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Silt

February 15, 2024

For other uses, see Silt (disambiguation).

Silt is granular material of a size between sand and clay and composed mostly of broken grains of quartz.[1] Silt may occur as a soil (often mixed with sand or clay) or as sediment mixed in suspension with water. Silt usually has a floury feel when dry, and lacks plasticity when wet. Silt can also be felt by the tongue as granular when placed on the front teeth (even when mixed with clay particles).

Windrow of windblown silt, Northwest Territories, Canada

Silt is a common material, making up 45% of average modern mud. It is found in many river deltas and as wind-deposited accumulations, particularly in central Asia, north China, and North America. It is produced in both very hot climates (through such processes as collisions of quartz grains in dust storms) and very cold climates (through such processes as glacial grinding of quartz grains.)

Loess is soil rich in silt which makes up some of the most fertile agricultural land on Earth. However, silt is very vulnerable to erosion, and it has poor mechanical properties, making construction on silty soil problematic. The failure of the Teton Dam in 1976 has been attributed to the use of unsuitable loess in the dam core, and liquefication of silty soil is a significant earthquake hazard. Windblown and waterborne silt are significant forms of environmental pollution, often exacerbated by poor farming practices.

Description edit

Silt is detritus (fragments of weathered and eroded rock) with properties intermediate between sand and clay. A more precise definition of silt used by geologists is that it is detrital particles with sizes between 1/256 and 1/16 mm (about 4 to 63 microns).[2] This corresponds to particles between 8 and 4 phi units on the Krumbein phi scale.[3][4] Other geologists define silt as detrital particles between 2 and 63 microns or 9 to 4 phi units.[5] A third definition is that silt is fine-grained detrital material composed of quartz rather than clay minerals.[6] Since most clay mineral particles are smaller than 2 microns,[7] while most detrital particles between 2 and 63 microns in size are composed of broken quartz grains, there is good agreement between these definitions in practice.[5]

The upper size limit of 1/16 mm or 63 microns corresponds to the smallest particles that can be discerned with the unaided eye.[8] It also corresponds to a Tanner gap in the distribution of particle sizes in sediments: Particles between 120 and 30 microns in size are scarce in most sediments, suggesting that the distinction between sand and silt has physical significance.[5] As noted above, the lower limit of 2 to 4 microns corresponds to the transition from particles that are predominantly broken quartz grains to particles that are predominantly clay mineral particles.[5]

Assallay and coinvestigators further divide silt into three size ranges: C (2–5 microns), which represents post-glacial clays and desert dust; D1 (20–30 microns) representing "traditional" loess; and D2 (60 microns) representing the very coarse North African loess.[5]

Silt can be distinguished from clay in the field by its lack of plasticity or cohesiveness and by its grain size. Silt grains are large enough to give silt a gritty feel,[7] particularly if a sample is placed between the teeth. Clay-size particles feel smooth between the teeth.[9] The proportions of coarse and fine silt in a sediment sample are determined more precisely in the laboratory using the pipette method, which is based on settling rate via Stokes' law and gives the particle size distribution accordingly.[10] The mineral composition of silt particles can be determined with a petrographic microscope for grain sizes as low as 10 microns.[11]

Vadose silt is silt-sized calcite crystals found in pore spaces and vugs in limestone. This is emplaced as sediment is carried through the vadose zone to be deposited in pore space.[12]

Definitions edit

ASTM American Standard of Testing Materials: 200 sieve – 0.005 mm.

USDA United States Department of Agriculture 0.05–0.002 mm.

ISSS International Society of Soil Science 0.02–0.002 mm.

