Retreat of glaciers since 1850


Retreat of glaciers since 1850

The retreat of glaciers since 1850, worldwide and rapid, affects the availability of fresh water for irrigation and domestic use, mountain recreation, animals and plants that depend on glacier-melt, and in the longer term, the level of the oceans. Studied by glaciologists, the temporal coincidence of "glacier retreat" with the measured increase of atmospheric greenhouse gases is often cited as an evidentiary underpinning of anthropogenic (human-caused) global warming. Mid-latitude mountain ranges such as the Himalayas, Alps, Rocky Mountains, Cascade Range, and the southern Andes, as well as isolated tropical summits such as Mount Kilimanjaro in Africa, are showing some of the largest proportionate glacial loss.ref_harv|glacier|IPCC|IPCCref_harv|realclimate|Mölg|Mölg

The Little Ice Age was a period from about 1550 to 1850 when the world experienced relatively cooler temperatures compared to the present. Subsequently, until about 1940, glaciers around the world retreated as the climate warmed. Glacial retreat slowed and even reversed, in many cases, between 1950 and 1980 as a slight global cooling occurred. However, since 1980 a significant global warming has led to glacier retreat becoming increasingly rapid and ubiquitous, so much so that some glaciers have disappeared altogether, and the existence of a great number of the remaining glaciers of the world is threatened. In locations such as the Andes of South America and Himalayas in Asia, the demise of glaciers in these regions will have potential impact on water supplies. The retreat of mountain glaciers, notably in western North America, Asia, the Alps, Indonesia and Africa, and tropical and subtropical regions of South America, has been used to provide qualitative evidence for the rise in global temperatures since the late 19th century.ref_harv|climate|IPCC2|IPCC2 ref_harv|glims|NSIDC|NSIDC The recent substantial retreat and an acceleration of the rate of retreat since 1995 of a number of key outlet glaciers of the Greenland and West Antarctic ice sheets, may foreshadow a rise in sea level, having a potentially dramatic effect on coastal regions worldwide.

Glacier mass balance

Crucial to the survival of a glacier is its mass balance, the difference between accumulation and ablation (melting and sublimation). ref_harv|tropic|Mote and Kaser|Mote and Kaser Climate change may cause variations in both temperature and snowfall, causing changes in mass balance. A glacier with a sustained negative balance is out of equilibrium and will retreat. A glacier with sustained positive balance is also out of equilibrium, and will advance to reestablish equilibrium. Currently, there are a few advancing glaciers, although their modest growth rates suggest that they are not far from equilibrium.ref_harv|Trabant|Trabant|Trabant|

Glacier retreat results in the loss of the low-elevation region of the glacier. Since higher elevations are cooler, the disappearance of the lowest portion of the glacier reduces overall ablation, thereby increasing mass balance and potentially reestablishing equilibrium. However, if the mass balance of a significant portion of the accumulation zone of the glacier is negative, it is in disequilibrium with the climate and will melt away without a colder climate and or an increase in frozen precipitation.

The key symptom of a glacier in disequilibrium is thinning along the entire length of the glacier.ref_harv|cascades|Pelto|Peltoref_harv|nichols2|Pelto and Hartzell|Pelto and Hartzell For example, Easton Glacier (see below) will likely shrink to half its size, but at a slowing rate of reduction, and stabilize at that size, despite the warmer temperature, over a few decades. However, the Grinnell Glacier (pictured above) will shrink at an increasing rate until it disappears. The difference is that the upper section of Easton Glacier remains healthy and snow covered, while even the upper section of the Grinnell Glacier is bare, is melting and has thinned. Small glaciers with minimal altitude gain are most likely to fall into disequilibrium with the climate.

Methods for measuring glacier retreat include staking terminus location, global positioning mapping, aerial mapping, and laser altimetry.

Mid-latitude glaciers

Mid-latitude glaciers are located either between the Tropic of Cancer and the Arctic Circle, or between the Tropic of Capricorn and the Antarctic Circle. These two regions support glacier ice from mountain glaciers, valley glaciers and even smaller icecaps, which are usually located in higher mountainous regions. All of these glaciers are located in mountain ranges, notably the Himalayas; the Alps; the Pyrenees; Rocky Mountains and Pacific Coast Ranges of North America; the Patagonian Andes in South America; and mountain ranges in the island nation of New Zealand. Glaciers in these latitudes are more widespread and tend to be more massive the closer they are located to the polar regions. These glaciers are the most widely studied over the past 150 years. As is true with the glaciers located in the tropical zone, virtually all the glaciers in the mid-latitudes are in a state of negative mass balance and are retreating.

Eastern hemisphere

Europe

The World Glacier Monitoring Service reports on changes in the terminus, or lower-elevation end, of glaciers from around the world every five years.ref_harv|world|WGMS|WGMS In their 1995–2000 edition, they noted the terminal point variations of glaciers across the Alps. Over the five-year period from 1995 to 2000, 103 of 110 glaciers examined in Switzerland, 95 of 99 glaciers in Austria, all 69 glaciers in Italy, and all 6 glaciers in France were in retreat. French glaciers experienced a sharp retreat in the years 1942–53 followed by advances up to 1980, and then further retreat beginning in 1982. As an example, since 1870 the Argentière Glacier and Mont Blanc Glacier have receded by 1,150 (3,800 ft) and 1,400 m (4,600 ft), respectively. The largest glacier in France, the Mer de Glace, which is 11 km (7 miles) long and 400 m (1,300 ft) thick, has lost 8.3% of its length, or 1 km (0.6 miles), in 130 years, and thinned by 27%, or 150 m (500 ft), in the midsection of the glacier since 1907. The Bossons Glacier in Chamonix, France, has retreated 1,200 m (3,900 ft) from extents observed in the early 20th century. In 2005, of 91 Swiss glaciers studied, 84 retreated from where their terminal points had been in 2004 and the remaining 7 showed no change.ref_harv|swiss2|MSNBC|MSNBC

Other researchers have found that glaciers across the Alps appear to be retreating at a faster rate than a few decades ago. In 2006, the Swiss Glacier survey of 85 glaciers found 84 retreating and 1 advancing. The Trift Glacier had retreated over 500 m (1,600 ft) just in the three years of 2003 to 2005, which is 10% of its total length. The Grosser Aletsch Glacier, the largest glacier in Switzerland, has retreated 2,600 m (8,500 ft) since 1880. This rate of retreat has also increased since 1980, with 30%, or 800 m (2,600 ft), of the total retreat occurring in the last 20% of the time period.ref_harv|swiss|SFIoTZ|SFIoTZ Similarly, of the glaciers in the Italian Alps, only about a third were in retreat in 1980, while by 1999, 89% of these glaciers were retreating. In 2005, the Italian Glacier Commission found that 123 glaciers were retreating, 1 advancing and 6 stationary.ref_harv|italy|IGC|IGC Repeat photography of glaciers in the Alps provides clear evidence that glaciers in this region have retreated significantly in the past several decades. ref_harv|swiss|Alean|Alean Morteratsch Glacier, Switzerland is one key example. The yearly measurements of the length changes started in 1878. The overall retreat from 1878 to 1998 accounts for a total of 2 km with a mean annual retreat rate of approximately 17 m/y. This long-term average was markedly surpassed in recent years receding 30 m/y from 1999–2005.ref_harv|swiss|SFIoTZ|SFIoTZ One major concern which has in the past had great impact on lives and property is the death and destruction from a Glacial Lake Outburst Flood (GLOF). Glaciers stockpile rock and soil that has been carved from mountainsides at their terminal end. These debris piles often form dams that impound water behind them and form glacial lakes as the glaciers melt and retreat from their maximum extents. These terminal moraines are frequently unstable and have been known to burst if overfilled or displaced by earthquakes, landslides or avalanches. If a glacier has a rapid melting cycle during warmer months, the terminal moraine may not be strong enough to continue to impound the rising water behind it, leading to a massive localized flood. This is an increasing risk due to the creation and expansion of glacial lakes resulting from glacier retreat. Past floods have been deadly and have resulted in enormous property damage. Towns and villages in steep, narrow valleys that are downstream from glacial lakes are at the greatest risk. In 1892 a GLOF released some 200,000 m³ (260,000 yd³) of water from the lake of the Glacier de Tête Rousse, resulting in the deaths of 200 people in the French town of Saint Gervais.ref_harv|italy|Pelto5|Pelto5 GLOFs have been known to occur in every region of the world where glaciers are located. Continued glacier retreat is expected to create and expand glacial lakes, increasing the danger of future GLOFs.

