the particles. The distribution of sediment near the boundary comes into
sedimentation equilibrium. Measurements of the distribution yields information on the nature of the particles.[4][5]
In
geology, the term sedimentation is broadly applied to the entire range of processes that result in the formation of sedimentary rock, from initial formation of sediments by
erosion of particles from rock outcrops, through
sediment transport and settling, to the
lithification of the sediments. However, the term is more particularly applied to the deposition of sediments, and in the strictest sense, it applies only to the mechanical deposition of sediment particles from an initial suspension in air or water. Sedimentation results in the formation of depositional
landforms and the rocks that constitute the
sedimentary record.[6] The building up of land surfaces by sedimentation, particularly in river valleys, is called aggradation.[7]
The rate of sedimentation is the thickness of sediment accumulated per unit time.[8] For
suspended load, this can be expressed mathematically by the
Exner equation.[9] Rates of sedimentation vary from less than 3 millimeters (0.12 in) for
pelagic sediment to several meters per year in portions of major
river deltas. However, long-term accumulation of sediments is determined less by rate of sedimentation than by rate of subsidence, which creates
accommodation space for sediments to accumulate over geological time scales. Most sedimentation in the
geologic record occurred in relative brief depositional episodes separated by long intervals of nondeposition or even erosion.[10]
In
estuarine environments, settling can be influenced by the presence or absence of vegetation. Trees such as mangroves are crucial to the
attenuation of waves or currents, promoting the settlement of suspended particles.[11]
An undesired increased transport and sedimentation of suspended material is called
siltation, and it is a major source of pollution in waterways in some parts of the world.[12][13] High sedimentation rates can be a result of poor land management and a high frequency of flooding events. If not managed properly, it can be detrimental to fragile ecosystems on the receiving end, such as coral reefs.[14]Climate change also affects siltation rates.[15]
Sedimentation enhancing strategies are
environmental management projects aiming to restore and facilitate land-building processes in
deltas.[16]Sediment availability and deposition are important because deltas naturally
subside and therefore need sediment accumulation to maintain their elevation, particularly considering increasing rates of
sea-level rise.[17][18] Sedimentation enhancing strategies aim to increase sedimentation on the delta plain primarily by restoring the exchange of water and sediments between
rivers and low-lying delta plains. Sedimentation enhancing strategies can be applied to encourage
land elevation gain to offset sea-level rise.[19] Interest in sedimentation enhancing strategies has recently increased due to their ability to raise land elevation, which is important for the long-term
sustainability of deltas.[16]
In chemistry
In chemistry, sedimentation has been used to measure the size of large molecules (
macromolecule), where the force of gravity is augmented with
centrifugal force in an
ultracentrifuge.
The physical process of sedimentation (the act of depositing
sediment) has applications in
water treatment, whereby
gravity acts to remove
suspended solids from water.[20] Solid particles entrained by the
turbulence of moving water may be removed naturally by sedimentation in the still water of lakes and oceans.
Settling basins are ponds constructed for the purpose of removing entrained solids by sedimentation.[21]Clarifiers are tanks built with mechanical means for continuous removal of solids being deposited by sedimentation;[22] however, clarification does not remove
dissolved solids.[23]
^
Zegler, Frank; Bernard Kutter (2010-09-02).
"Evolving to a Depot-Based Space Transportation Architecture"(PDF). AIAA SPACE 2010 Conference & Exposition. AIAA. Archived from
the original(PDF) on 2013-05-10. Retrieved 2011-01-25. It consumes waste hydrogen and oxygen to produce power, generate settling and attitude control thrust.
^Coe, H.S.; Clevenger, G.H. (1916). "Methods for determining the capacities of slime-settling tanks". Transactions of the American Institute of Mining and Metallurgical Engineers. 55: 356.
^Jackson, Julia A., ed. (1997). "sedimentation". Glossary of geology (Fourth ed.). Alexandria, Virginia: American Geological Institute.
ISBN0922152349.
^Blatt, Harvey; Middleton, Gerard; Murray, Raymond (1980). Origin of sedimentary rocks (2d ed.). Englewood Cliffs, N.J.: Prentice-Hall. pp. 30–31, 122–123.
ISBN0136427103.
^Van Santen, P.; Augustinus, P. G. E. F.; Janssen-Stelder, B. M.; Quartel, S.; Tri, N. H. (2007-02-15). "Sedimentation in an estuarine mangrove system". Journal of Asian Earth Sciences. Morphodynamics of the Red River Delta, Vietnam. 29 (4): 566–575.
Bibcode:
2007JAESc..29..566V.
doi:
10.1016/j.jseaes.2006.05.011.
^Victor, Steven; Neth, Leinson; Golbuu, Yimnang; Wolanski, Eric; Richmond, Robert H. (2006-02-01). "Sedimentation in mangroves and coral reefs in a wet tropical island, Pohnpei, Micronesia". Estuarine, Coastal and Shelf Science. 66 (3–4): 409–416.
Bibcode:
2006ECSS...66..409V.
doi:
10.1016/j.ecss.2005.07.025.
^Omelia, C (1998). "Coagulation and sedimentation in lakes, reservoirs and water treatment plants". Water Science and Technology. 37 (2): 129.
doi:
10.1016/S0273-1223(98)00018-3.
^Goldman, Steven J., Jackson, Katharine & Bursztynsky, Taras A. Erosion & Sediment Control Handbook. McGraw-Hill (1986).
ISBN0-07-023655-0. pp. 8.2, 8.12.
^Hammer, Mark J. Water and Waste-Water Technology. John Wiley & Sons (1975).
ISBN0-471-34726-4. pp. 223–225.