Civil engineers in the United States define silt as material made of particles that pass a number 200 sieve (0.074 mm or less) but show little plasticity when wet and little cohesion when air-dried.[13] The International Society of Soil Science (ISSS) defines silt as soil containing 80% or more of particles between 0.002 mm to 0.02 mm in size[14] while the U.S. Department of Agriculture puts the cutoff at 0.05mm.[15] The term silt is also used informally for material containing much sand and clay as well as silt-sized particles, or for mud suspended in water.[8]

Occurrence edit

Silt is a very common material, and it has been estimated that there are a billion trillion trillion (1033) silt grains worldwide. Silt is abundant in eolian and alluvial deposits, including river deltas, such as the Nile and Niger River deltas. Bangladesh is largely underlain by silt deposits of the Ganges delta. Silt is also abundant in northern China, central Asia, and North America.[5] However, silt is relatively uncommon in the tropical regions of the world.[16]

Silt is commonly found in suspension in river water, and it makes up over 0.2% of river sand. It is abundant in the matrix between the larger sand grains of graywackes. Modern mud has an average silt content of 45%.[17] Silt is often found in mudrock as thin laminae, as clumps, or dispersed throughout the rock. Laminae suggest deposition in a weak current that winnows the silt of clay, while clumps suggest an origin as fecal pellets. Where silt is dispersed throughout the mudrock, it likely was deposited by rapid processes, such as flocculation.[18] Sedimentary rock composed mainly of silt is known as siltstone.[19]

Silt is common throughout the geologic record, but it seems to be particularly common in Quaternary formations. This may be because deposition of silt is favored by the glaciation and arctic conditions characteristic of the Quaternary.[5] Silt is sometimes known as rock flour or glacier meal, especially when produced by glacial action.[20] Silt suspended in water draining from glaciers is sometimes known as rock milk or moonmilk.[21]

Sources edit

 
A stream carrying silt from fields in Brastad, Sweden

A simple explanation for silt formation is that it is a straightforward continuation to a smaller scale of the disintegration of rock into gravel and sand.[22] However, the presence of a Tanner gap between sand and silt (a scarcity of particles with sizes between 30 and 120 microns) suggests that different physical processes produce sand and silt.[23] The mechanisms of silt formation have been studied extensively in the laboratory[24] and compared with field observations. These show that silt formation requires high-energy processes acting over long periods of time, but such processes are present in diverse geologic settings.[5]

Quartz silt grains are usually found to have a platy or bladed shape.[25] This may be characteristic of how larger grains abrade, or reflect the shape of small quartz grains in foliated metamorphic rock, or arise from authigenic growth of quartz grains parallel to bedding in sedimentary rock.[26] Theoretically, particles formed by random fracturing of an isotropic material, such as quartz, naturally tend to be blade-shaped.[27] The size of silt grains produced by abrasion or shattering of larger grains may reflect defects in the crystal structure of the quartz, known as Moss defects.[28] Such defects are produced by tectonic deformation of the parent rock, and also arise from the high-low transition of quartz: Quartz experiences a sharp decrease in volume when it cools below a temperature of about 573 °C (1,063 °F),[29] which creates strain and crystal defects in the quartz grains in a cooling body of granite.[30]

Mechanisms for silt production include:[5]

  • Erosion of initially silt-sized grains from low-grade metamorphic rock.
  • Production of silt-sized grains from fracture of larger grains during initial rock weathering and soil formation,[31] through processes such as frost shattering[32] and haloclasty.[33] This produces silt particles whose size of 10-30 microns is determined by Moss defects.[5]
  • Production of silt-sized grains from grain-to-grain impact during transport of coarser sediments.
  • Formation of authigenic quartz during weathering to clay.
  • Crystallization of the tests of siliceous organisms deposited in mudrock.

Laboratory experiments have produced contradictory results regarding the effectiveness of various silt production mechanisms. This may be due to the use of vein or pegmatite quartz in some of the experiments. Both materials form under conditions promoting ideal crystal growth, and may lack the Moss defects of quartz grains in granites. Thus production of silt from vein quartz is very difficult by any mechanism, whereas production of silt from granite quartz proceeds readily by any of a number of mechanisms.[5] However, the main process is likely abrasion through transport, including fluvial comminution, aeolian attrition and glacial grinding.[24]