Though the glaciers of the Alps have received more attention from glaciologists than in other areas of Europe, research indicates that throughout most of Europe, glaciers are rapidly retreating. In the Kebnekaise Mountains of northern Sweden, a study of 16 glaciers between 1990 and 2001 found that 14 glaciers were retreating, one was advancing and one was stable.ref_harv|sweden|GSU|GSU During the 20th century, glaciers in Norway retreated overall with brief periods of advance around 1910, 1925 and in the 1990s. In the 1990s, 11 of 25 Norwegian glaciers observed had advanced due to several consecutive winters with above normal precipitation. However, following several consecutive years of little winter precipitation since 2000, and record warmth during the summers of 2002 and 2003, Norwegian glaciers have decreased significantly since the 1990s. By 2005 only 1 of the 25 glaciers monitored in Norway was advancing, two were stationary and 22 were retreating. In 2006 glacier mass balances were very negative in Norway and of the 26 glaciers examined, 24 were retreating with one stationary and one advancing.ref_harv|NVE|Kjøllmoen|Kjøllmoen The Norwegian Engabreen Glacier has retreated 185 m (603 ft) since 1999, while the Brenndalsbreen and Rembesdalsskåka glaciers have retreated 276 m (905 ft) and 250 m (820 ft), respectively, since 2000. The Briksdalsbreen glacier retreated 96 m (314 ft) in 2004 alone—the largest annual retreat recorded for this glacier since monitoring began in 1900. This figure was exceeded in 2006 with five glaciers retreating over 100 m from the fall of 2005 to the fall of 2006. Four outlets from the Jostedalsbreen ice cap, Kjenndalsbreen,Brenndalsbreen, Briksdalsbreen and Bergsetbreen had a frontal retreat of more than 100metres. Gråfjellsbrea, an outlet from Folgefonna, had a retreat of almost 100 metres. Overall, from 1999 to 2005, Briksdalsbreen retreated 336 m (1102 ft)ref_harv|NVE|Kjøllmoen|Kjøllmoenref_harv|norway|CICaER|CICaER. In the Spanish Pyrenees, recent studies have shown important losses in extent and volume in the glaciers of theMaladeta massif during the period 1981-2005: (1) glacial ice decreased in extent 35.7%, reducing from 240.9 ha to 155.0 ha; (2) losses in total ice volume reached 0.0137 km3 (75.6 mW.e.); (3) mean altitude of the studied glaciers increased 43.5 m. These changes seem to have been forced by climatic change (reduction in the snowfall contributions and increase in the maximum temperatures) during the past few decades in this Pyrenean region. In addition, local variables such as the orientation of eachglacier, their altitude and their initial size seem to have induced significant spatial differences in the magnitude of the losses ref_harv|Pyrenees|Chueca et alia|Chueca et alia.

Asia

The Himalayas and other mountain chains of central Asia support large regions that are glaciated. These glaciers provide critical water supplies to arid countries such as Mongolia, western China, Pakistan and Afghanistan. As is true with other glaciers worldwide, the glaciers of Asia are experiencing a rapid decline in mass. The loss of these glaciers would have a tremendous impact on the ecosystem of the region.

A WWF report concluded that 67% of all Himalayan glaciers are retreating. In examining 612 glaciers in China between 1950 and 1970, 53% of the glaciers studied were retreating. After 1990, 95% of these glaciers were measured to be retreating, indicating that retreat of these glaciers was becoming more widespread.ref_harv|asia|Rai, Guring, et alia|Rai, Guring, et alia Glaciers in the Mount Everest region of the Himalayas are all in a state of retreat. The Khumbu Glacier, which is one of the main routes to the base of Mount Everest, has retreated 5 km (3.1 miles) since 1953. The Rongbuk Glacier, draining the north side of Mount Everest into Tibet, has been retreating 20 m (65 ft) per year. In India the Gangotri Glacier, which is a significant source of water for the Ganges River, retreated 34 m (111 ft) per year between 1970 and 1996, and has averaged a loss of 30 m (100 ft) per year since 2000. With the retreat of glaciers in the Himalayas, a number of glacial lakes have been created. A growing concern is the potential for Glacial Lake Outburst Floods—researchers estimate 20 glacial lakes in Nepal and 24 in Bhutan pose hazards to human populations should their terminal moraine dams fail. One glacial lake identified as potentially hazardous is Bhutan's Raphstreng Tsho, which measured 1.6 km (0.99 mile) long, 0.96 km (0.59 mile) wide and was 80 m (262 ft) deep in 1986. By 1995 the lake had swollen to be 1.94 km (1.20 mile) long, 1.13 km (0.70 mile) wide and a depth of 107 m (351 ft). In 1994 a GLOF from Luggye Tsho, a glacial lake adjacent to Raphstreng Tsho, killed 23 people downstream.ref_harv|unep|UNEP|UNEP

Glaciers in the Ak-shirak Range in Kyrgyzstan experienced a slight loss between 1943 and 1977 and an accelerated loss of 20% of their remaining mass between 1977 and 2001.ref_harv|Ak-shirak|Khromova, Dyurgerov and Barry|Khromova, Dyurgerov and Barry In the Tien Shan mountains, which Kyrgyzstan shares with China and Kazakhstan, studies in the northern areas of that mountain range show that the glaciers that help supply water to this arid region have been losing nearly two cubic km (0.47 mile³) of ice per year between 1955 and 2000. The University of Oxford study also reported that an average of 1.28% of the volume of these glaciers had been lost per year between 1974 and 1990.ref_harv|Tien|Kirby|Kirby

To the south of the Tien Shan, the Pamirs mountain range located primarily in Tajikistan has many thousands of glaciers, all of which are in a general state of retreat. During the 20th century, the glaciers of Tajikistan lost 20 km³ (4.8 mile³) of ice. The 70 km (43 mile) long Fedchenko Glacier, which is the largest in Tajikistan and the largest non-polar glacier on Earth, lost 1.4% of its length, or 1 km (0.6 mile), 2 km³ (0.5 mile³) of its mass, and the glaciated area was reduced by 11 km² (4.2 mile²) during the 20th century. Similarly, the neighboring Skogatch Glacier lost 8% of its total mass between 1969 and 1986. The country of Tajikistan and neighboring countries of the Pamir Range are highly dependent upon glacial runoff to ensure river flow during droughts and the dry seasons experienced every year. The continued demise of glacier ice will result in a short-term increase, followed by a long-term decrease in glacial melt water flowing into rivers and streams.ref_harv|Pamir|Novikov|Novikov

In New Zealand the mountain glaciers have been in general retreat since 1890, with an acceleration of this retreat since 1920. Most of the glaciers have thinned measurably and have reduced in size, and the snow accumulation zones have risen in elevation as the 20th century progressed. During the period 1971–75, Ivory Glacier receded 30 m (98 ft) at the glacial terminus, and about 26% of the surface area of the glacier was lost over the same period. Since 1980 numerous small glacial lakes were created behind the new terminal moraines of several of these glaciers. Glaciers such as Classen, Godley and Douglas now all have new glacial lakes below their terminal locations due to the glacial retreat over the past 20 years. Satellite imagery indicates that these lakes are continuing to expand. There has been significant and ongoing ice volume losses on the largest New Zealand glaciers, including Tasman, Ivory, Classen, Mueller, Maud, Hooker, Grey, Godley, Ramsay, Murchison, Therma, Volta and Douglas Glaciers. The retreat of these glaciers has been marked by expanding proglacial lakes and terminus region thinning. The loss in volume from 1975-2005 is 11% of the totalref_harv|volumes|Salinger|Salinger.

Several glaciers, notably the much visited Fox and Franz Josef Glaciers in New Zealand, have periodically advanced, especially during the 1990s, but the scale of these advances is small when compared to 20th-century retreat. Both glaciers are currently more than 2.5 km shorter than a century ago. These large, rapidly flowing glaciers situated on steep slopes have been very reactive to small mass-balance changes. A few years of conditions favorable to glacier advance, such as increased snowfall and cooler temperatures, are rapidly echoed in a corresponding advance, followed by equally rapid retreat when those favorable conditions end.ref_harv|newzealand|USGS3|USGS3 The glaciers that have been advancing in a few locations in New Zealand have been doing so due to a temporary weather change associated with El Niño, which has brought more precipitation and cloudier, cooler summers since 2002.ref_harv|elnino|Goodenough|Goodenough-

Western hemisphere

North American glaciers are primarily located along the spine of the Rocky Mountains in the United States and Canada, and the Pacific Coast Ranges extending from northern California to Alaska. While Greenland is geologically associated with North America, it is also a part of the Arctic region. Aside from the few tidewater glaciers such as Taku Glacier, that are in the advance stage of their tidewater glacier cycle prevalent along the coast of Alaska, virtually all the glaciers of North America are in a state of retreat. The observed retreat rate has increased rapidly since approximately 1980, and overall each decade since has seen greater rates of retreat than the preceding one. There are also small remnant glaciers scattered throughout the Sierra Nevada mountains of California and Nevada.

Cascades

The Cascade Range of western North America extends from southern British Columbia in Canada to northern California. Excepting Alaska, about half of the glacial area in the U.S. is contained in the more than 700 glaciers of the North Cascades, a portion of the range between the Canadian border and I-90 in central Washington. These glaciers store as much water as that contained in all the lakes and reservoirs in the rest of the state, and provide much of the stream and river flow in the dry summer months, approximating some 870,000 m³ (1,140,000 yd³).

