{"id":241,"date":"2017-01-30T18:02:08","date_gmt":"2017-01-30T18:02:08","guid":{"rendered":"https:\/\/courses.lumenlearning.com\/physicalgeology\/?post_type=chapter&p=241"},"modified":"2017-01-30T18:02:08","modified_gmt":"2017-01-30T18:02:08","slug":"6-1-clastic-sedimentary-rocks","status":"publish","type":"chapter","link":"https:\/\/courses.lumenlearning.com\/suny-purchase-physicalgeology\/chapter\/6-1-clastic-sedimentary-rocks\/","title":{"raw":"6.1 Clastic Sedimentary Rocks","rendered":"6.1 Clastic Sedimentary Rocks"},"content":{"raw":"

A clast<\/strong> is a fragment of rock or mineral, ranging in size from less than a micron[footnote]A micron is a millionth of a metre. There are 1,000 microns in a millimetre.[\/footnote]\u00a0(too small to see) to as big as an apartment block. Various types of clasts are shown in Figure 5.12 and in Exercise 5.3. The smaller ones tend to be composed of a single mineral crystal, and the larger ones are typically composed of pieces of rock. As we\u2019ve seen in Chapter 5, most sand-sized clasts are made of quartz because quartz is more resistant to weathering than any other common mineral. Most clasts that are smaller than sand size (<1\/16 mm) are made of clay minerals. Most clasts larger than sand size (>2 mm) are actual fragments of rock, and commonly these might be fine-grained rock like basalt or andesite, or if they are bigger, coarse-grained rock like granite or gneiss.\n\nGrain-Size Classification<\/strong>\n\nGeologists that study sediments and sedimentary rocks use the Udden-Wentworth grain-size scale for describing the sizes of the grains in these materials (Table 6.1).\n<\/p>
Description<\/strong>\u00a0<\/strong><\/td>\nSize Range in mm<\/strong><\/td>\n<\/tr>
from<\/strong><\/td>\nto<\/strong><\/td>\n\n<\/tr>
Boulder<\/strong><\/td>\nlarge<\/td>\n1,024<\/td>\nno limit<\/td>\n<\/tr>
medium<\/td>\n512<\/td>\n1024<\/td>\n<\/tr>
small<\/td>\n256<\/td>\n512<\/td>\n<\/tr>
Cobble<\/strong>\u00a0<\/strong><\/td>\nlarge<\/td>\n128<\/td>\n256<\/td>\n<\/tr>
small<\/td>\n64<\/td>\n128<\/td>\n<\/tr>
Pebble\n<\/strong>(Granule)\u00a0<\/strong><\/td>\nvery coarse<\/td>\n32<\/td>\n64<\/td>\n<\/tr>
coarse<\/td>\n16<\/td>\n32<\/td>\n<\/tr>
medium<\/td>\n8<\/td>\n16<\/td>\n<\/tr>
fine<\/td>\n4<\/td>\n8<\/td>\n\u00a0Size in microns<\/strong><\/td>\n<\/tr>
very fine<\/td>\n2<\/td>\n4<\/td>\n\u00a0from<\/td>\n\u00a0to<\/td>\n<\/tr>
Sand<\/strong><\/td>\nvery coarse<\/td>\n\u00a01<\/td>\n2<\/td>\n1,000<\/td>\n2,000<\/td>\n<\/tr>
coarse<\/td>\n\u00a00.5<\/td>\n1<\/td>\n\u00a0500<\/td>\n1,000<\/td>\n<\/tr>
medium<\/td>\n\u00a00.25<\/td>\n0.5<\/td>\n\u00a0250<\/td>\n500<\/td>\n<\/tr>
fine<\/td>\n0.125<\/td>\n0.25<\/td>\n125<\/td>\n250<\/td>\n<\/tr>
very fine<\/td>\n\u00a00.063<\/td>\n0.125<\/td>\n\u00a063<\/td>\n125<\/td>\n<\/tr>
\u00a0Silt<\/strong><\/td>\n\u00a0very coarse<\/td>\n\n\n\u00a032<\/td>\n63<\/td>\n<\/tr>
\n\u00a0coarse<\/td>\n\n\n\u00a016<\/td>\n32<\/td>\n<\/tr>
\nmedium<\/td>\n\n\n\u00a08<\/td>\n16<\/td>\n<\/tr>
\n\u00a0fine<\/td>\n\n\n\u00a04<\/td>\n8<\/td>\n<\/tr>
\n\u00a0v. fine<\/td>\n\n\n\u00a02<\/td>\n4<\/td>\n<\/tr>
\u00a0Clay<\/strong><\/td>\n\u00a0clay<\/td>\n\n\n\u00a00<\/td>\n2<\/td>\n<\/tr><\/tbody><\/table>\nTable 6.1 The Udden-Wentworth grain-size scale for classifying sediments and the grains that make up sedimentary rocks\n\nThere are six main grain-size categories; five are broken down into subcategories, with clay<\/strong> being the exception. The diameter limits for each successive subcategory are twice as large as the one beneath it. In general, a boulder<\/strong> is bigger than a toaster and difficult to lift. There is no upper limit to the size of boulder.[footnote]The largest known free-standing rock (i.e., not part of bedrock) is Giant Rock in the Mojave Desert, California. It\u2019s about as big as an apartment building \u2014 seven storeys high![\/footnote]\u00a0A small cobble<\/strong> will fit in one hand, a large one in two hands. A pebble<\/strong> is something that you could throw quite easily. The smaller ones \u2014 known as granules <\/strong>\u2014 are gravel size, but still you could throw one. But you can\u2019t really throw a single grain of sand<\/strong>. Sand ranges from 2 mm down to 0.063 mm, and its key characteristic is that it feels \u201csandy\u201d or gritty between your fingers \u2014 even the finest sand grains feel that way. Silt<\/strong> is essentially too small for individual grains to be visible, and while sand feels sandy to your fingers, silt feels smooth to your fingers but gritty in your mouth. Clay is so fine that it feels smooth even in your mouth.\n
\n

