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Glacier and Permafrost Signals of 20th-Century Warming

Published online by Cambridge University Press:  20 January 2017

Wilfried Haeberli
Wilfried Haeberli*
Affiliation:
Versuchsanstalt für Wasserbau, Hydrologie und Glaziologie, ΕΤΗ-Zentrum, CH 8092 Zürich, Gloriastrasse 37/39, Switzerland
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Abstract

Currently-available evidence of 20th-century warming from glaciers and permafrost is briefly reviewed. The signals are clear and strong: warming of polar firn and permafrost, and mass losses of glaciers at lower latitudes, were most striking towards the middle of the century. The easily observable length-reduction of mountain glaciers confirms the global character of the evolution. A probably intermittent reversal of the trend was observed in places after about 1950.

Type
Research Article
Information
Annals of Glaciology , Volume 14 , 1990 , pp. 99 - 101
Copyright
Copyright © International Glaciological Society 1990

Introduction

Due to the slowness of heat diffusion and the retarding effect of latent heat exchange, secular climatic trends are clearly preserved in mass and temperature changes of glaciers and permafrost. For this reason perennial land-ice bodies are key parameters for climate system monitoring (Wood, Reference Wood1988). An attempt is here made to mention briefly the available information, outline ideas for their interpretation, and demonstrate the advantages of a comprehensive approach which includes both glaciers and permafrost.

Glacier Geometry

Standardized data on changes in surface area, thickness, volume, mass and length of mountain glaciers are being collected internationally and published by the World Glacier Monitoring Service (WGMS) of the International Commission on Snow and Ice (ICSI) within the framework of GEMS/ UNEP, FAGS/ICSU and UNESCO/IHP programmes (Haeberli, Reference Haeberli, Müller, Alean and Bösch1989). Emphasis is on mass balance (here its specific value, b) and length changes of glaciers (Δ1).

Direct glacier mass-balance observations using glaciological methods (stakes and pits) started mainly after World War II, but data concerning the whole 20th century, predominantly collected by the geodetic/photogrammetric method (repeated precision mapping), are available for the European Alps (Reference Finsterwalder and RentschFinsterwalder and Rentsch, 1980; cf. Chen and Funk, in press). Mean values of b over the entire period vary between −2 and −6 dm a−1.

Glacier length variations reflect changes in b after a reaction time which depends on the ratio between the flowline-length in the ablation area and the kinematic wave velocity. Advance and retreat rates of glacier margins are, however, often influenced also by local orographic conditions; mechanically unstable glaciers (surges, calving) and those that are heavily debris-covered must be excluded from direct climatic interpretation. Scatter in Δ1 values due to orographic complications can be reduced by averaging measurements from more than one glacier and the influence of different reaction times can be taken into account by classifying glaciers according to length. Figure 1 presents data from the Swiss Alps. The overall picture is a pronounced retreat of glacier tongues, the absolute amount being related to glacier length.

From continuity (Paterson, Reference Paterson1981), an assumed initial step change in mass balance (Δb) enabling a given Δ1 can be estimated from the ablation at the glacier margin multipled by Δ1/1, where 1 is total glacier length. Values of Δb calculated in this way for all categories A through D in Figure 1 are −5 to −10 dm a−1. Roughly half this amount, or −2.5 to −5 dm a−1, corresponds to the average b value for steadily adjusting glaciers. Hence, the observed glacier retreat confirms the representativity of directly measured b values. With typical Alpine gradients of mass balance with altitude (b′, 5 to 10 dm a−1, 100 m altitude), the observed Δb with respect to the past century corresponds to a shift in equilibrium line altitude (ΔELA) of roughly +50 to + 100 m. This result is further confirmed by direct comparison of glacier geometry at the maximum extent of the Little Ice Age and today (Maisch, Reference Maisch1988). Most, if not all, of this change can be explained by an air temperature increase of +0.5° to 1°C (Kuhn, Reference Kuhn1989) as measured on average for the northern hemisphere (UNEP, 1987).

Fig. 1. Length changes of Alpine glaciers since the beginning of the 20th century. Three-year running means are averaged from the indicated glaciers in each of the following size categories: (A) small cirque and mountain glaciers shorter than 2 km, (B) larger cirque and mountain glaciers 2–5 km long, (C) short valley glaciers 5–10 km long, and (D) long valley glaciers more than 10 km long. The four groups reflect balance changes with increasing signal strength, time delay and smoothing: high-frequency (annual) signals show up in category A, decadal trends are clearly visible in Β and C, whereas D mainly gives secular trends. Data basis: Kasser and others (Reference Kasser, Aellen and Siegenthaler1986).