Because silt deposits (such as loess, a soil composed mostly of silt[34]) seem to be associated with glaciated or mountainous regions in Asia and North America, much emphasis has been placed on glacial grinding as a source of silt. High Asia has been identified as a major generator of silt, which accumulated to form the fertile soils of north India and Bangladesh, and the loess of central Asia and north China.[5] Loess has long been though to be absent or rare in deserts lacking nearby mountains (Sahara, Australia).[35] However, laboratory experiments show eolian and fluvial processes can be quite efficient at producing silt,[24] as can weathering in tropical climates.[36] Silt seems to be produced in great quantities in dust storms, and silt deposits found Israel, Tunisia, Nigeria, and Saudi Arabia cannot be attributed to glaciation. Furthermore, desert source areas in Asia may be more important for loess formation than previously thought. Part of the problem may be the conflation of high rates of production with environments conducive to deposition and preservation, which favors glacial climates more than deserts.[37]

Loess associated with glaciation and cold weathering may be distinguishable from loess associated with hot regions by the size distribution. Glacial loess has a typical particle size of about 25 microns. Desert loess contains either larger or smaller particles, with the fine silt produced in dust storms and the coarse silt fraction possibly representing the fine particle tail of sand production.[5]

Human impact edit

Loess underlies some of the most productive agricultural land worldwide. However, it is very susceptible to erosion.[5] The quartz particles in silt do not themselves provide nutrients, but they promote excellent soil structure, and silt-sized particles of other minerals, present in smaller amounts, provide the necessary nutrients.[16] Silt, deposited by annual floods along the Nile River, created the rich, fertile soil that sustained the Ancient Egyptian civilization. The closure of the Aswan High Dam has cut off this source of silt, and the fertility of the Nile delta is deteriorating.[38]

Loess tends to lose strength when wetted, and this can lead to failure of building foundations.[5] The silty material has an open structure that collapses when wet.[39] Quick clay (a combination of very fine silt and clay-sized particles from glacial grinding) is a particular challenge for civil engineering.[40]

The failure of the Teton Dam has been attributed to the use of loess from the Snake River floodplain in the core of the dam.[41] Loess lacks the necessary plasticity for use in a dam core, but its properties were poorly understood, even by the U.S. Bureau of Reclamation, with its wealth of experience building earthen dams.[5]

Silt is susceptible to liquefaction during strong earthquakes due to its lack of plasticity. This has raised concerns about the earthquake damage potential in the silty soil of the central United States in the event of a major earthquake in the New Madrid Seismic Zone.[42][43]

Environmental impacts edit

 
A silted lake located in Eichhorst, Germany

Silt is easily transported in water[44] and is fine enough to be carried long distances by air in the form of dust.[45] While the coarsest silt particles (60 micron) settle out of a meter of still water in just five minutes, the finest silt grains (2 microns) can take several days to settle out of still water.[46] When silt appears as a pollutant in water the phenomenon is known as siltation.[47]

Silt deposited by the Mississippi River throughout the 20th century has decreased due to a system of levees, contributing to the disappearance of protective wetlands and barrier islands in the delta region surrounding New Orleans.[48]

In southeast Bangladesh, in the Noakhali district, cross dams were built in the 1960s whereby silt gradually started forming new land called "chars". The district of Noakhali has gained more than 73 square kilometres (28 sq mi) of land in the past 50 years. With Dutch funding, the Bangladeshi government began to help develop older chars in the late 1970s, and the effort has since become a multi-agency operation building roads, culverts, embankments, cyclone shelters, toilets and ponds, as well as distributing land to settlers. By fall 2010, the program will have allotted some 100 square kilometres (20,000 acres) to 21,000 families.[49]

A main source of silt in urban rivers is disturbance of soil by construction activity.[50] A main source in rural rivers is erosion from plowing of farm fields,[51] clearcutting or slash and burn treatment of forests.[52]

Culture edit

The fertile black silt of the Nile river's banks is a symbol of rebirth, associated with the Egyptian god Anubis.[53][54]

See also edit

 
Wikimedia Commons has media related to Silt.