Exercises<\/h3>\nExercise 6.1 Describe the Sediment on a Beach<\/strong>\n\nProviding that your landscape isn\u2019t covered in deep snow at present, visit a beach somewhere nearby \u2014 an ocean shore, a lakeshore, or a bar on a river \u2014 and look carefully at the size and shape of the beach sediments. Are they sand, pebbles, or cobbles? If they are not too fine, you should be able to tell if they are well rounded or more angular.\n\nThe beach in the image\u00a0is at Sechelt, B.C. Although there is a range of clast sizes, it\u2019s mostly made up of well-rounded cobbles, interspersed with pebbles. This beach is subject to strong wave activity, especially when winds blow across the Strait of Georgia from the south. That explains why the clasts are relatively large and are well rounded.\n\n\"sediment\"<\/a><\/strong>\n\n<\/div>\nIf you drop a granule into a glass of water, it will sink quickly to the bottom (less than half a second). If you drop a grain of sand into the same glass, it will sink more slowly (a second or two depending on the size). A grain of silt will take several seconds to get to the bottom, and a particle of fine clay may never get there. The rate of settling is determined by the balance between gravity and friction, as shown in Figure 6.3.\n\n[caption id=\"attachment_84\" align=\"aligncenter\" width=\"225\"]\"grain\"<\/a> Figure 6.3 The two forces operating on a grain of sand in water. Gravity is pushing it down, and the friction between the grain and the water is resisting that downward force. Large particles settle quickly because the gravitational force (which is proportional to the mass, and therefore to the volume of the particle) is much greater than the frictional force (which is proportional to the surface area of the particle). For small particles it is only slightly greater, so they settle slowly.[\/caption]\n\n
\n\nTransportation<\/strong>\n\nOne of the key principles of sedimentary geology is that the ability of a moving medium (air or water) to move sedimentary particles, and keep them moving, is dependent on the velocity of flow. The faster the medium flows, the larger the particles it can move. This is illustrated in Figure 6.4. Parts of the river are moving faster than other parts, especially where the slope is greatest and the channel is narrow. Not only does the velocity of a river change from place to place, but it changes from season to season.\n\nDuring peak discharge<\/strong>[footnote]Discharge of a stream is the volume of flow passing a point per unit time. It\u2019s normally measured in cubic metres per second (m3\/s).[\/footnote]\u00a0at this location, the water is high enough to flow over the embankment on the right, and it flows fast enough to move the boulders that cannot be moved during low flows.\n
\n\n[caption id=\"attachment_85\" align=\"aligncenter\" width=\"400\"]\"Figure<\/a> Figure 6.4 Variations in flow velocity on the Englishman River near Parksville, B.C. When the photo was taken the river was not flowing fast enough anywhere to move the boulders and cobbles visible here, but it is fast enough when the discharge is higher.[\/caption]\n\n<\/div>\n
\n\nClasts within streams are moved in several different ways, as illustrated in Figure 6.5. Large bedload<\/strong> clasts are pushed (by traction) or bounced along the bottom (saltation), while smaller clasts are suspended in the water and kept there by the turbulence of the flow. As the flow velocity changes, different-sized clasts may be either incorporated into the flow or deposited on the bottom. At various places along a river, there are always some clasts being deposited, some staying where they are, and some being eroded and transported. This changes over time as the discharge of the river changes in response to changing weather conditions.\n\nOther sediment transportation media, such as waves, ocean currents, and wind, operate under similar principles, with flow velocity as the key underlying factor that controls transportation and deposition.\n\n[caption id=\"attachment_86\" align=\"aligncenter\" width=\"400\"]\"Figure<\/a> Figure 6.5 Transportation of sediment clasts by stream flow. The larger clasts, resting on the bottom (bedload), are moved by traction (sliding) or by saltation (bouncing). Smaller clasts are kept in suspension by turbulence in the flow. Ions (depicted as + and - in the image, but invisible in real life) are dissolved in the water.[\/caption]\n\nClastic sediments are deposited in a wide range of environments, including glaciers, slope failures, rivers \u2014 both fast and slow, lakes, deltas, and ocean environments \u2014 both shallow and deep. Depending on the grain size in particular, they may eventually form into rocks ranging from fine mudstone to coarse breccia and conglomerate.\n\nLithification<\/strong> is the term used to describe a number of different processes that take place within a deposit of sediment to turn it into solid rock. One of these processes is burial by other sediments, which leads to compaction of the material and removal of some of the intervening water and air. After this stage, the individual clasts are all touching one another. Cementation<\/strong> is the process of crystallization of minerals within the pores between the small clasts, and also at the points of contact between the larger clasts (sand size and larger). Depending on the pressure, temperature, and chemical conditions, these crystals might include calcite, hematite, quartz, clay minerals, or a range of other minerals.\n\nThe characteristics and distinguishing features of clastic sedimentary rocks are summarized in Table 6.2. Mudrock<\/strong> is composed of at least 75% silt- and clay-sized fragments. If it is dominated by clay, it is called claystone<\/strong>. If it shows evidence of bedding or fine laminations, it is shale<\/strong>; otherwise it is mudstone. Mudrocks form in very low energy environments, such as lakes, river backwaters, and the deep ocean.\n