As recently as 1975, many North Cascade glaciers were advancing due to cooler weather and increased precipitation that occurred from 1944 to 1976. However, by 1987 all the North Cascade glaciers were retreating, and the pace of the glacier retreat has increased each decade since the mid-1970s. Between 1984 and 2005, the North Cascade glaciers lost an average of more than 12.5 m in thickness and between 20% and 40% of their volume.ref_harv|cascades|Pelto|2

Glaciologists researching the North Cascades glaciers have found that all 47 monitored glaciers are receding and that four glaciers—Spider Glacier, Lewis Glacier (pictured), Milk Lake Glacier, and David Glacier—have disappeared completely since 1985. The White Chuck Glacier (near Glacier Peak) is a particularly dramatic example. The glacier shrank from 3.1 km² (1.19 miles²) in 1958 to 0.9 km² (0.34 miles²) in 2002. Similarly, the Boulder Glacier on the southeast flank of Mount Baker retreated 450 m (1,476 ft) from 1987 to 2005, leaving barren terrain behind. This retreat has occurred during a period of reduced winter snowfall and higher summer temperatures. In this region of the Cascades, winter snowpack has declined 25% since 1946, and summer temperatures have risen 0.7 °C (1.2 °F) during the same period. The reduced snowpack has occurred despite a small increase in winter precipitation; thus, it reflects warmer winter temperatures leading to rainfall and melting on glaciers even during the winter. As of 2005, 67% of the North Cascade glaciers observed are in disequilibrium and will not survive the continuation of the present climate. These glaciers will eventually disappear unless temperatures fall and frozen precipitation increases. The remaining glaciers are expected to stabilize, unless the climate continues to warm, but will be much reduced in size.ref_harv|cascades2|Pelto3|Pelto3ref_harv|cascades3|Pelto4|Pelto4

US Rocky Mountains

On the sheltered slopes of the highest peaks of Glacier National Park in Montana, its eponymous glaciers are diminishing rapidly. The area of each glacier has been mapped by the National Park Service and the U.S. Geological Survey for decades. Comparing photographs taken in the mid-19th century with contemporary images provides ample evidence that the glaciers in the park have retreated notably since 1850. Repeat photography over the decades since clearly show that glaciers throughout the park such as Grinnell Glacier are all retreating. The larger glaciers are now approximately a third of their former size when first studied in 1850, and numerous smaller glaciers have disappeared completely. Only 27% of the 99 km² (38 miles²) area of Glacier National Park covered by glaciers in 1850 remained covered by 1993. ref_harv|gnp|USGS|USGS Researchers believe that by the year 2030, the vast majority of glacial ice in Glacier National Park will be gone unless current climate patterns reverse their course.ref_harv|mont|USGS5|USGS5 Grinnell Glacier is just one of many glaciers in Glacier National Park that have been well documented by photographs for many decades. The photographs below clearly demonstrate the retreat of this glacier since 1938.

The semiarid climate of Wyoming still manages to support about a dozen small glaciers within Grand Teton National Park, which all show evidence of retreat over the past 50 years. Schoolroom Glacier, located slightly southwest of Grand Teton, one of the more easily reached glaciers in the park, is expected to disappear by 2025.ref_harv|gtnp|Peterson|Peterson Research between 1950 and 1999 demonstrated that the glaciers in Bridger-Teton National Forest and Shoshone National Forest in the Wind River Range shrank by over a third of their size during that period. Photographs indicate that the glaciers today are only half the size as when first photographed in the late 1890s. Research also indicates that the glacial retreat was proportionately greater in the 1990s than in any other decade over the last 100 years. Gannett Glacier on the northeast slope of Gannett Peak is the largest single glacier in the Rocky Mountains south of Canada. It has reportedly lost over 50% of its volume since 1920, with almost half of that loss occurring since 1980. Glaciologists believe the remaining glaciers in Wyoming will disappear by the middle of the 21st century if the current climate patterns continue.ref_harv|wyoming|WWRDSL|WWRDSL

Canadian Rockies

In the Canadian Rockies, the glaciers are generally larger and more widespread than they are to the south in Montana. One of the more accessible glaciers in the Canadian Rockies is the Athabasca Glacier, which is an outlet glacier of the 325 km² (125 miles²) Columbia Icefield. The Athabasca Glacier has retreated 1,500 m (4,921 ft) since the late 19th century. The rate of retreat for this glacier has increased since 1980, following a period of slow retreat from 1950 to 1980. The Peyto Glacier in Alberta covers an area of about 12 km² (4.63 miles²), and retreated rapidly during the first half of the 20th century, stabilized by 1966, and resumed shrinking in 1976.ref_harv|canada|CCIN|CCIN Illecillewaet Glacier in British Columbia's Glacier National Park (Canada) has retreated 2 km (1.25 miles) since first photographed in 1887.

Alaska

There are thousands of glaciers in Alaska, though only a relative few of them have been named. The Columbia Glacier near Valdez in Prince William Sound has retreated 15 km (9.3 miles) in the last 25 years. Icebergs calved off this glacier were a partial cause of the Exxon Valdez oil spill, as the oil tanker had changed course to avoid the icebergs. The Valdez Glacier is in the same area, and though it does not calve, it has also retreated significantly. "A 2005 aerial survey of Alaskan coastal glaciers identified more than a dozen glaciers, many former tidewater and calving glaciers, including Grand Plateau, Alsek, Bear, and Excelsior Glaciers that are rapidly retreating. Of 2,000 glaciers observed, 99% are retreating." ref_harv|alaska|Molnia2|Molnia2 Icy Bay in Alaska is fed by three large glaciers—Guyot, Yahtse, and Tyndall Glaciers—all of which have experienced a loss in length and thickness and, consequently, a loss in area. Tyndall Glacier became separated from the retreating Guyot Glacier in the 1960s and has retreated 24 km (14.9 miles) since, averaging more than 500 m (1,640 ft) per year.ref_harv|alaska|Molnia|Molnia

The Juneau Icefield Research Program has monitored the outlet glaciers of the Juneau Icefield since 1946. On the west side of the ice field, the terminus of the Mendenhall Glacier, which flows into suburban Juneau, Alaska, has retreated 580 m (1,902 ft). Of the nineteen glaciers of the Juneau Icefield, eighteen are retreating, and one, the Taku Glacier, is advancing. Eleven of the glaciers have retreated more than 1.0 km (0.6 miles) since 1948 — Antler Glacier, 5.4 km (3.4 miles); Gilkey Glacier, 3.5 km (2.2 miles); Norris Glacier, 1.1 km (0.7 miles) and Lemon Creek Glacier, 1.5 km (0.9 miles).ref_harv|Juneau Icefield|Pelto6| Taku Glacier has been advancing since at least 1890, when naturalist John Muir observed a large iceberg calving front. By 1948 the adjacent fjord had filled in, and the glacier no longer calved and was able to continue its advance. By 2005 the glacier was only 1.5 km (0.93 miles) from reaching Taku Point and blocking Taku Inlet. The advance of Taku Glacier averaged 17 m (55 ft) per year between 1988 and 2005. The mass balance was very positive for the 1946–88 period fueling the advance; however, since 1988 the mass balance has been slightly negative, which should in the future slow the advance of this mighty glacier.ref_harv|taku|Pelto and Miller|Pelto and Miller

Long-term mass balance records from Lemon Creek Glacier in Alaska show slightly declining mass balance with time.ref_harv|lemon|Miller and Pelto|Miller and Pelto The mean annual balance for this glacier was −0.23 m (−0.75 ft) each year during the period of 1957 to 1976. Mean annual balance has been increasingly negatively averaging −1.04 m (−3.4 ft) per year from 1990 to 2005. Repeat glacier altimetry, or altitude measuring, for 67 Alaska glaciers find rates of thinning have increased by more than a factor of two when comparing the periods from 1950 to 1995 (0.7 m [2.3 ft] per year) and 1995 to 2001 (1.8 m [5.9 ft] per year).ref_harv|thin|Arendt, et alia|Arendt, et alia This is a systemic trend with loss in mass equating to loss in thickness, which leads to increasing retreat—the glaciers are not only retreating, but they are also becoming much thinner. In Denali National Park, all glaciers monitored are retreating, with an average retreat of 20 m (66 ft) per year. The terminus of the Toklat Glacier has been retreating 26 m (78 ft) per year and the Muldrow Glacier has thinned by 20 m (66 ft) since 1979.ref_harv|Denali|Adema|Adema Well documented in Alaska are surging glaciers that have been known to rapidly advance, even as much as 100 m (333 ft) per day, though the reasons they do this is not fully understood. ref_harv|surge|Pedersen|Pedersen Variegated, Black Rapids, Muldrow, Susitna and Yanert are examples of surging glaciers in Alaska that have made rapid advances in the past. These glaciers are all retreating overall, punctuated by short periods of advance.

