1. EARTH SCIENCE Prentice Hall EARTH SCIENCE Tarbuck Lutgens 

2. 7 Chapter 7 Glaciers, Desert, and Wind

3. Types of Glaciers 7.1 Glaciers  A glacier is a thick ice mass that forms above the snowline over hundreds or thousands of years.

4. Types of Glaciers 7.1 Glaciers The ice age was a period of time when much of the Earth was covered in glaciers.  A glacier is a thick ice mass that forms above the snowline over hundreds or thousands of years.

5. Types of Glaciers 7.1 Glaciers The ice age was a period of time when much of the Earth was covered in glaciers.  A glacier is a thick ice mass that forms above the snowline over hundreds or thousands of years.  Valley Glaciers I ce masses that slowly advance down mountain valleys originally occupied by streams.

6. Types of Glaciers 7.1 Glaciers The ice age was a period of time when much of the Earth was covered in glaciers.  A glacier is a thick ice mass that forms above the snowline over hundreds or thousands of years.  Valley Glaciers I ce masses that slowly advance down mountain valleys originally occupied by streams. A stream of ice that flows between steep rock walls from near the top of the mountain valley.

7. Types of Glaciers 7.1 Glaciers  Ice Sheets Ice sheets are enormous ice masses that flow in all directions from one or more centers and cover everything but the highest land.

8. Types of Glaciers 7.1 Glaciers  Ice Sheets Ice sheets are enormous ice masses that flow in all directions from one or more centers and cover everything but the highest land. Ice sheets are sometimes called continental ice sheets because they cover large regions where the climate is extremely cold.

9. Types of Glaciers 7.1 Glaciers  Ice Sheets Ice sheets are enormous ice masses that flow in all directions from one or more centers and cover everything but the highest land. Ice sheets are sometimes called continental ice sheets because they cover large regions where the climate is extremely cold. They are huge compared to valley glaciers.

10. Types of Glaciers 7.1 Glaciers  Ice Sheets Ice sheets are enormous ice masses that flow in all directions from one or more centers and cover everything but the highest land. Ice sheets are sometimes called continental ice sheets because they cover large regions where the climate is extremely cold. They are huge compared to valley glaciers. They currently cover Greenland and Antarctica.

11. Currently Continental Ice Sheets Cover Greenland and Antarctica

12. How Glaciers Move 7.1 Glaciers  The movement of glaciers is referred to as flow, and it happens in two ways.

13. How Glaciers Move 7.1 Glaciers  The movement of glaciers is referred to as flow, and it happens in two ways. 1. Plastic flow—involves movement within the ice

14. How Glaciers Move 7.1 Glaciers  The movement of glaciers is referred to as flow, and it happens in two ways. 1. Plastic flow—involves movement within the ice 2. Basal slip—slipping and sliding downward due to gravity

15. How Glaciers Move 7.1 Glaciers  The movement of glaciers is referred to as flow, and it happens in two ways. 1. Plastic flow—involves movement within the ice 2. Basal slip—slipping and sliding downward due to gravity The glacial budget is the balance, or lack of balance, between accumulation at the upper end of a glacier and loss, or wastage, at the lower end.  Budget of a Glacier

16. How a Glacier Moves

17. Calving

18. Glacial Erosion 7.1 Glaciers  Many landscapes were changed by the widespread glaciers of the recent ice age.

19. Glacial Erosion 7.1 Glaciers  Many landscapes were changed by the widespread glaciers of the recent ice age. Plucking—lifting of rock blocks  How Glaciers Erode

20. Glacial Erosion 7.1 Glaciers  Many landscapes were changed by the widespread glaciers of the recent ice age. Plucking—lifting of rock blocks - Rock flour (pulverized rock) - Striations (grooves in the bedrock)  How Glaciers Erode Abrasion

21. Landforms Created by Glacial Erosion 7.1 Glaciers  Glaciers are responsible for a variety of erosional landscape features, such as glacial troughs, hanging valleys, cirques, arêtes, and horns.

22. Landforms Created by Glacial Erosion 7.1 Glaciers A glacial trough is a U-shaped valley that was once V-shaped but was deepen by a glacier.  Glaciated Valleys  Glaciers are responsible for a variety of erosional landscape features, such as glacial troughs, hanging valleys, cirques, arêtes, and horns.

23. Erosional Landforms Caused by Valley Glaciers

24. Landforms Created by Glacial Erosion 7.1 Glaciers  A cirque is a bowl-shaped depression at the head of a glacial valley.

