{"id":551,"date":"2018-02-23T19:54:56","date_gmt":"2018-02-24T00:54:56","guid":{"rendered":"https:\/\/opentextbc.ca\/physicalgeologyh5p\/chapter\/13-3-fractures-faults-and-joints-2\/"},"modified":"2023-06-07T14:26:44","modified_gmt":"2023-06-07T18:26:44","slug":"fractures-joints-and-faults","status":"publish","type":"chapter","link":"https:\/\/opentextbc.ca\/physicalgeologyh5p\/chapter\/fractures-joints-and-faults\/","title":{"raw":"13.3 Fractures, Joints, and Faults","rendered":"13.3 Fractures, Joints, and Faults"},"content":{"raw":"When rocks break in response to stress, the resulting break is called a\u00a0fracture<\/strong>. If rocks on one side of the break shift relative to rocks on the other side, then the fracture is a fault<\/strong>. If there is no movement of one side relative to the other, and if there are many other fractures with the same orientation, then the fractures are called joints<\/strong>. Joints with a common orientation make up a joint set<\/strong> (Figure 13.19).\r\n\r\n[caption id=\"attachment_539\" align=\"aligncenter\" width=\"550\"]\"\" Figure 13.19<\/strong> Joint sets have broken these siltstone and shale beds into long rectangular planks. Source: Michael C. Rygel (2008), CC BY-SA 3.0. Image source.<\/a>[\/caption]\r\n

Jointing<\/h1>\r\nMost joints form when the overall stress regime is one of tension (pulling apart) rather than compression. The tension can be from a rock contracting, such as during the cooling of volcanic rock (Figure 13.9, upper left). It can also be from a body of rock expanding. Exfoliation<\/strong> joints<\/strong>, which make the rock appear to be flaking off in sheets (Figure 13.20), occur when a body of rock expands in response to reduced pressure, such as when overlying rocks have been removed by erosion.\r\n\r\n[caption id=\"attachment_540\" align=\"aligncenter\" width=\"550\"]\"\" Figure 13.20<\/strong> Half Dome at Yosemite National Park is an exposed granite batholith that displays exfoliation joints, causing sheets of rock to break off. Source: HylgeriaK (2010), CC BY-SA 3.0. Image source.<\/a>[\/caption]\r\n\r\nNevertheless, it is possible for joints to develop where the overall regime is one of compression. Joints can develop where rocks are being folded, because the hinge zone of the fold is under tension as it stretches to accommodate the bending (Figure 13.21).\r\n\r\n[caption id=\"attachment_541\" align=\"aligncenter\" width=\"371\"]\"\" Figure 13.21<\/strong> Joints developed in the hinge zone of folded rocks. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a>[\/caption]\r\n\r\nJoints can also develop in a rock a rock under compression as a way to accommodate the change in shape (Figure 13.22).\u00a0 The joints accommodate the larger compression stress\u00a0 (larger red arrows) by allowing the rock to stretch in the up-down direction (along the green arrows).\r\n\r\n[caption id=\"attachment_542\" align=\"aligncenter\" width=\"369\"]\"\" Figure 13.22<\/strong> Joints developing to accommodate the larger horizontal component of compression (large red arrows). Source: Steven Earle, CC BY 4.0. Image source.<\/a>[\/caption]\r\n

Faulting<\/h1>\r\nA fault is a boundary between two bodies of rock along which there has been relative motion (e.g., Figure 13.23). Some large faults, like the San Andreas fault in California or the Tintina fault, extending from northern British Columbia through central Yukon and into Alaska, show evidence of hundreds of kilometres of motion. Other faults show only centimetres of movement.\u00a0In order to estimate the amount of motion on a fault, it is necessary to find a feature that shows up on both sides of the fault, and has been offset by the fault. This could be the edge of a bed or dike as in Figure 13.23, or it could be a landscape feature, such as a fence or a stream.\r\n\r\n[caption id=\"attachment_543\" align=\"aligncenter\" width=\"550\"]\"\" Figure 13.23<\/strong> View looking down on a fault (white dashed line) in intrusive rocks on Quadra Island, British Columbia. The pink dyke has been offset approximately 10 cm by the fault (length of the white arrow). Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a>[\/caption]\r\n

Types of Faults<\/h2>\r\nDifferent kinds of faults develop under different stress conditions. We describe faults in terms of how the rocks on one side of the fault move relative to the other.\r\n