Andes

A large region of population surrounding the central and southern Andes of Argentina and Chile reside in arid areas that are dependent on water supplies from melting glaciers. The water from the glaciers also supplies rivers that have in some cases been dammed for hydroelectric power. Some researchers believe that by 2030, many of the large ice caps on the highest Andes will be gone if current climate trends continue. In Patagonia on the southern tip of the continent, the large ice caps have retreated a full kilometer (0.6 mile) since the early 1990s and 10 km (6 miles) since the late 1800s. It has also been observed that Patagonian glaciers are receding at a faster rate than in any other region in the world.ref_harv|patagonia|BBC2|BBC2 The Northern Patagonian Ice Field lost 93 km² (35 mi²) of glacier area during the years between 1945 and 1975, and 174 km² (67 mi²) from 1975 to 1996, which indicates that the rate of retreat is increasing. This represents a loss of 8% of the ice field, with all glaciers experiencing significant retreat. The Southern Patagonian Ice Field has exhibited a general trend of retreat on 42 glaciers, while four glaciers were in equilibrium and two advanced during the years between 1944 and 1986. The largest retreat was on O'Higgins Glacier, which during the period 1896–1995 retreated 14.6 km (9.1 miles). The Perito Moreno Glacier is 30 km (18 mile) long and is a major outflow glacier of the Patagonian ice sheet, as well as the most visited glacier in Patagonia. Perito Moreno Glacier is presently in equilibrium, but has undergone frequent oscillations in the period 1947–96, with a net gain of 4.1 km (2.5 miles). This glacier has advanced since 1947, and has been essentially stable since 1992. Perito Moreno Glacier is one of three glaciers in Patagonia known to have advanced, compared to several hundred others in retreat.ref_harv|patagonia2|Skvarca and Naruse|Skvarca and Naruseref_harv|patagonia3|Cassasa|Cassasa. In the Aconcagau River Basin glacier retreat has resulted in a 20% loss in glacier area, declining from 151 km² to 121 km².ref_harv|patagonia4|Brown, Rivera and Acuna|Brown, Rivera and Acuna

Tropical glaciers

Tropical glaciers are located between the Tropic of Cancer and the Tropic of Capricorn, in the region that lies 23° 26′ 22″ north or south of the equator. Tropical glaciers are the most uncommon of all glaciers for a variety of reasons. Firstly, the tropics are the warmest part of the planet. Secondly, the seasonal change is minimal with temperatures warm year round, resulting in a lack of a colder winter season in which snow and ice can accumulate. Thirdly, few taller mountains can be found in these regions upon which enough cold air exists for the establishment of glaciers. All of the glaciers located in the tropics are on isolated high mountain peaks. Overall, tropical glaciers are smaller than those found elsewhere and are the most likely glaciers to show rapid response to changing climate patterns. A small temperature increase of only a few degrees can have almost immediate and adverse impact on tropical glaciers.ref_harv|tropic|Jankowski|Jankowski

Africa

With almost the entire continent of Africa located in the tropical and subtropical climate zones, glaciers are restricted to two isolated peaks and the Ruwenzori Range. Kilimanjaro, at 5,895 m (19,340 ft), is the highest peak on the continent. Since 1912 the glacier cover on the summit of Kilimanjaro has apparently retreated 75%, and the volume of glacial ice is now 80% less than it was a century ago due to both retreat and thinning.ref_harv|kilimanjaro4|Thompson|Thompson In the 14-year period from 1984 to 1998, one section of the glacier atop the mountain receded 300 m (980 ft).ref_harv|kilimanjaro|Wielochowski|Wielochowski A 2002 study determined that if current conditions continue, the glaciers atop Kilimanjaro will disappear sometime between 2015 and 2020.ref_harv|kilimanjaro3|Thompson, et alia|Thompson, et aliaref_harv|vanish|OSU|OSU A March 2005 report indicated that there is almost no remaining glacial ice on the mountain, and it is the first time in 11,000 years that barren ground has been exposed on portions of the summit.ref_harv|kilimanjaro|Guardian|Guardianref_harv|kilimanjaro5|Tyson|Tyson Researchers reported Kilimanjaro's glacier retreat was due to a combination of increased sublimation and decreased snow fall. ref_harv|tropic|Mote and Kaser|Mote and Kaser

The Furtwängler Glacier is located near the summit of Kilimanjaro. Between 1976 and 2000, the area of Furtwängler Glacier was cut almost in half, from 113,000 m² to 60,000 m².ref_harv|kilimanjaro6|Thompson2|Thompson2 During fieldwork conducted early in 2006, scientists discovered a large hole near the center of the glacier. This hole, extending through the 6 meter (20 ft) remaining thickness of the glacier to the underlying rock, is expected to grow and split the glacier in two by 2007.ref_harv|kilimanjaro4|Thompson|ThompsonTo the north of Kilimanjaro lies Mount Kenya, which at 5,199 m (17,057 ft) is the second tallest mountain on the African continent. Mount Kenya has a number of small glaciers that have lost at least 45% of their mass since the middle of the 20th century. According to research compiled by the U.S. Geological Survey (USGS), there were eighteen glaciers atop Mount Kenya in 1900, and by 1986 only eleven remained. The total area covered by glaciers was 1.6 km² (0.62 mi²) in 1900; however. by the year 2000 only about 25%, or 0.4 km² (0.15 mi²), remained.ref_harv|kenya|USGS2|USGS2 To the west of Mounts Kilimanjaro and Kenya, the Ruwenzori Range rises to 5,109 m (16,761 ft). Photographic evidence of this mountain range indicates a marked reduction in glacially covered areas over the past century. In the 35-year period between 1955 and 1990, glaciers on the Ruwenzori Range receded about 40%. It is expected that due to their proximity to the heavy moisture of the Congo region, the glaciers in the Ruwenzori Range may recede at a slower rate than those on Kilimanjaro or in Kenya.ref_harv|congo|Wielochowski2|Wielochowski2

outh America

A study by glaciologists of two small glaciers in South America reveals another retreat. More than 80% of all glacial ice in the northern Andes is concentrated on the highest peaks in small glaciers of approximately one km² (0.4 mi²) in size. A 1992 to 1998 observation of the Chacaltaya Glacier in Bolivia and Antizana Glacier in Ecuador indicated that between 0.6 m and 1.4 m (1.9 ft to 4.6 ft) of ice was lost per year on each glacier. Figures for Chacaltaya Glacier show a loss of 67% of its volume and 40% of its thickness over the same period. Chacaltaya Glacier has lost 90% of its mass since 1940 and is expected to disappear altogether sometime between 2010 and 2015. Research also indicates that since the mid-1980s, the rate of retreat for both of these glaciers has been increasing.ref_harv|andes|Francou|FrancouFurther south in Peru, the Andes are at a higher altitude overall, and there are approximately 722 glaciers covering an area of 723 km² (279 mi²). Research in this region of the Andes is less extensive but indicates an overall glacial retreat of 7% between 1977 and 1983.ref_harv|peru|USGS4|USGS4 The Quelccaya Ice Cap is the largest tropical icecap in the world, and all of the outlet glaciers from the icecap are retreating. In the case of Qori Kalis Glacier, which is Quelccayas' main outlet glacier, the rate of retreat had reached 155 m (508 ft) per year during the three year period of 1995 to 1998. The melting ice has formed a large lake at the front of the glacier since 1983, and bare ground has been exposed for the first time in thousands of years.ref_harv|southamerica|Byrd|Byrd

Oceania

On the large island of New Guinea, there is photographic evidence of massive glacial retreat since the region was first extensively explored by airplane in the early 1930s. Due to the location of the island within the tropical zone, there is little to no seasonal variation in temperature. The tropical location has a predictably steady level of rain and snowfall, as well as cloud cover year round, and there has been no noticeable change in the amount of moisture which has fallen during the 20th century. The 7 km² (2.7 mi²) glacial cap on Puncak Jaya is the largest on the island, and has retreated from one larger mass into several smaller glacial bodies since 1936. Of these smaller glaciers, research between 1973 and 1976 showed glacier retreat for the Meren Glacier of 200 m and 50 m (660 ft and 160 ft) for the Carstensz Glacier. The Northwall Firn, another large remnant of the icecap that once was atop Puncak Jaya, has itself split into several separate glaciers since 1936. Research presented in 2004 of IKONOS satellite imagery of the New Guinean glaciers provided a dramatic update. The imagery indicated that in the two years from 2000 to 2002, the East Northwall Firn had lost 4.5%, the West Northwall Firn 19.4% and the Carstensz 6.8% of their glacial mass. Researchers also discovered that, sometime between 1994 and 2000, the Meren Glacier disappeared altogether.ref_harv|meren|Kincaid and Klein|Kincaid and Klein Separate from the glaciers of Puncak Jaya, another small icecap known to have existed on the summit of Puncak Trikora completely disappeared sometime between 1939 and 1962.ref_harv|newguinea|Allison and Peterson|Allison and Peterson

Polar regions

Despite their proximity and importance to human populations, the mountain and valley glaciers of tropical and mid-latitude glaciers amount to only a small fraction of glacial ice on the Earth. About 99% of all freshwater ice is in the great ice sheets of polar and subpolar Antarctica and Greenland. These continuous continental-scale ice sheets, 3 km (1.8 miles) or more in thickness, cap much of the polar and subpolar land masses. Like rivers flowing from an enormous lake, numerous outlet glaciers transport ice from the margins of the ice sheet to the ocean.

