History of the avalanche problem in Scotland

The first recorded avalanche to take place in Scotland was on New Year's Day, 1800, when a party of five gamehunters was overwhelmed in a shooting lodge in the Gaick hills, just south of the Cairngorms (Table I). The building was completely destroyed (the first and only time in Scotland), and the event was ascribed to supernatural causes (Reference GordonGordon, 1969). A less well documented avalanche in the shape of a giant snowball fell by the side of a poor man's cottage. Fortunately for both him and his family, when opened it was found to contain "three brace of ptarmigan, six hares, four brace of grouse, a blackcock, a pheasant, three geese, and two fat stags" (Reference BrownBrown, 1978, p. 158). In Scotland we have good reasons for believing our avalanche problems are unique!

Table I. Avalanche accidents in Scotland 1800–1979

The first reliable reports of avalanches were published just before 1900 in the early volumes of the Scottish Mountaineering Club Journal and the Cairngorm Club Journal. Whilst the latter concentrated on the Cairngorms, the former covered the whole of Scotland, particularly Ben Nevis (Fig. 1). Each journal shows a pattern of early interest in avalanches followed by a decline in interest. References to avalanches are rare in the Cairngorm Club Journal after 1901, and infrequent in the Scottish Mountaineering Club Journal after 1915. Many of these early articles described minor accidents although, apart from the 1800 disaster, the first injury did not occur until 1938 and this was no more than a broken ankle.

After 1937, mountain accident statistics were published annually in the Scottish Mountaineering Club Journal. These were based on newspaper reports and oral accounts, and formed the chief source of avalanche data until 1976, by which time avalanches accounted for four per cent of all reported accidents (Reference O'DonovanO'Donovan, 1977). This compares with the period 1925–45, during which avalanches accounted for only one accident out of 90 (Reference HumbleHumble, 1946). These reports suffer from the drawback of only including those incidents that resulted in a rescue team call-out. They therefore exclude all accidents in which the victims were able to free themselves and walk away. As most Scottish avalanches are small, this happens frequently, and in 1978, for example, walking parties were avalanched without personal damage on five separate occasions. It is a common experience for gully climbers to be bombarded by small avalanches during a winter ascent, and this is expected as "all part of the game".

Fig. 1. Location map of the Cairngorms.

Field investigations since 1976 have shown that accident reports record only a very tiny percentage of the total number of avalanches in Scotland. Nevertheless that fraction is large enough to have affected over 150 people since 1925 (Reference WrightWright, unpublished). Since 1970, avalanches have accounted for roughly two fatalities and six injuries per annum. Nearly all these incidents have involved either climbers or hillwalkers, but cross-country skiers have occasionally been caught (Reference CousinsCousins, 1977). The death of climbers is usually caused by the effects of the fall and by striking rocks, but burials affect both climbers and walkers. In 1964, out of four caught, one avalanche victim survived burial for 22 h, a Scottish record. Hillwalkers are more likely to be injured by large, open-face slab avalanches. Two were killed on 27 December 1978 by a large avalanche that swept off Braeriach towards Glen Einich.

The problem of avalanche hazard in Scotland is thus different from that in Alpine countries where avalanches damage villages, roads, railways, ski installations, and forested areas, and where the cost of such damage alone justifies research and protection. Only two records exist of an avalanche crossing a road in Scotland, and a train or car has never been hit. There are no communities or single houses at risk and, although on a number of occasions avalanches have damaged Forestry Commission plantations and private woodlands, losses are negligible. Sheep and deer have been killed in avalanches, but such events arouse only local interest. Finally, despite 18 years of operation, the Cairngorm ski installations and pistes have never been avalanched, and there have been only minor accidents on the other main ski area in west Scotland. This situation may change with the planned expansion of ski-ing, but for the time being avalanche danger remains the exclusive problem of the mountaineer and crosscountry skier.