25. Landforms Created by Glacial Erosion 7.1 Glaciers Snaking, sharp-edged ridges called arêtes and sharp pyramid-like peaks called horns project above mountain landscapes.  Arêtes and Horns  A cirque is a bowl-shaped depression at the head of a glacial valley.

26. Cirque

27. Glacial Deposits 7.1 Glaciers  Types of Glacial Drift Glacial drift applies to all sediments of glacial origin, no matter how, where, or in what form they were deposited.

28. Glacial Deposits 7.1 Glaciers There are two types of glacial drift.  Types of Glacial Drift Glacial drift applies to all sediments of glacial origin, no matter how, where, or in what form they were deposited. 1. Till is material deposited directly by the glacier.

29. Glacial Deposits 7.1 Glaciers There are two types of glacial drift.  Types of Glacial Drift Glacial drift applies to all sediments of glacial origin, no matter how, where, or in what form they were deposited. 1. Till is material deposited directly by the glacier. 2. Stratified drift is sediment laid down by glacial meltwater.

30. Moraines, Outwash Plains, and Kettles 7.1 Glaciers  Glaciers are responsible for a variety of depositional features, including

31. Moraines, Outwash Plains, and Kettles 7.1 Glaciers Moraines—layers or ridges of till  Glaciers are responsible for a variety of depositional features, including - Lateral - Medial - End - Ground - Terminal end - Recessional end

32. Medial Moraine

33. Moraines, Outwash Plains, and Kettles 7.1 Glaciers  Glaciers are responsible for a variety of depositional features, including

34. Moraines, Outwash Plains, and Kettles 7.1 Glaciers outwash plains—sloping plains consisting of deposits from meltwater streams in front of the margin of an ice sheet  Glaciers are responsible for a variety of depositional features, including

35. Moraines, Outwash Plains, and Kettles 7.1 Glaciers outwash plains—sloping plains consisting of deposits from meltwater streams in front of the margin of an ice sheet  Glaciers are responsible for a variety of depositional features, including kettles—depressions created when a block of ice becomes lodged in glacial deposits and subsequently melts

36. Moraines, Outwash Plains, and Kettles 7.1 Glaciers  Glaciers are responsible for a variety of depositional features, including

37. Moraines, Outwash Plains, and Kettles 7.1 Glaciers  Glaciers are responsible for a variety of depositional features, including drumlins—streamlined, asymmetrical hills composed of glacial dirt

38. Moraines, Outwash Plains, and Kettles 7.1 Glaciers  Glaciers are responsible for a variety of depositional features, including drumlins—streamlined, asymmetrical hills composed of glacial dirt eskers—ridges composed largely of sand and gravel deposited by a stream flowing beneath a glacier near its terminus

39. Glaciers of the Ice age 7.1 Glaciers  Ice Age Began 2 to 3 million years ago

40. Glaciers of the Ice age 7.1 Glaciers  Ice Age Began 2 to 3 million years ago Division of geological time is called the Pleistocene epoch

41. Glaciers of the Ice age 7.1 Glaciers  Ice Age Began 2 to 3 million years ago Division of geological time is called the Pleistocene epoch Ice covered 30% of Earth's land area.

42. Glaciers of the Ice age 7.1 Glaciers  Ice Age Began 2 to 3 million years ago Division of geological time is called the Pleistocene epoch Ice covered 30% of Earth's land area. Greatly affected drainage

43. Extent of the Northern Hemisphere Ice Sheets

44. Geologic Processes in Arid Climates 7.2 Deserts  Weathering Much of the weathered debris in deserts results from mechanical weathering.

45. Geologic Processes in Arid Climates 7.2 Deserts  Weathering Much of the weathered debris in deserts results from mechanical weathering. Chemical weathering is not completely absent in deserts. Over long time spans, clay and thin soils do form.

46. Geologic Processes in Arid Climates 7.2 Deserts Not as effective as in humid regions  Weathering Much of the weathered debris in deserts results from mechanical weathering. Chemical weathering is not completely absent in deserts. Over long time spans, clay and thin soils do form.

47. Geologic Processes in Arid Climates 7.2 Deserts Not as effective as in humid regions  Weathering Much of the weathered debris in deserts results from mechanical weathering. Chemical weathering is not completely absent in deserts. Over long time spans, clay and thin soils do form.  The Role of Water In the desert, most streams are ephemeral—they only carry water after it rains.

48. A Dry Stream Desert Channel Before and After a Heavy Rainfall

49. Basin and Range: A Desert Landscape 7.2 Deserts  Most desert streams dry up long before they ever reach the ocean. The streams are quickly depleted by evaporation and soil infiltration.