Iceland

The northern Atlantic island nation of Iceland is home to the Vatnajökull, which is the largest ice cap in Europe. The Breiðamerkurjökull Glacier is one of the Vatnajökull outlet glaciers, and had receded by as much as 2 km (1.2 miles) between 1973 and 2004. In the early 20th century, Breiðamerkurjökull extended to within 250 m (820 ft) of the ocean, but by 2004 Breiðamerkurjökull's terminus had retreated three kilometers (1.86 miles) further inland. This glacier retreat exposed a rapidly expanding lagoon that is filled with icebergs calved from its front. The lagoon is 110 m (360 ft) deep and nearly doubled its size between 1994 and 2004. Mass-balance measurements of Iceland's glaciers show alternating positive and negative mass balance of glaciers during the period 1987–95, but the mass balance has been predominantly negative since. On Hofsjokull ice cap, mass balance has been negative each year from 1995-2005.

Most of the Icelandic glaciers retreated rapidly during the warm decades from 1930 to 1960, slowing down as the climate cooled during the following decade, and started to advance after 1970. The rate of advance peaked in the 1980s, after which it slowed down as a consequence of rapid warming of the climate that has taken place since the mid-1980s. Most glaciers in Iceland began to retreat after 1990, and by 2000 all monitored non-surge type glaciers in Iceland were retreating. An average of 45 non-surging termini were monitored each year by the Icelandic Glaciological Society from 2000-2005.ref_harv|termini|Sigurdsson|Sigurdsson

Canada

The Canadian Arctic islands have a number of substantial ice caps, including Penny and Barnes Ice Cap on Baffin Island, Bylot Ice Cap on Bylot Island, and Devon Ice Cap on Devon Island. All of these ice caps have been thinning and receding slowly. The Barnes and Penny ice caps on Baffin Island have been thinning at over 1 m (3.1 ft) per year in the lower elevations from 1995 to 2000. Overall, between 1995 and 2000, ice caps in the Canadian Arctic lost 25 km³ (6 miles³) of ice per year.ref_harv|arctic|Abdalati|Abdalati Between 1960 and 1999, the Devon Ice Cap lost 67 km³ (16 mi³) of ice, mainly through thinning. All major outlet glaciers along the eastern Devon Ice Cap margin have retreated 1–3 km (0.6–1.8 miles) since 1960.ref_harv|devon|Burgess and Sharpa|Burgess and Sharpa On the Hazen Plateau of Ellesmere Island, the Simmon Ice Cap has lost 47% of its area since 1959.ref_harv|simmons|Braun, et alia|Braun, et alia If the current climatic conditions continue, the remaining glacial ice on the Hazen Plateau will be gone around 2050. On August 13, 2005 the Ayles Ice Shelf broke free from the north coast of Ellesmere Island, the 25.5 square mile (66 km²) ice shelf drifted into the Arctic Ocean.ref_harv|Ayles|National Geographic|National Geographic. This followed the splitting of the Ward Hunt Ice Shelf in 2002. The Ward Hunt has lost 90% of its area in the last century.ref_harv|Ward Hunt IS|Mueller, Vincent and Jeffries|Mueller, Vincent and Jeffries

Northern Europe

Arctic islands north of Norway, Finland and Russia have all shown evidence of glacier retreat. In the Svalbard archipelago, the island of Spitsbergen has numerous glaciers. Research indicates that Hansbreen Glacier on Spitsbergen retreated 1.4 km (0.87 mi) from 1936 to 1982 and another 400 m (1,300 ft) during the 16-year period from 1982 to 1998.ref_harv|svalbard|Glowacki|Glowacki Blomstrandbreen, a glacier in the King's Bay area of Spitsbergen, has retreated approximately 2 km (1.2 miles) in the past 80 years. Since 1960 the average retreat of Blomstrandbreen has been about 35 m (110 ft) a year, and this average was enhanced due to an accelerated rate of retreat since 1995.ref_harv|spit|Greenpeace|Greenpeace Similarly, the Midre Lovenbreen Glacier retreated 200 m (656 ft) between 1977 and 1995.ref_harv|midre|Rippin, et alia|Rippin, et alia In the Novaya Zemlya archipelago north of Russia, research indicates that in 1952 there was 208 km (129 mi) of glacier ice along the coast. By 1993 this had been reduced by 8% to 198 km (123 mi) of glacier coastline.ref_harv|coast|Aleksey|Aleksey

Greenland

In Greenland, glacier retreat has been observed in outlet glaciers, resulting in an increase of the ice flow rate and destabilization of the mass balance of the ice sheet that is their source. The period since 2000 has brought retreat to several very large glaciers that had long been stable. Three glaciers that have been researched—Helheim Glacier, Kangerdlugssuaq Glacier, and Jakobshavn Isbræs—jointly drain more than 16% of the Greenland Ice Sheet. In the case of Helheim Glacier, researchers used satellite images to determine the movement and retreat of the glacier. Satellite images and aerial photographs from the 1950s and 1970s show that the front of the glacier had remained in the same place for decades. In 2001 the glacier began retreating rapidly, and by 2005 the glacier had retreated a total of 7.2 km (4.5 miles), accelerating from 70 ft (20 m) per day to 110 ft (35 m) per day during that period.ref_harv|greenland|Howat|Howat

Jakobshavn Isbræ in west Greenland, a major outlet glacier of the Greenland Ice Sheet, is the fastest moving glacier in the world over the past half century. It had been moving continuously at speeds of over 24 m (78 ft) per day with a stable terminus since at least 1950. In 2002, the 12 km (7.5 mile) long floating terminus of the glacier entered a phase of rapid retreat, with the ice front breaking up and the floating terminus disintegrating and accelerating to a retreat rate of over 30 m (100 ft) per day. On a shorter timescale, portions of the main trunk of Kangerdlugssuaq Glacier that were flowing at 15 m (50 ft) per day from 1988 to 2001 were measured to be flowing at 40 m (130 ft) per day in the summer of 2005. Not only has Kangerdlugssuaq retreated, it has also thinned by more than 100 m (330 ft).ref_harv|greenland2|Truffer|Truffer

The rapid thinning, acceleration and retreat of Helheim, Jakobshavns and Kangerdlugssuaq glaciers in Greenland, all in close association with one another, suggests a common triggering mechanism, such as enhanced surface melting due to regional climate warming. The current flow speeds at the terminus are too fast to be caused solely by internal deformation of the ice, implying that an increase in basal sliding forced by additional meltwater production is the probable cause of the velocity increases. This was termed the "Jakobshavns Effect" by Terence Hughes at the University of Maine in 1986.ref_harv|effects|Hughes|Hughes

Antarctica

The climate of Antarctica is one of intense cold and great aridity. Most of the world's freshwater ice is contained in the great ice sheets that cover the continent of Antarctica. The most dramatic example of glacier retreat on the continent is the loss of large sections of the Larsen Ice Shelf on the Antarctic Peninsula. Ice shelves are not stable when surface melting occurs, and the collapse of Larsen Ice Shelf has been caused by warmer melt season temperatures that have led to surface melting and the formation of shallow ponds of water on the ice shelf. The Larsen Ice Shelf lost 2,500 km² (965 mi²) of its area from 1995 to 2001. In a 35-day period beginning on January 31, 2002, about 3,250 km² (1,250 mi²) of shelf area disintegrated. The ice sheet is now 40% the size of its previous minimum stable extent.ref_harv|larson|NSaIDC2|NSaIDC2 Recent studies by the British Antarctic Survey have anticipated a potential breakup of the George VI Ice Shelf due to warming ocean currents resulting from global warming.ref_harv|george|Bentley & Hodgson|Bentley & Hodgson

Pine Island Glacier, an Antarctic outflow glacier that flows into the Amundsen Sea, thinned 3.5 ± 0.9 m (11.5 ± 3 ft) per year and retreated a total of 5 km (3 mi) in 3.8 years. The terminus of the Pine Island Glacier is a floating ice shelf, and the point at which it is afloat is retreating 1.2 km (0.7 mi) per year. This glacier drains a substantial portion of the West Antarctic Ice Sheet and has been referred to as the weak underbelly of this ice sheet.ref_harv|antarctica|Rignot|Rignot This same pattern of thinning and accelerated retreat is evident on the neighboring Thwaites Glacier. Additionally, the Dakshin Gangotri Glacier, a small outlet glacier of the Antarctic ice sheet, receded at an average rate of 0.7 m (2.2 ft) per year from 1983 to 2002. On the Antarctic Peninsula, which is the only section of Antarctica that extends well north of the Antarctic Circle, there are hundreds of retreating glaciers. In one study of 244 glaciers on the peninsula, 212 have retreated an average of 600 m (2,000 ft) from where they were when first measured in 1953.ref_harv|ave|AAAS|AAAS The greatest retreat was seen in Sjogren Glacier, which is now 13 km (8 miles) further inland than where it was in 1953. There are 32 glaciers that were measured to have advanced; however, these glaciers showed only a modest advance averaging 300 meters (1,000 ft) per glacier, which is significantly smaller than the massive retreat observed.ref_harv|peninsula|BBC3|BBC3