Comparison of glacier mass and length changes at low latitudes with much less complete values from polar regions must take into account climatological aspects and glacier morphology. Changes in precipitation cause strongest ELA-shifts under especially dry or wet conditions (Kerschner, Reference Kerschner1985). Moreover, b′ increases by more than one order of magnitude from continental to maritime glaciers (Kuhn, Reference Kuhn1981). Because b depends on ΔELA times b′, its sensitivity to climatic changes is generally much higher in maritime than in continental areas. It is therefore not astonishing that principal-component analysis of spatio-temporal distribution patterns classifies long-term glacier mass balances according to “continentality” (Letréguilly and Raynaud, in press) and that glaciers can gain mass as a reaction to increased precipitation despite simultaneously rising air temperature (Reference Mayo and TrabantMayo and Trabant, 1984). Morphological aspects are less well understood but relate to the hypsography (Reference Furbish and AndrewsFurbish and Andrews, 1984) and dynamic response of individual glaciers (cf. Reference Johannesson, Raymond and WaddingtonJohannesson and others, 1989), as well as probably to radiation-feedback mechanisms (cf. Oerlemans, 1989). Mass loss and retreat of small mountain glaciers were strongest in the first half of the century. This general tendency slowed down considerably and, in humid areas, even reversed after about 1950 (Reference Haeberli, Müller, Alean and BöschHaeberli and others, 1989).

Permafrost Geometry

Geometric changes of permafrost supersaturated in ice can take place through thaw settlement within the active layer (immediate response) and at the base of the frozen material (delayed response). The response time for basal melting depends on the thickness and the thermal diffusivity of the permafrost (Osterkamp, Reference Osterkamp1984). It is in the order of decades to centuries for cold/thick (continuous) permafrost and of years to decades for warm/thin (discontinuous) permafrost. The latter is especially sensitive to the observed secular warming and may even completely degrade from the top (fast) as well as from the bottom (slow). Initial attempts have been made to monitor photogrammetrically geometrical changes of rock glaciers, the most striking morphological expression of creeping mountain permafrost (Reference Haeberli and SchmidHaeberli and Schmid, 1988). The investigated Alpine permafrost appears to be slowly melting as a consequence of 20th-century warming. Thickness changes of permafrost are smaller than of glacier ice by one to two orders of magnitude and, hence, long-term and high-precision photogrammetry is required. Systematic measurements in various mountain ranges should therefore be initiated as soon as possible, to detect ongoing changes within reasonable time.

Permafrost Temperature

Temperature profiles in saturated/impermeable permafrost can be interpreted on the basis of heat diffusion theory (Reference Gold and LachenbruchGold and Lachenbruch, 1973). Extended drilling activity for oil prospecting in polar permafrost furnishes increasing evidence on 20th-century warming; much less information is available about effects at low latitudes or high altitudes. International inventories of borehole temperatures in permafrost are not yet available but may soon be realized by the International Permafrost Association (IPA).

Boreholes in thick/continuous permafrost commonly, but not universally, show pronounced geothermal anomalies within the uppermost 100–200 m. Maximum departure from steady-state temperature profiles in the Alaskan Arctic is observed at about 50–25 m depth and reaches values of 1–2°C, corresponding to secular surface warming of about 2–4°C — the same general magnitude as the warming of air temperatures during the past 100 years derived from nearby weather stations (Reference Lachenbruch, Cladouhos and SaltusLachenbruch and others, 1988). Signs of more recent, decadal cooling by roughly half the secular warming effect (increased temperature gradient/heat flow above about 50–25 m depth) may be partially attributed to the construction of gravel pads in connection with the drilling operation. Geothermal borehole information from mountain permafrost at lower latitudes is still extremely rare but also shows evidence of recent warming. Rock glacier permafrost in the Kluane Range, Yukon Territory, quickly warmed up and degraded from the top as well as from the bottom (Reference Johnson and NicklingJohnson and Nickling, 1979). A borehole on Plateau Mountain, Alberta, indicates a temperature gradient/heat flow near zero in permafrost more than 150 m thick (Harris, Reference Harris1988). Geothermal analysis of a borehole through the permafrost of an active rock glacier in the Swiss Alps shows increased heat flow down to an unfrozen layer at 52 m depth, perhaps reflecting cooling since about 1950, but also a heat flow inversion below 55 m which may indicate that existence of deep-seated relic permafrost from the Little Ice Age (Vonder Mühll and Haeberli, in press). Convective heat transport through circulating groundwater may play an important role in all these cases.