Dip-Slip Faults<\/h3>\r\nDip-slip faults<\/strong> are so named because the dominant motion involves moving up or down the dipping (tilting) fault plane. In dip-slip faults we identify rock above the fault as the hanging wall<\/strong>, (or headwall<\/strong>) and the rock beneath as the footwall<\/strong>. These terms were originally used by miners to describe the rocks above and below an ore body (Figure 13.24).\r\n\r\n[caption id=\"attachment_544\" align=\"aligncenter\" width=\"650\"]\"\" Figure 13.24<\/strong> The hanging wall (or headwall) of a fault is the rock above the fault. The footwall is the rock below. These terms were originally used by miners to describe the rocks above and below an ore body. Source: Photo- Gold Hill Mine, Yukon Territory, by Eric A. Hegg (1898), Public Domain.\u00a0 Image source.<\/a>. Diagram- Karla Panchuk (2018) CC BY 4.0.[\/caption]\r\n\r\nTension produces normal faults<\/strong>, in which the crust undergoes extension. This permits the hanging wall to slide down the footwall in response to gravity (Figure 13.25, left). Compression produces reverse faults<\/strong>, pushing the hanging wall up relative to the footwall. Reverse faults shorten and thicken the crust (Figure 13.25, right).\r\n

Strike-Slip Faults<\/h3>\r\nFaults where the motion is mostly horizontal and along the \u201cstrike\u201d or the length of the fault are called strike-slip faults<\/strong> (Figure 13.26 bottom). These happen where shear stress causes bodies of rock to slide sideways with respect to each other, as is the case along a transform boundary. If the far side moves to the right, as in Figures 13.23 and 13.26 (right), it is a right-handed<\/strong>, right-lateral<\/strong>,or dextral <\/strong>strike-slip fault. If the far side moves to the left it is a left-handed<\/strong>, left-lateral<\/strong>, or sinistral<\/strong> strike-slip fault.\r\n\r\n[caption id=\"attachment_545\" align=\"aligncenter\" width=\"650\"]\"\" Figure 13.25<\/strong> Dip slip faults. Normal faults are caused by tension, while reverse faults happen during compression. Source: Karla Panchuk (2018), CC BY-SA 4.0. Modifed after Woudloper (2010), CC BY-SA 3.0. Image source.<\/a>[\/caption]\r\n\r\n[caption id=\"attachment_546\" align=\"aligncenter\" width=\"562\"]\"\" Figure 13.26<\/strong> Strike-slip faults. Rocks on either side of the fault move parallel to the fault. In dextral strike-slip faults the far side moves to the right of the observer. In sinistral strike-slip faults the far side moves to the left of the observer. Source: Karla Panchuk (2018), CC BY 4.0.[\/caption]\r\n

Different Tectonic Settings Have Distinct Types of Faults<\/h2>\r\n

Horst and Graben Structure<\/h3>\r\nIn areas that are characterized by extensional tectonics, and with many normal faults arranged side-by-side, some blocks may subside (settle downward) relative to neighbouring parts. This is typical in areas of continental rifting, such as the Great Rift Valley of East Africa or in parts of Iceland. In such situations, blocks that move down relative to the other blocks are graben<\/strong>, and elevated blocks with graben on either side are called horsts<\/strong>. There are many horsts and graben in the Basin and Range area of the western United States, especially in Nevada. Part of the Fraser Valley region of British Columbia, in the area around Sumas Prairie, is a graben.\r\n\r\n[caption id=\"attachment_547\" align=\"aligncenter\" width=\"650\"]\"Figure Figure 13.27\u00a0<\/strong> Graben and horst structures form where extension is happening. All of the faults are normal faults. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a>[\/caption]\r\n

