Washington is the second most glaciated state in the US, with 449 km² of glaciers and perennial snow and ice features. (Second to Alaska’s 90,000 km² of glaciers.) It is by far more ice-covered than the third most glaciated state of Wyoming, which has 74 km². The major glaciated areas are the North Cascades (231 km² ) and Mount Baker (49 km²); Mount Rainier (88 km² for named glaciers only) (Nylen 2004); and the Olympic Mountains (37km²). Other glaciated regions are in Washington's southern Cascades: Mount Adams with 24 km², Goat Rocks with 5 km², and Mount Saint Helens with 2 km². Overall, there are approximately 3,095 perennial snow and ice features.

Note: all statistics here are based on USGS 1:24,000 scale topographic quadrangle maps which are derived from mapping photography ranging from 1943 to 1987 (Fountain, Hoffman, et al. 2007).

In the North Cascades National Park, glacier area decreased by 7% from 1958 to 1998 (Granshaw and Fountain 2006; Granshaw 2002). Smaller glaciers lost significantly more area than larger glaciers. The well-studied South Cascade Glacier shrank by 22% during this time period (USGS), while the Blue Glacier in Olympic National Park saw a terminus retreat of 2% between 1957 and 1997 (Conway, Rasmussen, and Marshall 1999). The glaciers on Mount Rainier decreased in area by 21% between 1913 and 1994 (Nylen 2004).

During the Pleistocene, the maximum glacial extent 20,000 years ago, the Cordilleran Ice Sheet extended into the US from Canada. Two southern lobes on either side of the Cascade Range covered the Puget Lowlands and the Okanogan highlands. Canadian geologist George M. Dawson first proposed that this massive ice sheet flowed from northern British Columbia in 1891 (Denton and Hughes 1981). Approximately 14,000-11,000 years ago the ice sheet retreated north of the U.S.-Canadian border (Waitt Jr. and Thorson 1983). The Channeled Scablands in the eastern half of the state were catastrophically sculpted by the outburst floods from ice-dammed Glacial Lake Missoula.

Areas directly affected by floodwaters from Glacial Lake Missoula. ©1995, 2003 Alan Kettler. All rights reserved. Used here by permission. Slightly revised from version that appeared in Smithsonian , April 1995, p. 50.

The first observations of the glaciated peaks in Washington were by Capt. Vancouver in the late 1700s, during his exploration of the northwest coast. Further discovery of this region did not occur until the Lewis and Clark expeditions (1804-1806), and mapping efforts were not initiated for another fifty years, by the initial Pacific Railroad survey between 1853 and 1855 (Beckey 2003).

The International Boundary Survey carried out the original boundary survey in the North Cascades region from 1858-1860 (Baker 1900). Surveyor Henry Custer wrote of the Challenger Glacier on Whatcom Peak in the North Cascades, “a solid wall of pure ice, to a height of over 5000 feet or near the summit of a very high mountain.” He compared the glacier’s “matchless grandeur” with Niagara Falls, only ten times as high (Beckey 2003).

US Geological Survey (USGS) Field crew in the Cascade Mountains, Washington. 1903. (U.S. Geological Survey)

In 1857, Lt. August V. Kautz climbed Mount Rainier via what is now the Nisqually Glacier, but had to turn back from the summit because they were ill-prepared for the cold, windy conditions and impending nightfall. His party members suffered from many health problems including snow-blindness (Kautz 1875). Eleven years later, Philemon Beecher Van Trump and Hazard Stevens were the first to reach the summit of Mount Rainier, but were forced to stay the night in the steam caves to rest and escape the icy winds (Beckey 2003).

Mount Baker is a large stratovolcano, and at 3,285m is the tallest peak in the North Cascades Range (Harper 1993). Mount Baker has 124 perennial snow/ice features, including 15 named glaciers. The total area of all features is 49 km², of which the named glaciers cover 44 km².

Shaded relief map of Mount Baker. Click on the map above for the full size version. 

Easton Glacier 1912.
Photographer: J.D. Welsh. (USFS)

The Stuart Range has 82 perennial snow/ice features, including 7 named glaciers. The total ice-covered area is 9 km², and the area of named features is 3 km². Mount Stuart (2,870m) is the second highest non-volcanic peak in the Cascades (Tabor 1982).

Shaded relief map of the Stuart Range. Click on the map above for the full size version. 

Mount Stuart. Sept 20, 1966. Photographer: Austin Post. (USGS Photographic Library)

The Olympic Mountains have 387 perennial snow/ice features, including about 20 named glaciers. The total area of ice features is 37 km², and the area of named features is 22 km². Blue Glacier, flowing from the summit of Mt Olympus, is a long-monitored glacier of the University of Washington.

Shaded relief map of the glaciers in Olympic National Park. Click on the map above for the full size version.

Blue Glacier. Oct 28, 1941. Photographer: W.B. Augustine

Mount Rainier has 495 perennial snow/ice features, including 33 named glaciers. The total ice-covered area is 94 km², and the area of the named features is 88 km². The elevation range of the glaciers is between 1,069m and 4,394m.

Shaded relief map of Mount Rainier.  Click on the map above for the full size version. 