On June 5, 2007, the British Antarctic Survey announced that the flow-rate of over 300 previously unstudied glaciers in Antarctica had increased by an average of 12% between 1993 and 2003. The increase in speed is thought to be caused by melting of lower glaciers that feed into the sea. The results, obtained by radar measurements taken using European Remote-Sensing Satellites 1 & 2, are to be published in the Journal of Geophysical Research and add to concerns that sea level rises during the 21st century may be greater than previously expected.ref_harv|BAS2007-06-05|BAS|BAS ref_harv|Inde2007-06-06|Independent|Independent

Impacts of glacier retreat

The continued retreat of glaciers will have a number of different quantitative impacts. In areas that are heavily dependent on water runoff from glaciers that melt during the warmer summer months, a continuation of the current retreat will eventually deplete the glacial ice and substantially reduce or eliminate runoff. A reduction in runoff will affect the ability to irrigate crops and will reduce summer stream flows necessary to keep dams and reservoirs replenished. This situation is particularly acute for irrigation in South America, where numerous artificial lakes are filled almost exclusively by glacial melt.ref_harv|peru2|BBC|BBC Central Asian countries have also been historically dependent on the seasonal glacier melt water for irrigation and drinking supplies. In Norway, the Alps, and the Pacific Northwest of North America, glacier runoff is important for hydropower.

Some of this retreat has resulted in efforts to slow down the loss of glaciers in the Alps. To retard melting of the glaciers used by certain Austrian ski resorts, portions of the Stubai and Pitztal Glaciers were covered with plastic. In Switzerland plastic sheeting is also used to reduce the melt of glacial ice used as ski slopes.ref_harv|plastic|ENN|ENN While covering glaciers with plastic sheeting may prove advantageous to ski resorts on a small scale, this practice is not expected to be economically practical on a much larger scale.

Many species of freshwater and saltwater plants and animals are dependent on glacier-fed waters to ensure the cold water habitat to which they have adapted. Some species of freshwater fish need cold water to survive and to reproduce, and this is especially true with salmon and cutthroat trout. Reduced glacial runoff can lead to insufficient stream flow to allow these species to thrive. Alterations to the ocean currents, due to increased freshwater inputs from glacier melt, and the potential alterations to thermohaline circulation of the worlds oceans, may impact existing fisheries upon which humans depend as well.

The potential for major sea level rise depends mostly on a significant melting of the polar ice caps of Greenland and Antarctica, as this is where the vast majority of glacial ice is located. The British Antarctic Survey has determined from climate modeling that for at least the next 50 years, snowfall on the continent of Antarctica should continue to exceed glacial losses from global warming. The amount of glacial loss on the continent of Antarctica is not increasing significantly, and it is not known if the continent will experience a warming or a cooling trend, although the Antarctic Peninsula has warmed in recent years, causing glacier retreat in that region.ref_harv|BAS|BAS|BAS If all the ice on the polar ice caps were to melt away, the oceans of the world would rise an estimated 70 m (230 ft). However, with little major melt expected in Antarctica, sea level rise of not more than 0.5 m (1.6 ft) is expected through the 21st century, with an average annual rise of 0.004 m (0.013 ft) per year. Thermal expansion of the world's oceans will contribute, independent of glacial melt, enough to double those figures.ref_harv|sea|NSIDC2|NSIDC2

See also

*Uunartoq Qeqertoq
*Nguzumpa glacier

References

Cited references


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date=March 14, 2005
publisher=The Guardian
url=http://www.guardian.co.uk/climatechange/story/0,,1437901,00.html

*note_label|Vatnajokull|Hall|Hallcite web
author=Dorothy Hall
title= Receding Glacier in Iceland
work=EO Newsroom: New Images
url=http://earthobservatory.nasa.gov/Newsroom/NewImages/images.php3?img_id=4794
accessdate=February 18 | accessyear=2006

*note_label|greenland|Howat|Howatcite web
author=Ian Howat
title=Rapidly accelerating glaciers may increase how fast the sea level rises
work=UC Santa Cruz, November 14–27, 2005 Vol. 10, No. 14
url=http://currents.ucsc.edu/05-06/11-14/glacier.asp
accessdate=November 27 | accessyear=2005

*note_label|effects|Hughes|Hughescite journal
author=T. Hughes
title=The Jakobshanvs effect
journal=Geophysical Research Letters
year=1986
volume=13
issue=1
pages=46–48
url=http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=1986GeoRL..13...46H&db_key=PHY&data_type=HTML&format=
doi=10.1029/GL013i001p00046

*note_label|italy|IGC|IGCcite web
author=Italian Glaciological Committee
title=Glaciers
work=Glaciers in Italy
url=http://www.disat.unimib.it/comiglacio/glaciologicalcommittee.htm
accessdate=September 8 | accessyear=2005

*note_label|glacier|IPCC|IPCCcite web
author=Intergovernmental panel on climate change
title=Graph of 20 glaciers in retreat worldwide
work=Climate Change 2001 (Working Group I: The Scientific Basis)
url=http://www.grida.no/climate/ipcc_tar/wg1/fig2-18.htm
accessdate=February 14 | accessyear=2006

*note_label|climate|IPCC2|IPCC2cite web
author=Intergovernmental panel on climate change
title=2.2.5.4 Mountain glaciers
work=Climate Change 2001 (Working Group I: The Scientific Basis)
url=http://www.grida.no/climate/ipcc_tar/wg1/064.htm
accessdate=February 14 | accessyear=2006

*note_label|tropic|Jankowski|Jankowskicite web
author=Michael Jankowski
title=Tropical Glacier Retreat
work=RealClimate
url=http://www.realclimate.org/index.php?p=157
accessdate=June 3 | accessyear=2005

*note_label|effects|Kaser|Kasercite journal
author=G.Kaser and H. Osmaston
title=Tropical Glaciers
book=UNESCO, CAMBRIDGE UNIVERSITY PRESS
year=2002
url=http://geowww.uibk.ac.at/glacio/LITERATUR/

*note_label|Ak-shirak|Khromova, Dyurgerov and Barry|Khromova, Dyurgerov and Barrycite journal
author=T. E. Khromova, M. B. Dyurgerov and R. G. Barry
title=Late-twentieth century changes in glacier extent in the Ak-shirak Range, Central Asia, determined from historical data and ASTER imagery (Abstract)
journal=American Geophysical Union
year=2003
volume=30
issue=16
pages=
url=http://www.agu.org/pubs/crossref/2003/2003GL017233.shtml

*note_label|meren|Kincaid and Klein|Kincaid and Kleincite web
author=Joni L. Kincaid and Andrew G. Klein
title=Retreat of the Irian Jaya Glaciers from 2000 to 2002 as Measured from IKONOS Satellite Images
format=pdf
work=61st Eastern Snow Conference Portland, Maine, USA 2004
url=http://www.easternsnow.org/proceedings/2004/kincaid_and_klein.pdf#search='meren%20glacier'
accessdate=2004

*note_label|Tien|Kirby|Kirbycite news
first=Alex
last=Kirby
title=Kazakhstan's glaciers 'melting fast'
date=September 4, 2003
publisher=BBC News
url=http://news.bbc.co.uk/2/hi/science/nature/3077422.stm

*note_label|NVE|Kjøllmoen|Kjøllmoencite web
author=Bjarne Kjøllmoen (Ed.), Liss M. Andreassen, Hallgeir Elvehøy, Miriam Jackson, Arve M. Tvede, Tron Laumann and Rianne H. Giesen
title=Glaciological investigations in Norway 2006
format=pdf
work=NVE Report 1 2007
url=http://www.nve.no/modules/module_109/publisher_view_product.asp?iEntityId=8666
accessdate=2007-08-29

*note_label|lemon|Miller and Pelto|Miller and Peltocite web
author=Maynard M. Miller, Mauri S. Pelto
title=Mass Balance Measurements of the Lemon Creek Glacier, Juneau Icefield, Alaska, 1953–2005
url=http://www.nichols.edu/departments/glacier/Lemon.html
accessmonthday = February| accessyear=2006

*note_label|realclimate|Mölg|Mölgcite web
author=Thomas Mölg
title=Worldwide glacier retreat
work=RealClimate
url=http://www.realclimate.org/index.php?p=129
accessdate=March 18 | accessyear=2005