References edit

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February 15, 2024
silt, other, uses, disambiguation, granular, material, size, between, sand, clay, composed, mostly, broken, grains, quartz, occur, soil, often, mixed, with, sand, clay, sediment, mixed, suspension, with, water, usually, floury, feel, when, lacks, plasticity, w. For other uses see Silt disambiguation Silt is granular material of a size between sand and clay and composed mostly of broken grains of quartz 1 Silt may occur as a soil often mixed with sand or clay or as sediment mixed in suspension with water Silt usually has a floury feel when dry and lacks plasticity when wet Silt can also be felt by the tongue as granular when placed on the front teeth even when mixed with clay particles Windrow of windblown silt Northwest Territories CanadaSilt is a common material making up 45 of average modern mud It is found in many river deltas and as wind deposited accumulations particularly in central Asia north China and North America It is produced in both very hot climates through such processes as collisions of quartz grains in dust storms and very cold climates through such processes as glacial grinding of quartz grains Loess is soil rich in silt which makes up some of the most fertile agricultural land on Earth However silt is very vulnerable to erosion and it has poor mechanical properties making construction on silty soil problematic The failure of the Teton Dam in 1976 has been attributed to the use of unsuitable loess in the dam core and liquefication of silty soil is a significant earthquake hazard Windblown and waterborne silt are significant forms of environmental pollution often exacerbated by poor farming practices Contents 1 Description 1 1 Definitions 2 Occurrence 3 Sources 4 Human impact 5 Environmental impacts 6 Culture 7 See also 8 ReferencesDescription editSilt is detritus fragments of weathered and eroded rock with properties intermediate between sand and clay A more precise definition of silt used by geologists is that it is detrital particles with sizes between 1 256 and 1 16 mm about 4 to 63 microns 2 This corresponds to particles between 8 and 4 phi units on the Krumbein phi scale 3 4 Other geologists define silt as detrital particles between 2 and 63 microns or 9 to 4 phi units 5 A third definition is that silt is fine grained detrital material composed of quartz rather than clay minerals 6 Since most clay mineral particles are smaller than 2 microns 7 while most detrital particles between 2 and 63 microns in size are composed of broken quartz grains there is good agreement between these definitions in practice 5 The upper size limit of 1 16 mm or 63 microns corresponds to the smallest particles that can be discerned with the unaided eye 8 It also corresponds to a Tanner gap in the distribution of particle sizes in sediments Particles between 120 and 30 microns in size are scarce in most sediments suggesting that the distinction between sand and silt has physical significance 5 As noted above the lower limit of 2 to 4 microns corresponds to the transition from particles that are predominantly broken quartz grains to particles that are predominantly clay mineral particles 5 Assallay and coinvestigators further divide silt into three size ranges C 2 5 microns which represents post glacial clays and desert dust D1 20 30 microns representing traditional loess and D2 60 microns representing the very coarse North African loess 5 Silt can be distinguished from clay in the field by its lack of plasticity or cohesiveness and by its grain size Silt grains are large enough to give silt a gritty feel 7 particularly if a sample is placed between the teeth Clay size particles feel smooth between the teeth 9 The proportions of coarse and fine silt in a sediment sample are determined more precisely in the laboratory using the pipette method which is based on settling rate via Stokes law and gives the particle size distribution accordingly 10 The mineral composition of silt particles can be determined with a petrographic microscope for grain sizes as low as 10 microns 11 Vadose silt is silt sized calcite crystals found in pore spaces and vugs in limestone This is emplaced as sediment is carried through the vadose zone to be deposited in pore space 12 Definitions edit ASTM American Standard of Testing Materials 200 sieve 0 005 mm USDA United States