Temperatures, Melt Layers and Isotopes in Cold Firn

Heat diffusion theory combined with flow modelling must be applied to interpret temperature profiles within cold firn areas where percolation of meltwater is limited or absent. As with permafrost temperatures, considerable bore-hole evidence and sophisticated analyses are available from polar regions, but information about low latitudes is almost completely lacking. All over the accumulation area of Greenland, as well as in marginal parts of Antarctica, temperature gradient/heat flow is clearly inverted between 50 to 200 m depth (Robin, Reference Robin1983). The magnitude of these anomalies is comparable with those observed in polar permafrost, confirming the pronounced secular warming trend. The more recent decadal cooling trend can also be found in many boreholes of the Greenland ice sheet in qualitative accordance with the temperature history as derived from the oxygen-isotope records (cf. Johnsen, Reference Johnsen1977; Clausen and others, 1987). The influence of latent heat effects from refrozen melt layers is usually neglected in analyses of firn temperature. Such refrozen melt layers represent important evidence of meteorological conditions at the surface during dry weather (Reference Beck, Wagenbach and MünnichBeck and others, 1988) and, hence, are complementary to the oxygen-isotope record which reflects precipitation temperature. Stratigraphie investigation of firn cores from the Canadian Arctic (Koerner, Reference Koerner1977; cf. also Reference Herron, Herron and LangwayHerron and others, 1981) reveals a pronounced increase in melt-layer frequency since the middle of the 19th century and especially in the first half of the 20th century. By modelling the thermal regime of an Arctic valley glacier, Blatter (Reference Blatter1987) shows the measured firn temperature profiles to be well in accordance with air temperatures rising by about 3°C until the 1940s. An attempt to compare firn temperatures at polar and temperate latitudes is being made at the Colle Gnifetti drill site in the Swiss Alps (Haeberli and Funk, in press). Despite the fact that melt-layer frequency in the firn cores clearly increases towards the middle of the 20th century (Schotterer and others Reference Schotterer, Haeberli, Good, Oeschger and Röthlisberger1981), the temperature profile measured on this −14°C firn saddle at 4450 m a.s.l. is close to steady-state conditions. The coupling of melt-layer formation, protection against wind erosion and accumulation of cold snow (Reference Alean, Haeberli and SchädlerAlean and others, 1984) perhaps helps to explain why warming of cold firn as a response to 20th-century atmospheric warming appears to be much less pronounced on low-latitude mountains than in Arctic regions.

Conclusion and Recommendation

Taken as complex and integrated climatic evidence which is independent of instrumental meteorological measurements, glacier and permafrost signals of 20th-century warming are coherent: warming of polar firn and permafrost is pronounced and mass loss/retreat of mountain glaciers is striking all over the world. Effects appear to be strongest at high latitudes and signs of a probably intermittent reversal of the trend after about 1950 are clearly visible. The latest development (1980s) is still hidden in as yet unpublished data as well as in natural noise such as seasonal temperature variations in permafrost or delayed response of glacier tongues.

A global view can be obtained only by combining various pieces of evidence. Comparability of data, however, suffers from the uneven regional distribution of such evidence. More numerous, systematic and internationally co-ordinated measurements should be carried out in permafrost and cold firn at low latitudes and many more glaciers should be monitored at high latitudes. The lack of informa¬tion from the southern hemisphere outside Antarctica is especially severe and should be overcome as soon as possible. So far, the length reduction of mountain glaciers still remains the most easily detectable, unequivocal proof from cold regions that fast and worldwide secular climatic change is taking place. This often-underestimated evidence deserves more attention and intensified analysis.

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Figure 0

Fig. 1. Length changes of Alpine glaciers since the beginning of the 20th century. Three-year running means are averaged from the indicated glaciers in each of the following size categories: (A) small cirque and mountain glaciers shorter than 2 km, (B) larger cirque and mountain glaciers 2–5 km long, (C) short valley glaciers 5–10 km long, and (D) long valley glaciers more than 10 km long. The four groups reflect balance changes with increasing signal strength, time delay and smoothing: high-frequency (annual) signals show up in category A, decadal trends are clearly visible in Β and C, whereas D mainly gives secular trends. Data basis: Kasser and others (1986).