Group<\/th>\nExamples<\/th>\nCharacteristics<\/th>\n<\/tr><\/thead>
Mudrock<\/strong><\/td>\nmudstone<\/td>\n>75% silt and clay, not bedded<\/td>\n<\/tr>
shale<\/td>\n>75% silt and clay, thinly bedded<\/td>\n<\/tr>
Coal<\/strong><\/td>\n\ndominated by fragments of partially decayed plant matter, often enclosed between beds of sandstone or mudrock<\/td>\n<\/tr>
Sandstone<\/strong><\/td>\nquartz sandstone<\/td>\ndominated by sand, >90% quartz<\/td>\n<\/tr>
arkose<\/td>\ndominated by sand, >10% feldspar<\/td>\n<\/tr>
lithic wacke<\/td>\ndominated by sand, >10% rock fragments, >15% silt and clay<\/td>\n<\/tr>
Conglomerate<\/strong><\/td>\n\ndominated by rounded clasts, pebble size and larger<\/td>\n<\/tr>
Breccia<\/strong><\/td>\n\ndominated by angular clasts, pebble size and larger<\/td>\n<\/tr><\/tbody><\/table>
\n\nTable 6. 2 The main types of clastic sedimentary rocks and their characteristics.\n\nMost coal forms in fluvial or delta environments where vegetation growth is vigorous and where decaying plant matter accumulates in long-lasting swamps with low oxygen levels. To avoid oxidation and breakdown, the organic matter must remain submerged for centuries or millennia, until it is covered with another layer of either muddy or sandy sediments.\n\nIt is important to note that in some textbooks coal is described as an \u201corganic sedimentary rock.\u201d In this book, coal is classified with the clastic rocks for two reasons:\u00a0first, because it is made up of fragments of organic matter; and second, because coal seams (sedimentary layers) are almost always interbedded with layers of clastic rocks, such as mudrock or sandstone. In other words, coal accumulates in environments where other clastic rocks accumulate.\n\nIt\u2019s worth taking\u00a0a closer look at the different types of sandstone because sandstone is a common and important sedimentary rock. Typical sandstone compositions are shown in Figure 6.6. The term arenite<\/strong> applies to a so-called clean sandstone, meaning one with less than 15% silt and clay. Considering the sand-sized grains only, arenites with 90% or more quartz are called quartz arenites. If they have more than 10% feldspar and more feldspar than rock fragments, they are called feldspathic arenites or arkosic arenites<\/strong> (or just arkose<\/strong>). If they have more than 10% rock fragments, and more rock fragments than feldspar, they are lithic<\/strong>[footnote]\u201cLithic\u201d means \u201crock.\u201d Lithic clasts are rock fragments, as opposed to mineral fragments.[\/footnote]\u00a0arenites<\/strong>. A sandstone with more than 15% silt or clay is called a wacke <\/strong>(pronounced wackie<\/em>). The terms quartz wacke, lithic wacke<\/em>, and feldspathic wacke<\/em> are used. Another name for a lithic wacke is greywacke<\/strong>.\n\nSome examples of sandstones, magnified in thin section are shown in Figure 6.7. (A thin section is rock sliced thin enough so that light can shine through.)\n\nClastic sedimentary rocks in which a significant proportion of the clasts are larger than 2 mm are known as conglomerate<\/strong> if the clasts are well rounded, and breccia<\/strong> if they are angular. Conglomerates form in high-energy environments where the particles can become rounded, such as fast-flowing rivers. Breccias typically form where the particles are not transported a significant distance in water, such as alluvial fans and talus slopes. Some examples of clastic sedimentary rocks are shown on Figure 6.8.\n
\n\n[caption id=\"attachment_89\" align=\"aligncenter\" width=\"400\"]\"Figure<\/a> Figure 6.6 A compositional triangle for arenite sandstones, with the three most common components of sand-sized grains: quartz, feldspar, and rock fragments. Arenites have less than 15% silt or clay. Sandstones with more than 15% silt and clay are called wackes (e.g., quartz wacke, lithic wacke).[\/caption]\n\n[caption id=\"attachment_936\" align=\"aligncenter\" width=\"300\"]\"Figure<\/a> Figure 6.7 Photos of thin sections of three types of sandstone. Some of the minerals are labelled: Q=quartz, F=feldspar and L= lithic (rock fragments). The quartz arenite and arkose have relatively little silt-clay matrix, while the lithic wacke has abundant matrix.[\/caption]\n\n[caption id=\"attachment_937\" align=\"aligncenter\" width=\"296\"]\"Figure<\/a> Figure 6.8 Examples of various clastic sedimentary rocks.[\/caption]\n\n<\/div>\n
\n
\n