Thrust Faults<\/h3>\r\nThrust faults are a type of reverse fault with a very low-angle fault plane. The fault planes of thrust faults typically slope at less than 30\u00b0. Thrust faults are relatively common in mountain belts that were created by continent-continent collisions.\u00a0Some represent tens of kilometres of thrusting, where thick sheets of sedimentary rock have been pushed up and over other layers of rock (Figure 13.28).\r\n\r\n[caption id=\"attachment_548\" align=\"aligncenter\" width=\"550\"]\"Figure Figure 13.28<\/strong> A thrust fault. Top: prior to faulting. Bottom: after significant fault offset. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a>[\/caption]There are numerous thrust faults in the Rocky Mountains, and a well-known example is the McConnell Thrust, along which a sequence of sedimentary rocks about 800 m thick has been pushed for about 40 km from west to east over underlying rock (Figure 13.29).\u00a0The thrusted rocks range in age from Cambrian to Cretaceous, so in the area around Mt. Yamnuska Cambrian-aged rock (around 500 Ma) has been thrust over, and now lies on top of Cretaceous-aged rock (around 75 Ma) (Figure 13.30).\r\n\r\n[caption id=\"attachment_549\" align=\"aligncenter\" width=\"581\"]\"Figure Figure 13.29<\/strong>\u00a0 The McConnell Thrust in the eastern part of the Rockies. The rock within the faded area has been eroded. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a>[\/caption]\r\n\r\n[caption id=\"attachment_550\" align=\"aligncenter\" width=\"569\"]\"\" Figure 13.30<\/strong> The McConnell Thrust at Mt. Yamnuska near Exshaw, Alberta. Cambrian limestones have been thrust over top of Cretaceous mudstone. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a>[\/caption]\r\n\r\n
\r\n\r\n<\/a>Practice with Types of Faults<\/strong>\r\n
What kind of dip-slip fault is this?<\/strong>\"\"\r\n\r\nThe hanging wall went\u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0<\/span> relative to the footwall. (Hint: Up or down?)\r\n\r\n\"\"\r\n\r\nThat makes this a \u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0\u00a0\u00a0<\/span> fault (Hint: Normal, reverse, thrust, or strike-slip?), caused by \u00a0\u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0<\/span> stress. (Hint: Tension, compression, or shear?)\r\n\r\n\"\"\r\n\r\nWhat kind of dip-slip fault is this?<\/strong>\r\n\r\n\"\"\r\n\r\nThe hanging wall went\u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0<\/span> relative to the footwall. (Hint: Up or down?)\r\n\r\n\"\"\r\n\r\nThe fault cuts the beds at a \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> angle. (Hint: High or low?) This makes it a \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> fault (Hint: Normal, reverse, thrust, or strike-slip?), caused by \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> stress. (Hint: Tension, compression, or shear?)\r\n\r\n\"\"\r\n\r\nWhat kind of faults are these?<\/strong>\r\n\r\n\"\"\r\n\r\nThe hanging wall goes \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> relative to the footwall when each fault is considered individually. (Hint: Up or down?)\r\n\r\n\"\"\r\n\r\nThat makes this\u00a0 \u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0\u00a0 \u00a0\u00a0\u00a0\u00a0 <\/span>-slip fault (Hint: Strike or dip?) a \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> fault. (Hint: Normal, reverse, or thrust?)\r\n\r\n\"\"\r\n\r\nWhat kind of fault is this?<\/strong>\r\n\r\n\"\"\r\n\r\nThis is a\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 <\/span>-slip fault (Hint: Strike or dip?), formed from \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> stress. (Hint: Tension, compression, or shear?)\r\n\r\nFrom the perspective of the photographer, the beds on the opposite side of the fault are shifted to the\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 <\/span>. (Hint: Left or right?) This makes this fault \u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0 <\/span>. (Hint: Sinistral or dextral?)\r\n\r\n\"\"\r\n\r\nTo check your answers, navigate to the below link to view the interactive version of this activity.\r\n\r\n<\/div>\r\n[h5p id=\"157\"]\r\n\r\n<\/div>","rendered":"

When rocks break in response to stress, the resulting break is called a\u00a0fracture<\/strong>. If rocks on one side of the break shift relative to rocks on the other side, then the fracture is a fault<\/strong>. If there is no movement of one side relative to the other, and if there are many other fractures with the same orientation, then the fractures are called joints<\/strong>. Joints with a common orientation make up a joint set<\/strong> (Figure 13.19).<\/p>\n

\"\"
Figure 13.19<\/strong> Joint sets have broken these siltstone and shale beds into long rectangular planks. Source: Michael C. Rygel (2008), CC BY-SA 3.0. Image source.<\/a><\/figcaption><\/figure>\n

Jointing<\/h1>\n

Most joints form when the overall stress regime is one of tension (pulling apart) rather than compression. The tension can be from a rock contracting, such as during the cooling of volcanic rock (Figure 13.9, upper left). It can also be from a body of rock expanding. Exfoliation<\/strong> joints<\/strong>, which make the rock appear to be flaking off in sheets (Figure 13.20), occur when a body of rock expands in response to reduced pressure, such as when overlying rocks have been removed by erosion.<\/p>\n

\"\"
Figure 13.20<\/strong> Half Dome at Yosemite National Park is an exposed granite batholith that displays exfoliation joints, causing sheets of rock to break off. Source: HylgeriaK (2010), CC BY-SA 3.0. Image source.<\/a><\/figcaption><\/figure>\n