50. Basin and Range: A Desert Landscape 7.2 Deserts  Most desert streams dry up long before they ever reach the ocean. The streams are quickly depleted by evaporation and soil infiltration. alluvial fan—a fan-shaped deposit of sediment formed when a stream’s slope is abruptly reduced  Interior drainage into basins produces

51. Basin and Range: A Desert Landscape 7.2 Deserts playa lake—a flat area on the floor of an undrained desert basin (playa) that fills and becomes a lake after heavy rain  Most desert streams dry up long before they ever reach the ocean. The streams are quickly depleted by evaporation and soil infiltration. alluvial fan—a fan-shaped deposit of sediment formed when a stream’s slope is abruptly reduced  Interior drainage into basins produces

52. Alluvial Fans

53. Basin and Range: A Desert Landscape  Most desert erosion results from running water. Although wind erosion is more significant in deserts than elsewhere, water does most of the erosional work in deserts. 7.2 Deserts

54. Wind Erosion 7.3 Landscapes Shaped by Wind  Wind erodes in the desert in two ways. 1. Deflation is the lifting and removal of loose particles such as clay and silt. It produces blowouts

55. Wind Erosion 7.3 Landscapes Shaped by Wind  Wind erodes in the desert in two ways. 1. Deflation is the lifting and removal of loose particles such as clay and silt. It produces blowouts desert pavement—a layer of coarse pebbles and gravel created when wind removed the finer material

56. Wind Erosion 7.3 Landscapes Shaped by Wind  Wind erodes in the desert in two ways. 1. Deflation is the lifting and removal of loose particles such as clay and silt. It produces 2. Abrasion blowouts desert pavement—a layer of coarse pebbles and gravel created when wind removed the finer material

57. Desert Deflation

58. Wind Deposits 7.3 Landscapes Shaped by Wind  The wind can create landforms when it deposits its sediments, especially in deserts and along coasts. Both layers of loess and sand dunes are landscape features deposited by the wind.  Loess Deposits of windblown silt Extensive blanket deposits Primary sources are deserts and glacial stratified drift.

59. Wind Deposits 7.3 Landscapes Shaped by Wind  The wind can create landforms when it deposits its sediments, especially in deserts and along coasts. Both layers of loess and sand dunes are landscape features deposited by the wind.

60. Wind Deposits 7.3 Landscapes Shaped by Wind  The wind can create landforms when it deposits its sediments, especially in deserts and along coasts. Both layers of loess and sand dunes are landscape features deposited by the wind.  Loess Deposits of windblown silt

61. Wind Deposits 7.3 Landscapes Shaped by Wind  The wind can create landforms when it deposits its sediments, especially in deserts and along coasts. Both layers of loess and sand dunes are landscape features deposited by the wind.  Loess Deposits of windblown silt Extensive blanket deposits

62. Wind Deposits 7.3 Landscapes Shaped by Wind  The wind can create landforms when it deposits its sediments, especially in deserts and along coasts. Both layers of loess and sand dunes are landscape features deposited by the wind.  Loess Deposits of windblown silt Extensive blanket deposits Primary sources are deserts and glacial stratified drift.

63. Wind Deposits 7.3 Landscapes Shaped by Wind  Sand Dunes Unlike deposits of loess, which form blanket- like layers over broad areas, winds commonly deposit sand in mounds or ridges called dunes.

64. Wind Deposits 7.3 Landscapes Shaped by Wind  Sand Dunes Unlike deposits of loess, which form blanket- like layers over broad areas, winds commonly deposit sand in mounds or ridges called dunes. Characteristic features - Slip face is the leeward slope of the dune

65. Wind Deposits 7.3 Landscapes Shaped by Wind  Sand Dunes Unlike deposits of loess, which form blanket- like layers over broad areas, winds commonly deposit sand in mounds or ridges called dunes. Characteristic features - Slip face is the leeward slope of the dune - Cross beds are the sloping layers of sand in the dune.

66. A Dune in New Mexico’s White Sands National Monument

67. Cross Beds Are Part of Navajo Sandstone in Zion National Park, Utah.

68. Wind Deposits 7.3 Landscapes Shaped by Wind  Types of Sand Dunes What form sand dunes assume depends on the wind direction and speed, how much sand is available, and the amount of vegetation.

69. Wind Deposits 7.3 Landscapes Shaped by Wind  Types of Sand Dunes What form sand dunes assume depends on the wind direction and speed, how much sand is available, and the amount of vegetation. - Barchan dunes - Transverse dunes - Longitudinal dunes - Star dunes - Parabolic dunes - Barchanoid dunes

70. Types of Sand Dunes