Exercises<\/h3>\n
\n\nExercise 6.2 Classifying Sandstones<\/strong>\n\nThe table below shows magnified thin sections of three sandstones, along with descriptions of their compositions. Using Table 6.1 and Figure 6.6, find an appropriate name for each of these rocks.\n\n<\/div>\n
\n
Magnified Thin Section<\/strong><\/td>\nDescription<\/strong><\/td>\nRock name?<\/strong><\/td>\n<\/tr>
\"thin-1\"<\/a><\/td>\nAngular sand-sized grains are approximately 85% quartz and 15% feldspar. Silt and clay make up less than 5% of the rock.<\/td>\n\u00a0<\/strong><\/td>\n<\/tr>
\"thin-2\"<\/a><\/td>\nRounded sand-sized grains are approximately 99% quartz and 1% feldspar. Silt and clay make up less than 2% of the rock.<\/td>\n\u00a0<\/strong><\/td>\n<\/tr>
\u00a0\"thin-3\"<\/a><\/td>\nAngular sand-sized grains are approximately 70% quartz, 20% lithic, and 10% feldspar. Silt and clay make up about 20% of the rock.<\/td>\n\u00a0<\/strong><\/td>\n<\/tr><\/tbody><\/table><\/div>\n<\/div>\n<\/div>\n
\n