Department of Agriculture 0 05 0 002 mm ISSS International Society of Soil Science 0 02 0 002 mm Civil engineers in the United States define silt as material made of particles that pass a number 200 sieve 0 074 mm or less but show little plasticity when wet and little cohesion when air dried 13 The International Society of Soil Science ISSS defines silt as soil containing 80 or more of particles between 0 002 mm to 0 02 mm in size 14 while the U S Department of Agriculture puts the cutoff at 0 05mm 15 The term silt is also used informally for material containing much sand and clay as well as silt sized particles or for mud suspended in water 8 Occurrence editSilt is a very common material and it has been estimated that there are a billion trillion trillion 1033 silt grains worldwide Silt is abundant in eolian and alluvial deposits including river deltas such as the Nile and Niger River deltas Bangladesh is largely underlain by silt deposits of the Ganges delta Silt is also abundant in northern China central Asia and North America 5 However silt is relatively uncommon in the tropical regions of the world 16 Silt is commonly found in suspension in river water and it makes up over 0 2 of river sand It is abundant in the matrix between the larger sand grains of graywackes Modern mud has an average silt content of 45 17 Silt is often found in mudrock as thin laminae as clumps or dispersed throughout the rock Laminae suggest deposition in a weak current that winnows the silt of clay while clumps suggest an origin as fecal pellets Where silt is dispersed throughout the mudrock it likely was deposited by rapid processes such as flocculation 18 Sedimentary rock composed mainly of silt is known as siltstone 19 Silt is common throughout the geologic record but it seems to be particularly common in Quaternary formations This may be because deposition of silt is favored by the glaciation and arctic conditions characteristic of the Quaternary 5 Silt is sometimes known as rock flour or glacier meal especially when produced by glacial action 20 Silt suspended in water draining from glaciers is sometimes known as rock milk or moonmilk 21 Sources edit nbsp A stream carrying silt from fields in Brastad SwedenA simple explanation for silt formation is that it is a straightforward continuation to a smaller scale of the disintegration of rock into gravel and sand 22 However the presence of a Tanner gap between sand and silt a scarcity of particles with sizes between 30 and 120 microns suggests that different physical processes produce sand and silt 23 The mechanisms of silt formation have been studied extensively in the laboratory 24 and compared with field observations These show that silt formation requires high energy processes acting over long periods of time but such processes are present in diverse geologic settings 5 Quartz silt grains are usually found to have a platy or bladed shape 25 This may be characteristic of how larger grains abrade or reflect the shape of small quartz grains in foliated metamorphic rock or arise from authigenic growth of quartz grains parallel to bedding in sedimentary rock 26 Theoretically particles formed by random fracturing of an isotropic material such as quartz naturally tend to be blade shaped 27 The size of silt grains produced by abrasion or shattering of larger grains may reflect defects in the crystal structure of the quartz known as Moss defects 28 Such defects are produced by tectonic deformation of the parent rock and also arise from the high low transition of quartz Quartz experiences a sharp decrease in volume when it cools below a temperature of about 573 C 1 063 F 29 which creates strain and crystal defects in the quartz grains in a cooling body of granite 30 Mechanisms for silt production include 5 Erosion of initially silt sized grains from low grade metamorphic rock Production of silt sized grains from fracture of larger grains during initial rock weathering and soil formation 31 through processes such as frost shattering 32 and haloclasty 33 This produces silt particles whose size of 10 30 microns is determined by Moss defects 5 Production of silt sized grains from grain to grain impact during transport of coarser sediments Formation of authigenic quartz during weathering to clay Crystallization of the tests of siliceous organisms deposited in mudrock Laboratory experiments have produced contradictory