*note_label|alaska|Molnia|Molniacite web
author=Bruce F. Molnia
title=Fast-flow advance and parallel rapid retreat of non-surging tidewater glaciers in Icy Bay and Yakutat Bay, Alaska 1888–2003
url=http://gsa.confex.com/gsa/2003AM/finalprogram/abstract_65710.htm
accessdate=September 6 | accessyear=2003

*note_label|alaska|Molnia2|Molnia2cite web
author=Bruce F. Molnia
title=Repeated Rapid Retreats of Bering Glacier by Disarticulation—The Cyclic Dynamic Response of an Alaskan Glacier System
url=http://www.agu.org/meetings/fm05/fm05-sessions/fm05_C42A.html
accessmonthday=December | accessyear=2005

*note_label|tropic|Mote and Kaser|Mote and KaserCitation | first1=Philip W. | last1=Mote
first2=Georg | last2=Kaser | journal=American Scientist | volume=95 | issue=4 | year=2007
title=The Shrinking Glaciers of Kilimanjaro: Can Global Warming Be Blamed?
pages=pp. 318-325

*note_label|swiss2|MSNBC|MSNBCcite web
author=MSNBC
title=Swiss glaciers continue shrinking, report finds
url=http://www.msnbc.msn.com/id/11254319/
accessmonthday=August | accessyear=2006

*note_label|Ward Hunt IS|Mueller, Vincent and Jeffries|Mueller, Vincent and Jeffriescite web
author=Mueller, Vincent and Jeffries
title=Break-up of the largest Arctic ice shelf and associated loss of an epishelf lake
url=http://www.agu.org/pubs/crossref/2003/2003GL017931.shtml
accessmonthday=December | accessyear=2006

*note_label|Ayles|National Geographic|National Geographicite web
author=National Geographic
title=Giant Ice Shelf Breaks Off in Canadian Arctic
url=http://news.nationalgeographic.com/news/2006/12/061229-arctic-ice_2.html
accessmonthday=December | accessyear=2006

*note_label|Pamir|Novikov|Novikovcite web
author=V. Novikov
title=Tajikistan 2002, State of the Environment Report
work=Climate Change
url=http://enrin.grida.no/htmls/tadjik/soe2001/eng/htmls/climate/state.htm
accessdate=March 3 | accessyear=2003

*note_label|glims|NSIDC|NSIDCcite web
author=National Snow and Ice Data Center
title=Global glacier recession
work=GLIMS Data at NSIDC
url=http://nsidc.org/data/glims/glaciermelt/index.html
accessdate=February 14 | accessyear=2006

*note_label|sea|NSIDC2|NSIDC2cite web
author=National Snow and Ice Data Center
title=Is Global Sea Level Rising?
work=
url=http://nsidc.org/sotc/sea_level.html
accessdate=March 14 | accessyear=2005

*note_label|larson|NSaIDC2|NSaIDC2cite web
author=National Snow and Ice Data Center
title=Larsen B Ice Shelf Collapses in Antarctica
work=The Cryosphere, Where the World is Frozen
url=http://nsidc.org/iceshelves/larsenb2002/
accessdate=March 21 | accessyear=2002

*note_label|vanish|OSU|OSUcite web
author=Ohio State University
title=African Ice Core Analysis reveals catastrophic droughts, shrinking ice fields and civilization shifts
work=Ohio State Research News
url=http://researchnews.osu.edu/archive/kilicores.htm
accessdate=October 3 | accessyear=2002

*note_label|surge|Pedersen|Pedersencite web
author= Fran Pedersen
title=Surging Glaciers
work=Surging Glaciers
url=http://www.gi.alaska.edu/ScienceForum/ASF2/241.html
accessdate=July 13 | accessyear= 1978

*note_label|cascades|Pelto|Peltonote_label|cascades|Pelto|2cite web
author=Mauri S. Pelto (Nichols College)
title=The Disequilibrium of North Cascade, Washington Glaciers 1984–2004
work=In "Hydrologic Processes"
url=http://www.nichols.edu/departments/glacier/diseqilibrium.html
accessdate=February 14 | accessyear=2006

*note_label|cascades2|Pelto3|Pelto3cite journal
author= Mauri S. Pelto; Cliff Hedlund
title= Terminus behavior and response time of North Cascade glaciers, Washington, U.S.A.
journal= Journal of Glaciology
year= 2001
volume= 47
issue= 158
pages= 497–506
url= http://www.nichols.edu/departments/glacier/terminus_behavior_and_response_t.htm
doi= 10.3189/172756501781832098

*note_label|cascades3|Pelto4|Pelto4cite web
author=Mauri S. Pelto (Nichols College)
title=North Cascade Glacier Terminus Behavior
url=http://www.nichols.edu/departments/glacier/north%20cascade%20glacier%20retreat.htm
accessdate=February 14 | accessyear=2006

*note_label|alaska|Pelto5|Pelto5cite web
author=Mauri S. Pelto
title=Recent Global Glacier Retreat Overview
url=http://www.nichols.edu/departments/glacier/glacier_retreat.htm
accessmonthday = February| accessyear=2006

*note_label|alaska|Pelto6|Pelto6cite web
author=Mauri S. Pelto and Maynard M. Miller
title=Terminus Behavior of Juneau Icefield Glaciers 1948–2005
work=North Cascade Glacier Climate Project
url=http://www.nichols.edu/departments/Glacier/juneau%20icefield.htm
accessmonthday = December| accessyear=2006

*note_label|nichols2|Pelto and Hartzell|Pelto and Hartzellcite journal
author=Pelto, M.S. and Hartzell, P.L.
title=Change in longitudinal profile on three North Cascades glaciers during the last 100 years
journal=Hydrologic Processes
year=2004
volume=18
issue=
pages=1139–1146
url=http://www.nichols.edu/departments/glacier/Longitudinal%20Profile.pdf
doi=10.1002/hyp.5513
format=PDF

*note_label|taku|Pelto and Miller|Pelto and Millercite web
author=Mauri S. Pelto, Maynard M. Miller
title=Mass Balance of the Taku Glacier, Alaska 1946–1986
format=pdf
url=http://crevassezone.org/Data/Reports/38-TakuMB46-86.pdf
accessdate=1990

*note_label|gtnp|Peterson|Petersoncite news
first=Bryce
last=Petersen
title=Glaciers going...going
date=August 24, 2005
publisher=Standard-Examiner
url=http://www.standard.net/standard.php/features/60097?printable=story

*note_label|asia|Rai, Guring, et alia|Rai, Guring, et aliacite web
author=Sandeep Chamling Rai, Trishna Gurung, et alia
title=An Overview of Glaciers, Glacier Retreat and Subsequent Impacts in Nepal, India and China
format=pdf
work=WWF Nepal Program
url=http://assets.panda.org/downloads/himalayaglaciersreport2005.pdf
accessdate=March 2005

*note_label|antarctica|Rignot|Rignotcite journal
author=E. J. Rignot
title=Fast Recession of a West Antarctic Glacier
journal=Science
year=1998 (July 24)
volume=281
issue=5376
pages=549–551
url=http://www.sciencemag.org/cgi/content/abstract/281/5376/549
doi=10.1126/science.281.5376.549

*note_label|midre|Rippin, et alia|Rippin, et aliacite journal
author= David Rippin, Ian Willis, Neil Arnold, Andrew Hodson, John Moore, Jack Kohler and Helgi Bjornsson
title= Changes in Geometry and Subglacial Drainage of Midre Lovenbreen, Svalbard, Determined from Digital Elevation Models
journal= Earth Surface Processes and Landforms
year= 2003
volume= 28
issue=
pages= 273–298
url= http://www.ulapland.fi/home/hkunta/jmoore/pdfs/Rippin_et_al_2003.pdf
doi= 10.1002/esp.485
format=PDF

*note_label|volumes|Salinger|Salingercite web
author=Salinger, Jim and Andrew Willsman
title=Annual Glacier Volumes in New Zealand 1995-2005
format=pdf
work=Statistics New Zealand
url=http://www.stats.govt.nz/NR/rdonlyres/51DEB609-9C85-490B-A561-048485BA6989/0/akl2007_014_SNZ_GlacierFinal.pdf
accessdate=2007-09-01

*note_label|patagonia2|Skvarca and Naruse|Skvarca and Narusecite journal
author= Skvarca, P. and R. Naruse
title=Dynamic behavior of glaciar Perito Moreno, Southern Patagonia
journal=Annals Of Glaciology
year=1997
volume=24
pages=268–271
url=http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=1986GeoRL..13...46H&db_key=PHY&data_type=HTML&format=

*note_label|swiss|SFIoTZ|SFIoTZcite web
author=Swiss Federal Institute of Technology Zurich
title=Swiss Glacier Monitoring Network
work=Variations of Grosser Aletschgletscher
url=http://glaciology.ethz.ch/messnetz/glacierlist.html
accessdate=August 18 | accessyear=2005