Nevertheless, it is possible for joints to develop where the overall regime is one of compression. Joints can develop where rocks are being folded, because the hinge zone of the fold is under tension as it stretches to accommodate the bending (Figure 13.21).<\/p>\n

\"\"
Figure 13.21<\/strong> Joints developed in the hinge zone of folded rocks. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n

Joints can also develop in a rock a rock under compression as a way to accommodate the change in shape (Figure 13.22).\u00a0 The joints accommodate the larger compression stress\u00a0 (larger red arrows) by allowing the rock to stretch in the up-down direction (along the green arrows).<\/p>\n

\"\"
Figure 13.22<\/strong> Joints developing to accommodate the larger horizontal component of compression (large red arrows). Source: Steven Earle, CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n

Faulting<\/h1>\n

A fault is a boundary between two bodies of rock along which there has been relative motion (e.g., Figure 13.23). Some large faults, like the San Andreas fault in California or the Tintina fault, extending from northern British Columbia through central Yukon and into Alaska, show evidence of hundreds of kilometres of motion. Other faults show only centimetres of movement.\u00a0In order to estimate the amount of motion on a fault, it is necessary to find a feature that shows up on both sides of the fault, and has been offset by the fault. This could be the edge of a bed or dike as in Figure 13.23, or it could be a landscape feature, such as a fence or a stream.<\/p>\n

\"\"
Figure 13.23<\/strong> View looking down on a fault (white dashed line) in intrusive rocks on Quadra Island, British Columbia. The pink dyke has been offset approximately 10 cm by the fault (length of the white arrow). Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n

Types of Faults<\/h2>\n

Different kinds of faults develop under different stress conditions. We describe faults in terms of how the rocks on one side of the fault move relative to the other.<\/p>\n

Dip-Slip Faults<\/h3>\n

Dip-slip faults<\/strong> are so named because the dominant motion involves moving up or down the dipping (tilting) fault plane. In dip-slip faults we identify rock above the fault as the hanging wall<\/strong>, (or headwall<\/strong>) and the rock beneath as the footwall<\/strong>. These terms were originally used by miners to describe the rocks above and below an ore body (Figure 13.24).<\/p>\n

\"\"
Figure 13.24<\/strong> The hanging wall (or headwall) of a fault is the rock above the fault. The footwall is the rock below. These terms were originally used by miners to describe the rocks above and below an ore body. Source: Photo- Gold Hill Mine, Yukon Territory, by Eric A. Hegg (1898), Public Domain.\u00a0 Image source.<\/a>. Diagram- Karla Panchuk (2018) CC BY 4.0.<\/figcaption><\/figure>\n

Tension produces normal faults<\/strong>, in which the crust undergoes extension. This permits the hanging wall to slide down the footwall in response to gravity (Figure 13.25, left). Compression produces reverse faults<\/strong>, pushing the hanging wall up relative to the footwall. Reverse faults shorten and thicken the crust (Figure 13.25, right).<\/p>\n

Strike-Slip Faults<\/h3>\n

Faults where the motion is mostly horizontal and along the \u201cstrike\u201d or the length of the fault are called strike-slip faults<\/strong> (Figure 13.26 bottom). These happen where shear stress causes bodies of rock to slide sideways with respect to each other, as is the case along a transform boundary. If the far side moves to the right, as in Figures 13.23 and 13.26 (right), it is a right-handed<\/strong>, right-lateral<\/strong>,or dextral <\/strong>strike-slip fault. If the far side moves to the left it is a left-handed<\/strong>, left-lateral<\/strong>, or sinistral<\/strong> strike-slip fault.<\/p>\n

\"\"
Figure 13.25<\/strong> Dip slip faults. Normal faults are caused by tension, while reverse faults happen during compression. Source: Karla Panchuk (2018), CC BY-SA 4.0. Modifed after Woudloper (2010), CC BY-SA 3.0. Image source.<\/a><\/figcaption><\/figure>\n
\"\"
Figure 13.26<\/strong> Strike-slip faults. Rocks on either side of the fault move parallel to the fault. In dextral strike-slip faults the far side moves to the right of the observer. In sinistral strike-slip faults the far side moves to the left of the observer. Source: Karla Panchuk (2018), CC BY 4.0.<\/figcaption><\/figure>\n