Attributions<\/h3>\n
Aplite Red<\/a> by Rudolf Pohl is under CC BY-SA 3.0<\/a><\/div>\n<\/div>\n<\/div>\n<\/div>\n<\/div>","rendered":"

A clast<\/strong> is a fragment of rock or mineral, ranging in size from less than a micron[1]<\/sup><\/a>\u00a0(too small to see) to as big as an apartment block. Various types of clasts are shown in Figure 5.12 and in Exercise 5.3. The smaller ones tend to be composed of a single mineral crystal, and the larger ones are typically composed of pieces of rock. As we\u2019ve seen in Chapter 5, most sand-sized clasts are made of quartz because quartz is more resistant to weathering than any other common mineral. Most clasts that are smaller than sand size (<1\/16 mm) are made of clay minerals. Most clasts larger than sand size (>2 mm) are actual fragments of rock, and commonly these might be fine-grained rock like basalt or andesite, or if they are bigger, coarse-grained rock like granite or gneiss.<\/p>\n

Grain-Size Classification<\/strong><\/p>\n

Geologists that study sediments and sedimentary rocks use the Udden-Wentworth grain-size scale for describing the sizes of the grains in these materials (Table 6.1).\n<\/p>\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
Description<\/strong>\u00a0<\/strong><\/td>\nSize Range in mm<\/strong><\/td>\n<\/tr>\n
from<\/strong><\/td>\nto<\/strong><\/td>\n\n<\/td>\n<\/tr>\n
Boulder<\/strong><\/td>\nlarge<\/td>\n1,024<\/td>\nno limit<\/td>\n<\/tr>\n
medium<\/td>\n512<\/td>\n1024<\/td>\n<\/tr>\n
small<\/td>\n256<\/td>\n512<\/td>\n<\/tr>\n
Cobble<\/strong>\u00a0<\/strong><\/td>\nlarge<\/td>\n128<\/td>\n256<\/td>\n<\/tr>\n
small<\/td>\n64<\/td>\n128<\/td>\n<\/tr>\n
Pebble
\n<\/strong>(Granule)\u00a0<\/strong><\/td>\n		very coarse<\/td>\n32<\/td>\n64<\/td>\n<\/tr>\n
coarse<\/td>\n16<\/td>\n32<\/td>\n<\/tr>\n
medium<\/td>\n8<\/td>\n16<\/td>\n<\/tr>\n
fine<\/td>\n4<\/td>\n8<\/td>\n\u00a0Size in microns<\/strong><\/td>\n<\/tr>\n
very fine<\/td>\n2<\/td>\n4<\/td>\n\u00a0from<\/td>\n\u00a0to<\/td>\n<\/tr>\n
Sand<\/strong><\/td>\nvery coarse<\/td>\n\u00a01<\/td>\n2<\/td>\n1,000<\/td>\n2,000<\/td>\n<\/tr>\n
coarse<\/td>\n\u00a00.5<\/td>\n1<\/td>\n\u00a0500<\/td>\n1,000<\/td>\n<\/tr>\n
medium<\/td>\n\u00a00.25<\/td>\n0.5<\/td>\n\u00a0250<\/td>\n500<\/td>\n<\/tr>\n
fine<\/td>\n0.125<\/td>\n0.25<\/td>\n125<\/td>\n250<\/td>\n<\/tr>\n
very fine<\/td>\n\u00a00.063<\/td>\n0.125<\/td>\n\u00a063<\/td>\n125<\/td>\n<\/tr>\n
\u00a0Silt<\/strong><\/td>\n\u00a0very coarse<\/td>\n\n<\/td>\n\n<\/td>\n\u00a032<\/td>\n63<\/td>\n<\/tr>\n
\n<\/td>\n\u00a0coarse<\/td>\n\n<\/td>\n\n<\/td>\n\u00a016<\/td>\n32<\/td>\n<\/tr>\n
\n<\/td>\nmedium<\/td>\n\n<\/td>\n\n<\/td>\n\u00a08<\/td>\n16<\/td>\n<\/tr>\n
\n<\/td>\n\u00a0fine<\/td>\n\n<\/td>\n\n<\/td>\n\u00a04<\/td>\n8<\/td>\n<\/tr>\n
\n<\/td>\n\u00a0v. fine<\/td>\n\n<\/td>\n\n<\/td>\n\u00a02<\/td>\n4<\/td>\n<\/tr>\n
\u00a0Clay<\/strong><\/td>\n\u00a0clay<\/td>\n\n<\/td>\n\n<\/td>\n\u00a00<\/td>\n2<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Table 6.1 The Udden-Wentworth grain-size scale for classifying sediments and the grains that make up sedimentary rocks<\/p>\n