results regarding the effectiveness of various silt production mechanisms This may be due to the use of vein or pegmatite quartz in some of the experiments Both materials form under conditions promoting ideal crystal growth and may lack the Moss defects of quartz grains in granites Thus production of silt from vein quartz is very difficult by any mechanism whereas production of silt from granite quartz proceeds readily by any of a number of mechanisms 5 However the main process is likely abrasion through transport including fluvial comminution aeolian attrition and glacial grinding 24 Because silt deposits such as loess a soil composed mostly of silt 34 seem to be associated with glaciated or mountainous regions in Asia and North America much emphasis has been placed on glacial grinding as a source of silt High Asia has been identified as a major generator of silt which accumulated to form the fertile soils of north India and Bangladesh and the loess of central Asia and north China 5 Loess has long been though to be absent or rare in deserts lacking nearby mountains Sahara Australia 35 However laboratory experiments show eolian and fluvial processes can be quite efficient at producing silt 24 as can weathering in tropical climates 36 Silt seems to be produced in great quantities in dust storms and silt deposits found Israel Tunisia Nigeria and Saudi Arabia cannot be attributed to glaciation Furthermore desert source areas in Asia may be more important for loess formation than previously thought Part of the problem may be the conflation of high rates of production with environments conducive to deposition and preservation which favors glacial climates more than deserts 37 Loess associated with glaciation and cold weathering may be distinguishable from loess associated with hot regions by the size distribution Glacial loess has a typical particle size of about 25 microns Desert loess contains either larger or smaller particles with the fine silt produced in dust storms and the coarse silt fraction possibly representing the fine particle tail of sand production 5 Human impact editLoess underlies some of the most productive agricultural land worldwide However it is very susceptible to erosion 5 The quartz particles in silt do not themselves provide nutrients but they promote excellent soil structure and silt sized particles of other minerals present in smaller amounts provide the necessary nutrients 16 Silt deposited by annual floods along the Nile River created the rich fertile soil that sustained the Ancient Egyptian civilization The closure of the Aswan High Dam has cut off this source of silt and the fertility of the Nile delta is deteriorating 38 Loess tends to lose strength when wetted and this can lead to failure of building foundations 5 The silty material has an open structure that collapses when wet 39 Quick clay a combination of very fine silt and clay sized particles from glacial grinding is a particular challenge for civil engineering 40 The failure of the Teton Dam has been attributed to the use of loess from the Snake River floodplain in the core of the dam 41 Loess lacks the necessary plasticity for use in a dam core but its properties were poorly understood even by the U S Bureau of Reclamation with its wealth of experience building earthen dams 5 Silt is susceptible to liquefaction during strong earthquakes due to its lack of plasticity This has raised concerns about the earthquake damage potential in the silty soil of the central United States in the event of a major earthquake in the New Madrid Seismic Zone 42 43 Environmental impacts edit nbsp A silted lake located in Eichhorst GermanySilt is easily transported in water 44 and is fine enough to be carried long distances by air in the form of dust 45 While the coarsest silt particles 60 micron settle out of a meter of still water in just five minutes the finest silt grains 2 microns can take several days to settle out of still water 46 When silt appears as a pollutant in water the phenomenon is known as siltation 47 Silt deposited by the Mississippi River throughout the 20th century has decreased due to a system of levees contributing to the disappearance of protective wetlands and barrier islands in the delta region surrounding New Orleans 48 In southeast Bangladesh in the Noakhali district cross dams were built in the 1960s whereby silt gradually started forming new land