Different Tectonic Settings Have Distinct Types of Faults<\/h2>\n

Horst and Graben Structure<\/h3>\n

In areas that are characterized by extensional tectonics, and with many normal faults arranged side-by-side, some blocks may subside (settle downward) relative to neighbouring parts. This is typical in areas of continental rifting, such as the Great Rift Valley of East Africa or in parts of Iceland. In such situations, blocks that move down relative to the other blocks are graben<\/strong>, and elevated blocks with graben on either side are called horsts<\/strong>. There are many horsts and graben in the Basin and Range area of the western United States, especially in Nevada. Part of the Fraser Valley region of British Columbia, in the area around Sumas Prairie, is a graben.<\/p>\n

\"Figure
Figure 13.27\u00a0<\/strong> Graben and horst structures form where extension is happening. All of the faults are normal faults. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n

Thrust Faults<\/h3>\n

Thrust faults are a type of reverse fault with a very low-angle fault plane. The fault planes of thrust faults typically slope at less than 30\u00b0. Thrust faults are relatively common in mountain belts that were created by continent-continent collisions.\u00a0Some represent tens of kilometres of thrusting, where thick sheets of sedimentary rock have been pushed up and over other layers of rock (Figure 13.28).<\/p>\n

\"Figure
Figure 13.28<\/strong> A thrust fault. Top: prior to faulting. Bottom: after significant fault offset. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n

There are numerous thrust faults in the Rocky Mountains, and a well-known example is the McConnell Thrust, along which a sequence of sedimentary rocks about 800 m thick has been pushed for about 40 km from west to east over underlying rock (Figure 13.29).\u00a0The thrusted rocks range in age from Cambrian to Cretaceous, so in the area around Mt. Yamnuska Cambrian-aged rock (around 500 Ma) has been thrust over, and now lies on top of Cretaceous-aged rock (around 75 Ma) (Figure 13.30).<\/p>\n

\"Figure
Figure 13.29<\/strong>\u00a0 The McConnell Thrust in the eastern part of the Rockies. The rock within the faded area has been eroded. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n
\"\"
Figure 13.30<\/strong> The McConnell Thrust at Mt. Yamnuska near Exshaw, Alberta. Cambrian limestones have been thrust over top of Cretaceous mudstone. Source: Steven Earle (2015), CC BY 4.0. Image source.<\/a><\/figcaption><\/figure>\n
\n

<\/a>Practice with Types of Faults<\/strong><\/p>\n

What kind of dip-slip fault is this?<\/strong>\"\"<\/p>\n

The hanging wall went\u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0<\/span> relative to the footwall. (Hint: Up or down?)<\/p>\n

\"\"<\/p>\n

That makes this a \u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0\u00a0\u00a0<\/span> fault (Hint: Normal, reverse, thrust, or strike-slip?), caused by \u00a0\u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0<\/span> stress. (Hint: Tension, compression, or shear?)<\/p>\n

\"\"<\/p>\n

What kind of dip-slip fault is this?<\/strong><\/p>\n

\"\"<\/p>\n

The hanging wall went\u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0\u00a0<\/span> relative to the footwall. (Hint: Up or down?)<\/p>\n

\"\"<\/p>\n

The fault cuts the beds at a \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> angle. (Hint: High or low?) This makes it a \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> fault (Hint: Normal, reverse, thrust, or strike-slip?), caused by \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> stress. (Hint: Tension, compression, or shear?)<\/p>\n

\"\"<\/p>\n

What kind of faults are these?<\/strong><\/p>\n

\"\"<\/p>\n

The hanging wall goes \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> relative to the footwall when each fault is considered individually. (Hint: Up or down?)<\/p>\n

\"\"<\/p>\n

That makes this\u00a0 \u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0\u00a0 \u00a0\u00a0\u00a0\u00a0 <\/span>-slip fault (Hint: Strike or dip?) a \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> fault. (Hint: Normal, reverse, or thrust?)<\/p>\n

\"\"<\/p>\n

What kind of fault is this?<\/strong><\/p>\n

\"\"<\/p>\n

This is a\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 <\/span>-slip fault (Hint: Strike or dip?), formed from \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0 \u00a0<\/span> stress. (Hint: Tension, compression, or shear?)<\/p>\n

From the perspective of the photographer, the beds on the opposite side of the fault are shifted to the\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 <\/span>. (Hint: Left or right?) This makes this fault \u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \u00a0 \u00a0 \u00a0 <\/span>. (Hint: Sinistral or dextral?)<\/p>\n

\"\"<\/p>\n

To check your answers, navigate to the below link to view the interactive version of this activity.<\/p>\n<\/div>\n

\n