*note_label|termini|Sigurdsson|Sigurdssoncite web
author=Sigurdsson, Oddur, Trausti Jonsson and Tomas Johannesson
title=Relation between glacier-termini variations and summer temperature in Iceland since 1930
format=pdf
work=
publisher=Hydrological Service, National Energy Authority
url=http://www.igsoc.org/annals/46/a46A210.pdf
accessdate=September 7 |accessyear=2007

*note_label|kilimanjaro4|Thompson|Thompsoncite web
last =
first =
authorlink =
coauthors =
year =
url = http://www.geology.ohio-state.edu/news_detail.php?newsId=1
title = Snows of Kilimanjaro Disappearing, Glacial Ice Loss Increasing
format =
work =
publisher = Ohio State University
accessdate = August 31 | accessyear =2006

*note_label|kilimanjaro6|Thompson2|Thompson2cite web
last = Thompson
first = Lonnie G., et al
authorlink =
coauthors =
year =
url = http://www.geo.umass.edu/climate/doug/pubs/thompson_etal_sci02.pdf
title = Kilimanjaro Ice Core Records: Evidence of Holocene Climate Change in Tropical Africa
format = pdf
work =
publisher = Science
accessdate = August 31 | accessyear =2006

*note_label|kilimanjaro3|Thompson, et alia|Thompson, et aliacite journal
author=Lonnie G. Thompson, et alia
title=Kilimanjaro Ice Core Records: Evidence of Holocene Climate Change in Tropical Africa
journal=Science
year=2002 (October 18)
volume=298
issue=5593
pages=589–593
url=http://www.sciencemag.org/cgi/content/abstract/298/5593/589
pmid=12386332

*note_label|Trabant|Trabant|Trabantcite web
author=Trabant, D.C., R.S. March, and D.S. Thomas
title=Hubbard Glacier, Alaska: Growing and Advancing in Spite of Global Climate Change and the 1986 and 2002 Russell Lake Outburst Floods
url=http://pubs.usgs.gov/fs/fs-001-03/fs-001.03.pdf
accessdate=2006
format=PDF

*note_label|greenland2|Truffer|Truffercite web
author=M Truffer, University of Alaska Fairbanks; M Fahnestock, University of New Hampshire
title=The Dynamics of Glacier System Response: Tidewater Glaciers and the Ice Streams and Outlet Glaciers of Greenland and Antarctica I
url=http://www.agu.org/meetings/fm05/fm05-sessions/fm05_C41A.html
accessdate=2005

*note_label|kilimanjaro5|Tyson|Tysoncite web
last = Tyson
first = Peter
authorlink =
coauthors =
year =
url = http://www.pbs.org/wgbh/nova/kilimanjaro/vanishing.html
title = Vanishing into Thin Air
format =
work = Volcano Above the Clouds
publisher = NOVA
accessdate = August | accessyear =2006

*note_label|unep|UNEP|UNEPcite web
author=United Nations Environment Programme
title=Global Warming Triggers Glacial Lakes Flood Threat – April 16, 2002
work=UNEP News Release 2002/20
url=http://www.unep.org/Documents.multilingual/Default.asp?DocumentID=245&ArticleID=3042&l=en
accessdate=April 16 | accessyear=2002

*note_label|gnp|USGS|USGScite web
author=U.S. Geological Survey
title=Glacier Monitoring in Glacier National Park
url=http://www.nrmsc.usgs.gov/research/glaciers.htm
accessdate=April 25 | accessyear=2003

*note_label|kenya|USGS2|USGS2cite web
author=U.S. Geological Survey
title=Glaciers of Africa
work=U.S. Geological Survey Professional Paper 1386-G-3
format=pdf
url=http://pubs.usgs.gov/prof/p1386g/africa.pdf#search='USGS%20Mount%20Kilimanjaro%20glacier'
accessdate=

*note_label|newzealand|USGS3|USGS3cite web
author=U.S. Geological Survey, U.S.Department of the Interior
title=Glaciers of New Zealand
work=
url=http://pubs.usgs.gov/prof/p1386h/nzealand/nzealand2.html
accessdate=May 4 | accessyear=2000

*note_label|peru|USGS4|USGS4cite web
author=U.S. Geological Survey, U.S.Department of the Interior
title=Peruvian Cordilleras
work=
url=http://pubs.usgs.gov/prof/p1386i/peru/occident.html
accessdate=February 9 | accessyear=1999

*note_label|mont|USGS5|USGS5cite web
author=U.S. Geological Survey, U.S.Department of the Interior
title=Glacier Retreat in Glacier National Park, Montana
work=
url=http://nrmsc.usgs.gov/research/glacier_retreat.htm
accessdate=April 25 | accessyear=2003

*note_label|world|WGMS|WGMScite web
author=World Glacier Monitoring Service
title=Home page
work=
url=http://www.geo.unizh.ch/wgms/fog.html
accessdate=December 20 | accessyear=2005

*note_label|kilimanjaro|Wielochowski|Wielochowskicite web
author=Andrew Wielochowski
title=Glacial recession on Kilimanjaro
url=http://www.kilimanjaro.cc/glacial-recession.htm
accessdate=October 6 | accessyear=1998

*note_label|congo|Wielochowski2|Wielochowski2cite web
author=Andrew Wielochowski
title=Glacial recession in the Rwenzori
url=http://www.kilimanjaro.cc/rwenzoriglaciers.htm
accessdate=July 20 | accessyear=2001

*note_label|wyoming|WWRDSL|WWRDSLcite web
author=Wyoming Water Resources Data System Library
title=Glacial Icemelt in the Wind River Range, Wyoming
url=http://library.wrds.uwyo.edu/wrp/90-16/90-16.html
accessdate=July 11 | accessyear=1990

General references


*cite web
author=Michael Pidwirny
title=Glacial Processes
work=PhysicalGeography.net
url=http://www.physicalgeography.net/fundamentals/10ae.html
accessdate=February 2 | accessyear=2006

*cite web
author=University College London
title=Climate change and the aquatic ecosystems of the Rwenzori Mountains, Uganda
work=Glaciology—assessing the magnitude of current glacial recession
url=http://www.geog.ucl.ac.uk/~rtaylor/data_disk/rwenzori/rwenzori_fo_ir.htm
accessdate=September 3 | accessyear=2003

*cite web
author=Andrew Wielochowski
title=Glacial recession on Kilimanjaro
work=
url=http://www.kilimanjaro.cc/glacial-recession.htm
accessdate=October 6 | accessyear=1998

*cite web
author=National Park Service, U.S. Department of the Interior
title=Icefields and Glaciers
work=Tongass National Forest, Forest Facts
url=http://www.fs.fed.us/r10/tongass/forest_facts/resources/geology/icefields.htm
accessdate=July 10 | accessyear=2002

*cite web
author=NOAA,
title=Arctic Change
work=Study of Environmental Arctic Change
url=http://www.arctic.noaa.gov/detect/ice-glacier.shtml
accessdate=February 15 | accessyear=2006

Additional reading and external links


*cite journal
author=Aniya, M. and Y.Wakao
title=Glacier variations of Heilo Patagonico Norte, Chile between 1945–46 and 1995–96
journal=Bulletin of Glacier Research
year=1997
volume=15
issue=
pages=11–18
url=

*cite journal
author=Hall M.H. and Fagre, D.B
title=Modeled Climate-Induced Glacier Change in Glacier National Park, 1850–2100
journal=BioScience
year=2003
volume=53
issue=
pages=131–140
url=
doi=10.1641/0006-3568(2003)053 [0131:MCIGCI] 2.0.CO;2
doilabel=10.1641/0006-3568(2003)053[0131:MCIGCI]2.0.CO;2

*cite book
author=Hastenrath, S.
year=2008
title=Recession of Equatorial Glaciers: A Photodocumentation
isbn=978-0-9729033-3-2
url=http://www.sundogpublishing.com/Hastenrath/Announcement.html
publisher=Sundog Publishing | location=Madison, WI

*cite book
author=IUGG(CCS)/UNEP/UNESCO
year=2005
title=Fluctuations of Glaciers 1995–2000, Vol. VIII
editor=Haeberli, W., Zemp, M., Frauenfelder, R., Hoelzle, M. and Kääb, A.
publisher=World Glacier Monitoring Service | location=Paris

*cite journal
author=Pelto, M.S. and Hartzell, P.L.
title=Change in longitudinal profile on three North Cascades glaciers during the last 100 years
journal=Hydrologic Processes
year=2004
volume=18
issue=
pages=1139–1146
url=
doi=10.1002/hyp.5513

*cite journal
author=Pelto, M.S. and Hedlund, C.
title=The terminus behavior and response time of North Cascade glaciers
journal=Journal of Glaciology
year=2001
volume=47
issue=
pages=497–506
url=
doi=10.3189/172756501781832098

*cite web
author=
title=United Nations Environment Programme: Global Outlook for Ice and Snow
work=
url=http://www.unep.org/geo/geo%5Fice/
accessdate=September 9 | accessyear=2007

* [http://www.glaciares.org Information on the recession of the glaciers of the Spanish Pyrenees]


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