North Mowich Glacier, September 1960. Photographer: Austin S. Post. (National Snow and Ice Data Center World Data Center for Glaciology, Boulder CO)

1928 map of Mount Rainier National Park. Click on the map above for full size version.

Goat Rocks has 57 perennial snow/ice features with 4 named glaciers. The total ice-covered area is 5 km², and the total area of the named glaciers is 3 km². The elevation range of the glaciers is between 1,218m and 2,437m.

Shaded relief map of Goat Rocks. Click on the map above for the full size version.

Meade Glacier, August 2007 (John Scurlock)

Mount Adams has 209 perennial snow/ice features and 11 named glaciers. The total ice-covered area is 24 km². The area of named glaciers is 20 km². The elevation range of the glaciers is between 1,752m and 3,746m. There has been little volcanic activity on Mount Adams in the past 10,000 years, however most of present-day Mount Adams formed rapidly in the previous 30,000 years. Since the formation, most of the upper part of the mountain has been eroded by glaciers. Additional areas are prone to debris avalanches because of weakened rocks from heated ground water and acidification by volcanic gases (Scott et al. 1995).

Shaded relief map of Mount Adams. Click on the map above for the full size version.

Lyman and Lava glaciers, October 2006. Photographer: Darryl Lloyd

Mount St Helens, 1939 (Mazamas)

Mount Saint Helens is the most active volcano in the continental US. Over the past 300,000 years, there have been periods of violent explosions, as well as quieter lava flows (Clynne, Ramsey, and Wolfe 2005). Mount Saint Helens has 9 perennial snow/ice features and 7 named glaciers. The total ice-covered area is 2 km².

May 18, 1980. (Cascades Volcano Observatory)

The eruption of Mount Saint Helens on May 18, 1980 removed the Loowit and Leschi glaciers, as well as reduced the area of the Wishbone, Shoestring, Ape, Nelson and Forsyth glaciers. The resulting crater facilitated the creation of a new glacier called Crater Glacier. The ablation rate of the glacier is slower due to debris cover. The glacier formed gradually, and 1996 aerial photographs showed definite glacial features. As of 2001, Crater Glacier is now the largest on Mount Saint Helens at 1km², and the Shoestring, Nelson, Forsyth and Dryer glaciers are no longer there (Schilling et al. 2004).

Both arms of Crater Glacier. July 31, 2008. Photographer: Steve Shilling. (USGS Cascade Volcano Observatory)

In October 2004, Mount Saint Helens began building a dome in the 1980 crater. The erupting lava and consequent dome growth affected Crater Glacier. The eruption first pressed the east arm against the east wall, and then uplifted the glacier's west arm and effectively separated the glacier into two parts (Schilling et al. 2006). Mount Saint Helens has been more or less continuously active since the 1980 eruption. The most current period of eruptive activity was from 2004 until 2008 (USGS Cascades Volcano Observatory).

South Cascade Glacier has the second longest mass balance record in the world. The glacier is the focus of glacier research in the area since the USGS monitoring program began in 1957.

Click inside the blue boxes for a detailed view of glacial termini. 

Chart displaying changes in glacier area over the past century. (Hoffman and Fountain, unpublished)

Mount Rainier’s glaciers have retreated considerably since August Kautz first noted the position of the Nisqually Glacier in 1857 (Kautz 1875).  His visit was just after the peak of the Little Ice Age, a period of general glacial advance. The Nisqually Glacier reached its furthest Little Ice Age extent in 1840, 2.3 km from its 2006 location (Heliker, Johnson, and Hodge 1984). The easily-accessible Nisqually Glacier flows near the Paradise Visitor Center and has therefore been closely monitored over the 20th century. Several minor advances have been documented in the 1950’s and mid-1970’s, but the overall change is one of dramatic retreat: 1.3 km from 1931 to 2006 based on recorded extents and aerial photographs (Hekkers 2008; Nylen 2004).

Geographic setting and aspect have inconsistent effects on glaciers. The Nisqually Glacier, like other south-facing glaciers, has retreated more than north-facing glaciers, resulting in an area loss of 0.44 km² in the last 70 years of the 20th century (Nylen 2004). South-facing glaciers lost 26% of their area while northern glaciers lost only 17%, and smaller glaciers are generally more susceptible to climatic changes than are larger glaciers (Nylen 2004). Rock avalanches can insulate a glacier, e.g., the 1963 rock avalanche on the Emmons Glacier that sustained a glacial advance through the early 1980's (Driedger 1986).

Map showing glacier change since 1896. Click on the map above for the full size version. 

• In 1998-1999 the Mt Baker ski area set the US record for the greatest annual snowfall of 32 meters.
  http://www.climate.washington.edu/facts.html

• In 2004 Washington ranked first in the nation in production of red raspberries (90.0% of total U.S. production), hops (75.0%), apples (58.1%), sweet cherries (47.3%), pears (42.6%), Concord grapes (39.3%), and Niagara grapes (31.6%).(http://www.50states.com/facts/washingt.htm )

Washington apples (Scott Bauer, USDA Agriculture Research Image Gallery)

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———. 1898. Glaciers of Mount Rainier. In USGS 18th Annual Report, 349-415: USGS.

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