There are six main grain-size categories; five are broken down into subcategories, with clay<\/strong> being the exception. The diameter limits for each successive subcategory are twice as large as the one beneath it. In general, a boulder<\/strong> is bigger than a toaster and difficult to lift. There is no upper limit to the size of boulder.[2]<\/sup><\/a>\u00a0A small cobble<\/strong> will fit in one hand, a large one in two hands. A pebble<\/strong> is something that you could throw quite easily. The smaller ones \u2014 known as granules <\/strong>\u2014 are gravel size, but still you could throw one. But you can\u2019t really throw a single grain of sand<\/strong>. Sand ranges from 2 mm down to 0.063 mm, and its key characteristic is that it feels \u201csandy\u201d or gritty between your fingers \u2014 even the finest sand grains feel that way. Silt<\/strong> is essentially too small for individual grains to be visible, and while sand feels sandy to your fingers, silt feels smooth to your fingers but gritty in your mouth. Clay is so fine that it feels smooth even in your mouth.<\/p>\n

\n

Exercises<\/h3>\n

Exercise 6.1 Describe the Sediment on a Beach<\/strong><\/p>\n

Providing that your landscape isn\u2019t covered in deep snow at present, visit a beach somewhere nearby \u2014 an ocean shore, a lakeshore, or a bar on a river \u2014 and look carefully at the size and shape of the beach sediments. Are they sand, pebbles, or cobbles? If they are not too fine, you should be able to tell if they are well rounded or more angular.<\/p>\n

The beach in the image\u00a0is at Sechelt, B.C. Although there is a range of clast sizes, it\u2019s mostly made up of well-rounded cobbles, interspersed with pebbles. This beach is subject to strong wave activity, especially when winds blow across the Strait of Georgia from the south. That explains why the clasts are relatively large and are well rounded.<\/p>\n

\"sediment\"<\/a><\/strong><\/p>\n<\/div>\n

If you drop a granule into a glass of water, it will sink quickly to the bottom (less than half a second). If you drop a grain of sand into the same glass, it will sink more slowly (a second or two depending on the size). A grain of silt will take several seconds to get to the bottom, and a particle of fine clay may never get there. The rate of settling is determined by the balance between gravity and friction, as shown in Figure 6.3.<\/p>\n

\"grain\"<\/a><\/p>\n

Figure 6.3 The two forces operating on a grain of sand in water. Gravity is pushing it down, and the friction between the grain and the water is resisting that downward force. Large particles settle quickly because the gravitational force (which is proportional to the mass, and therefore to the volume of the particle) is much greater than the frictional force (which is proportional to the surface area of the particle). For small particles it is only slightly greater, so they settle slowly.<\/p>\n<\/div>\n

\n

Transportation<\/strong><\/p>\n

One of the key principles of sedimentary geology is that the ability of a moving medium (air or water) to move sedimentary particles, and keep them moving, is dependent on the velocity of flow. The faster the medium flows, the larger the particles it can move. This is illustrated in Figure 6.4. Parts of the river are moving faster than other parts, especially where the slope is greatest and the channel is narrow. Not only does the velocity of a river change from place to place, but it changes from season to season.<\/p>\n

During peak discharge<\/strong>[3]<\/sup><\/a>\u00a0at this location, the water is high enough to flow over the embankment on the right, and it flows fast enough to move the boulders that cannot be moved during low flows.<\/p>\n

\n
\"Figure<\/a><\/p>\n

Figure 6.4 Variations in flow velocity on the Englishman River near Parksville, B.C. When the photo was taken the river was not flowing fast enough anywhere to move the boulders and cobbles visible here, but it is fast enough when the discharge is higher.<\/p>\n<\/div>\n<\/div>\n