called chars The district of Noakhali has gained more than 73 square kilometres 28 sq mi of land in the past 50 years With Dutch funding the Bangladeshi government began to help develop older chars in the late 1970s and the effort has since become a multi agency operation building roads culverts embankments cyclone shelters toilets and ponds as well as distributing land to settlers By fall 2010 the program will have allotted some 100 square kilometres 20 000 acres to 21 000 families 49 A main source of silt in urban rivers is disturbance of soil by construction activity 50 A main source in rural rivers is erosion from plowing of farm fields 51 clearcutting or slash and burn treatment of forests 52 Culture editThe fertile black silt of the Nile river s banks is a symbol of rebirth associated with the Egyptian god Anubis 53 54 See also edit nbsp Wikimedia Commons has media related to Silt Aleurite Erosion control Nonpoint source pollution Sediment control Silt fenceReferences edit Assallay A Rogers C D F Smalley I J Jefferson I F November 1998 Silt 2 62 mm 9 4f Earth Science Reviews 45 1 2 61 88 Bibcode 1998ESRv 45 61A doi 10 1016 S0012 8252 98 00035 X Blatt Harvey Middleton Gerard Murray Raymond 1980 Origin of sedimentary rocks 2d ed Englewood Cliffs N J Prentice Hall p 381 ISBN 0136427103 Jackson Julia A ed 1997 silt sed Glossary of geology Fourth ed Alexandria Virginia American Geological Institute ISBN 0922152349 Potter Paul Edwin Maynard J Barry Pryor Wayne A 1980 Sedimentology of shale study guide and reference source New York Springer Verlag p 15 ISBN 0387904301 a b c d e f g h i j k l m n o p Assallay et al 1998 Potter Maynard amp Pryor 1980 p 13 a b Potter Maynard amp Pryor 1980 p 15 a b Jackson 1997 silt sed Tucker Maurice E 2011 Sedimentary rocks in the field a practical guide 4th ed Chichester West Sussex Wiley Blackwell p 160 ISBN 9780470689165 Blatt Middleton amp Murray 1980 p 63 Blatt Middleton amp Murray 1980 p 305 Blatt Middleton amp Murray 1980 pp 492 493 Jackson 1997 silt eng Jackson 1997 silt soil Particle Size 618 43 National Soil Survey Handbook Part 618 42 55 Soil Properties and Qualities Natural Resource Conservation Service Archived from the original on 2006 05 27 Retrieved 2006 05 31 a b Chesworth W 1982 Late Cenozoic geology and the second oldest profession Geoscience Canada 9 1 Retrieved 12 October 2021 Blatt Middleton amp Murray 1980 pp 73 374 381 Potter Maynard amp Pryor 1980 pp 108 109 Blatt Middleton amp Murray 1980 pp 381 382 Jackson 1997 rock flour Jackson 1997 rock milk Schubert C 1964 Size frequency distribution of sand sized grains in an abrasion mill Sedimentology 3 4 288 295 Bibcode 1964Sedim 3 288S doi 10 1111 j 1365 3091 1964 tb00643 x Rogers J J W Krueger W C Krog M 1963 Sizes of Naturally Abraded Materials SEPM Journal of Sedimentary Research 33 628 632 doi 10 1306 74D70ED9 2B21 11D7 8648000102C1865D a b c Wright J Smith B Whalley B May 1998 Mechanisms of loess sized quartz silt production and their relative effectiveness laboratory simulations Geomorphology 23 1 15 34 Bibcode 1998Geomo 23 15W doi 10 1016 S0169 555X 97 00084 6 Krinsley D H Smalley I J 22 June 1973 Shape and Nature of Small Sedimentary Quartz Particles Science 180 4092 1277 1279 Bibcode 1973Sci 180 1277K doi 10 1126 science 180 4092 1277 PMID 17759122 S2CID 11606901 Blatt H 1 March 1987 Perspectives Oxygen isotopes and the origin of quartz Journal of Sedimentary Research 57 2 373 377 Bibcode 1987JSedR 57 373B doi 10 1306 212F8B34 2B24 11D7 8648000102C1865D Rogers C F Smalley I J 1993 The shape of loess particles Naturwissenschaften 80 10 461 462 Bibcode 1993NW 80 461R doi 10 1007 BF01136036 S2CID 44606484 Moss A J Green Patricia 1975 Sand and silt grains Predetermination of their formation and properties by microfractures in quartz Journal of the Geological Society of Australia 22 4 485 495 Bibcode 1975AuJES 22 485M doi 10 1080 00167617508728913 Nesse William D 2000 Introduction to mineralogy New York Oxford University Press p 68 ISBN 9780195106916 Smalley I J 1966 Formation of quartz sand Nature 211 5048 476 479 Bibcode 1966Natur 211 476S doi 10 1038 211476a0 S2CID 4258725 Nahon D Trompette R February 1982 Origin of siltstones glacial grinding versus weathering Sedimentology 29 1 25 35 Bibcode 1982Sedim 29 25N doi 10 1111 j 1365 3091 1982 tb01706 x Lautridou J P Ozouf J C 19 August 2016 Experimental frost shattering Progress