\n

Clasts within streams are moved in several different ways, as illustrated in Figure 6.5. Large bedload<\/strong> clasts are pushed (by traction) or bounced along the bottom (saltation), while smaller clasts are suspended in the water and kept there by the turbulence of the flow. As the flow velocity changes, different-sized clasts may be either incorporated into the flow or deposited on the bottom. At various places along a river, there are always some clasts being deposited, some staying where they are, and some being eroded and transported. This changes over time as the discharge of the river changes in response to changing weather conditions.<\/p>\n

Other sediment transportation media, such as waves, ocean currents, and wind, operate under similar principles, with flow velocity as the key underlying factor that controls transportation and deposition.<\/p>\n

\"Figure<\/a><\/p>\n

Figure 6.5 Transportation of sediment clasts by stream flow. The larger clasts, resting on the bottom (bedload), are moved by traction (sliding) or by saltation (bouncing). Smaller clasts are kept in suspension by turbulence in the flow. Ions (depicted as + and – in the image, but invisible in real life) are dissolved in the water.<\/p>\n<\/div>\n

Clastic sediments are deposited in a wide range of environments, including glaciers, slope failures, rivers \u2014 both fast and slow, lakes, deltas, and ocean environments \u2014 both shallow and deep. Depending on the grain size in particular, they may eventually form into rocks ranging from fine mudstone to coarse breccia and conglomerate.<\/p>\n

Lithification<\/strong> is the term used to describe a number of different processes that take place within a deposit of sediment to turn it into solid rock. One of these processes is burial by other sediments, which leads to compaction of the material and removal of some of the intervening water and air. After this stage, the individual clasts are all touching one another. Cementation<\/strong> is the process of crystallization of minerals within the pores between the small clasts, and also at the points of contact between the larger clasts (sand size and larger). Depending on the pressure, temperature, and chemical conditions, these crystals might include calcite, hematite, quartz, clay minerals, or a range of other minerals.<\/p>\n

The characteristics and distinguishing features of clastic sedimentary rocks are summarized in Table 6.2. Mudrock<\/strong> is composed of at least 75% silt- and clay-sized fragments. If it is dominated by clay, it is called claystone<\/strong>. If it shows evidence of bedding or fine laminations, it is shale<\/strong>; otherwise it is mudstone. Mudrocks form in very low energy environments, such as lakes, river backwaters, and the deep ocean.<\/p>\n\n\n\n\n\n\n\n\n\n\n\n\n
Group<\/th>\nExamples<\/th>\nCharacteristics<\/th>\n<\/tr>\n<\/thead>\n
Mudrock<\/strong><\/td>\nmudstone<\/td>\n>75% silt and clay, not bedded<\/td>\n<\/tr>\n
shale<\/td>\n>75% silt and clay, thinly bedded<\/td>\n<\/tr>\n
Coal<\/strong><\/td>\n\n<\/td>\ndominated by fragments of partially decayed plant matter, often enclosed between beds of sandstone or mudrock<\/td>\n<\/tr>\n
Sandstone<\/strong><\/td>\nquartz sandstone<\/td>\ndominated by sand, >90% quartz<\/td>\n<\/tr>\n
arkose<\/td>\ndominated by sand, >10% feldspar<\/td>\n<\/tr>\n
lithic wacke<\/td>\ndominated by sand, >10% rock fragments, >15% silt and clay<\/td>\n<\/tr>\n
Conglomerate<\/strong><\/td>\n\n<\/td>\ndominated by rounded clasts, pebble size and larger<\/td>\n<\/tr>\n
Breccia<\/strong><\/td>\n\n<\/td>\ndominated by angular clasts, pebble size and larger<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n
\n

Table 6. 2 The main types of clastic sedimentary rocks and their characteristics.<\/p>\n

Most coal forms in fluvial or delta environments where vegetation growth is vigorous and where decaying plant matter accumulates in long-lasting swamps with low oxygen levels. To avoid oxidation and breakdown, the organic matter must remain submerged for centuries or millennia, until it is covered with another layer of either muddy or sandy sediments.<\/p>\n

It is important to note that in some textbooks coal is described as an \u201corganic sedimentary rock.\u201d In this book, coal is classified with the clastic rocks for two reasons:\u00a0first, because it is made up of fragments of organic matter; and second, because coal seams (sedimentary layers) are almost always interbedded with layers of clastic rocks, such as mudrock or sandstone. In other words, coal accumulates in environments where other clastic rocks accumulate.<\/p>\n