in Physical Geography 6 2 215 232 doi 10 1177 030913338200600202 S2CID 140197148 Goudie A S Watson A January 1984 Rock block monitoring of rapid salt weathering in southern Tunisia Earth Surface Processes and Landforms 9 1 95 98 Bibcode 1984ESPL 9 95G doi 10 1002 esp 3290090112 Frechen M 2011 Loess in Europe Guest Editorial E amp G Quaternary Science Journal 60 1 3 5 doi 10 3285 eg 60 1 00 Smalley Ian J Krinsley David H April 1978 Loess deposits associated with deserts CATENA 5 1 53 66 Bibcode 1978Caten 5 53S doi 10 1016 S0341 8162 78 80006 X Pye Kenneth April 1983 Formation of quartz silt during humid tropical weathering of dune sands Sedimentary Geology 34 4 267 282 Bibcode 1983SedG 34 267P doi 10 1016 0037 0738 83 90050 7 Wright Janet S February 2001 Desert loess versus glacial loess quartz silt formation source areas and sediment pathways in the formation of loess deposits Geomorphology 36 3 4 231 256 Bibcode 2001Geomo 36 231W doi 10 1016 S0169 555X 00 00060 X Stanley D J Warne A G 30 April 1993 Nile Delta Recent Geological Evolution and Human Impact Science 260 5108 628 634 Bibcode 1993Sci 260 628S doi 10 1126 science 260 5108 628 PMID 17812219 S2CID 31544176 Rogers C D F Dijkstra T A Smalley I J June 1994 Hydroconsolidation and subsidence of loess Studies from China Russia North America and Europe Engineering Geology 37 2 83 113 doi 10 1016 0013 7952 94 90045 0 Cabrera J G Smalley I J October 1973 Quickclays as products of glacial action a new approach to their nature geology distribution and geotechnical properties Engineering Geology 7 2 115 133 Bibcode 1973EngGe 7 115C doi 10 1016 0013 7952 73 90041 0 Smalley I J Dijkstra T A October 1991 The Teton Dam Idaho U S A failure problems with the use of loess material in earth dam structures Engineering Geology 31 2 197 203 Bibcode 1991EngGe 31 197S doi 10 1016 0013 7952 91 90006 7 Guo Tianqiang Prakash Shamsher August 1999 Liquefaction of Silts and Silt Clay Mixtures Journal of Geotechnical and Geoenvironmental Engineering 125 8 706 710 doi 10 1061 ASCE 1090 0241 1999 125 8 706 Omermeier S F Jacobson R B Smoot J P Weems R E Gohn G S Monroe J E Powars D S 1990 Earthquake induced liquefaction features in the coastal setting of South Carolina and in the fluvial setting of the New Madrid seismic zone U S Geological Survey Professional Paper Professional Paper 1504 doi 10 3133 pp1504 Chengrui Mei Dregne Harold E March 2001 Review article Silt and the future development of China s Yellow River The Geographical Journal 167 1 7 22 Bibcode 2001GeogJ 167 7C doi 10 1111 1475 4959 00002 Evans R D Jefferson I F Kumar R O Hara Dhand K Smalley I J May 2004 The nature and early history of airborne dust from North Africa in particular the Lake Chad basin Journal of African Earth Sciences 39 1 2 81 87 doi 10 1016 j jafrearsci 2004 06 001 Potter Maynard amp Pryor 1980 pp 8 9 Berkman Hilary E Rabeni Charles F December 1987 Effect of siltation on stream fish communities Environmental Biology of Fishes 18 4 285 294 Bibcode 1987EnvBF 18 285B doi 10 1007 BF00004881 S2CID 1616346 Mississippi River USGS Biological Resources Archived from the original on 2005 10 28 Retrieved 2006 03 08 Bangladesh fights for survival against climate change Archived from the original on February 12 2010 Retrieved October 22 2009 Leedy Daniel L Franklin Thomas M Maestro Robert M 1981 Planning for Urban Fishing and Waterfront Recreation U S Department of the Interior Fish and Wildlife Service Eastern Energy and Land Use Team Archived from the original on 2017 12 24 Grisseur D H Mubeteneh T C Aurore D 3 November 2014 Pollution and Siltation of Rivers in the Western Highlands of Cameroon a Consequence of Farmland Erosion by Runoff 21st Century Watershed Technology Conference and Workshop Improving Water Quality and the Environment 1 8 doi 10 13031 wtcw 2014 012 hdl 2268 173760 ISBN 9781940956268 Sanchez P A 26 October 2015 Alternatives to Slash and Burn Agriculture ASA Special Publications 33 39 doi 10 2134 asaspecpub56 c4 ISBN 9780891183228 Hart George 1986 A Dictionary of Egyptian Gods and Goddesses London Routledge amp Kegan Paul p 22 ISBN 978 0 415 34495 1 Freeman Charles 1997 The Legacy of Ancient Egypt New York Facts on File p 91 ISBN 978 0 816 03656 1 Retrieved from https en wikipedia org w index php title Silt amp oldid 1204006861, wikipedia, wiki, book, books, library,

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