It\u2019s worth taking\u00a0a closer look at the different types of sandstone because sandstone is a common and important sedimentary rock. Typical sandstone compositions are shown in Figure 6.6. The term arenite<\/strong> applies to a so-called clean sandstone, meaning one with less than 15% silt and clay. Considering the sand-sized grains only, arenites with 90% or more quartz are called quartz arenites. If they have more than 10% feldspar and more feldspar than rock fragments, they are called feldspathic arenites or arkosic arenites<\/strong> (or just arkose<\/strong>). If they have more than 10% rock fragments, and more rock fragments than feldspar, they are lithic<\/strong>[4]<\/sup><\/a>\u00a0arenites<\/strong>. A sandstone with more than 15% silt or clay is called a wacke <\/strong>(pronounced wackie<\/em>). The terms quartz wacke, lithic wacke<\/em>, and feldspathic wacke<\/em> are used. Another name for a lithic wacke is greywacke<\/strong>.<\/p>\n

Some examples of sandstones, magnified in thin section are shown in Figure 6.7. (A thin section is rock sliced thin enough so that light can shine through.)<\/p>\n

Clastic sedimentary rocks in which a significant proportion of the clasts are larger than 2 mm are known as conglomerate<\/strong> if the clasts are well rounded, and breccia<\/strong> if they are angular. Conglomerates form in high-energy environments where the particles can become rounded, such as fast-flowing rivers. Breccias typically form where the particles are not transported a significant distance in water, such as alluvial fans and talus slopes. Some examples of clastic sedimentary rocks are shown on Figure 6.8.<\/p>\n

\n
\"Figure<\/a><\/p>\n

Figure 6.6 A compositional triangle for arenite sandstones, with the three most common components of sand-sized grains: quartz, feldspar, and rock fragments. Arenites have less than 15% silt or clay. Sandstones with more than 15% silt and clay are called wackes (e.g., quartz wacke, lithic wacke).<\/p>\n<\/div>\n

\"Figure<\/a><\/p>\n

Figure 6.7 Photos of thin sections of three types of sandstone. Some of the minerals are labelled: Q=quartz, F=feldspar and L= lithic (rock fragments). The quartz arenite and arkose have relatively little silt-clay matrix, while the lithic wacke has abundant matrix.<\/p>\n<\/div>\n

\"Figure<\/a><\/p>\n

Figure 6.8 Examples of various clastic sedimentary rocks.<\/p>\n<\/div>\n<\/div>\n

\n
\n

Exercises<\/h3>\n
\n

Exercise 6.2 Classifying Sandstones<\/strong><\/p>\n

The table below shows magnified thin sections of three sandstones, along with descriptions of their compositions. Using Table 6.1 and Figure 6.6, find an appropriate name for each of these rocks.<\/p>\n<\/div>\n

\n\n\n\n\n\n\n
Magnified Thin Section<\/strong><\/td>\nDescription<\/strong><\/td>\nRock name?<\/strong><\/td>\n<\/tr>\n
\"thin-1\"<\/a><\/td>\nAngular sand-sized grains are approximately 85% quartz and 15% feldspar. Silt and clay make up less than 5% of the rock.<\/td>\n\u00a0<\/strong><\/td>\n<\/tr>\n
\"thin-2\"<\/a><\/td>\nRounded sand-sized grains are approximately 99% quartz and 1% feldspar. Silt and clay make up less than 2% of the rock.<\/td>\n\u00a0<\/strong><\/td>\n<\/tr>\n
\u00a0\"thin-3\"<\/a><\/td>\nAngular sand-sized grains are approximately 70% quartz, 20% lithic, and 10% feldspar. Silt and clay make up about 20% of the rock.<\/td>\n\u00a0<\/strong><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n<\/div>\n<\/div>\n
\n

Attributions<\/h3>\n
Aplite Red<\/a> by Rudolf Pohl is under CC BY-SA 3.0<\/a><\/div>\n<\/div>\n<\/div>\n<\/div>\n<\/div>\n\n\t\t\t
\n\t\t\t

Candela Citations<\/h3>\n\t\t\t\t\t
\n\t\t\t\t\t\t
\n\t\t\t\t\t\t\t
CC licensed content, Shared previously<\/div>