Avalanche investigations in the Cairngorms

The increase in avalanche incidents, and the inherent interest of Scottish snow itself were the impetus behind the present study which was begun in 1977. It was designed to analyse the factors responsible for avalanche release and to develop a tentative forecasting model. On the basis that avalanches release when the shearing stresses acting on the snow exceed the frictional forces holding it in place, measurements were made of those variables thought to have a bearing on this balance of forces. Consequently the properties of the snow-pack itself were measured (temperature, density, stratigraphy), as well as those variables that affect the snow-pack, namely weather conditions and topography. Viewed in this way, weather and topography are the independent variables, snow-pack properties are the dependent variables, and avalanche release is the result of a particular configuration of the snow-pack properties in which stress and friction are not balanced. The correlation of avalanche release with weather, topography, and snow-pack parameters depends upon the availability of avalanche records, and these were obtained from fieldwork, climbing journals, books, police records, newspaper cuttings, and accident statistics. Letters were sent to all the Scottish climbing clubs asking for information, questionnaires were distributed around campsites, Youth Hostels, and hotels, and advertisements requesting information were placed in some magazines.

The Cairngorm Mountains were chosen as the study area for a number of reasons. First, by virtue of their elevation they retain their snow longer than any other mountain massif in Scotland, with the exception of Ben Nevis. Secondly, owing to the availability of some earlier work (Reference LangmuirLangmuir, 1969 and unpublished field notes; Reference BeattieBeattie, unpublished) a slightly longer span of snow-pit data was obtainable. Thirdly, the area was well served with weather stations. Finally, some equipment was available in the area and, due to the ski-ing development, relatively easy access was possible to known avalanche sites by road, chairlift, and on foot.

The Cairngorms comprise a gently undulating plateau with large areas above 1000 m and reach a maximum of 1 309 m in Ben Macdui. The plateau surfaces are fringed either by cliffs, typically 50 to 100 m high and broken into buttresses divided by numerous gullies, or talus slopes, angled at 35° with a maximum vertical range of 600 m in the Lairig Ghru and Glen Einich. Whereas the cliffs form the headwalls of glaciallyscoured corries, the talus slopes bound the main glacial troughs and form aretes between adjacent corries. There are no trees above 450 m and heather is the dominant vegetation. Isolated areas of rock slabs occur, as in Coire au Lochan and at the Devils Point.

On average the plateau is 800 m to 900 m higher than the surrounding valleys and as a consequence has a different climatic regime. Snow usually lasts all year round in isolated snow-beds, and may fall in every month. Heavy snow-falls of more than one metre are infrequent, but snow may fall in small quantities for several consecutive days. The main period of snow-fall is between November and May, with the coldest temperatures (< − 10°C) occurring in January and February. As the massif is nowhere more than 80 km from the sea it is frequently affected by warm maritime air bringing in thaw conditions. Temperatures may rise by 10 or 15 deg within a few hours. Cold, clear weather is normally associated with a northerly airstream and warm, cloudy weather with a southerly airflow. Winds are typically between 11 m s⁻¹ and 18 m s⁻¹, reaching a maximum of 68 m s⁻¹ in isolated gusts. Days of light variable winds are few.

Snow-pack conditions in the Cairngorms

During 1978 and 1979, 17 snow-pits were examined and a photographic record of snow distribution in Coire an-t-Sneachda was accumulated when conditions permitted. The main characteristics of the snow-pack were found to be:

1. (1) The accumulation of large thicknesses of windslab, particularly on lee slopes where snow may lie 30 m deep (Fig. 2). On 24 January 1978, poles standing three metres clear of the snow surface on the headwall of Coire Cas were completely buried during a snowfall of 15 cm accompanied by winds of 20 m s⁻¹.

2. (2) Five or six ice layers were commonly found in snow-pit sections (Fig. 3). These reached a maximum thickness of five centimetres, but were usually less than one centimetre. The thinner layers were clear, but thicker layers were often dirty with incorporated soil or twigs. Penetration values of several hundred kilogrammes were measured for the ice layers, which often underlay a slush zone above. The latter resulted from impeded drainage caused by the impermeable ice layers during a thaw.

3. (3) Coarse granular snow is always found at the base of the snow-pack, and occasionally in the middle or at the top as well. It usually exhibits a variable resistance to penetration, although hard and soft layers may look the same in section and layering may not be visible. In 1978 the lowest levels were always hard, with penetration values of 100 kg or more. By contrast, a common feature in 1979 was a weaker zone just above the base giving penetration values of 30 kg or less.

Fig. 2. Large slab-avalanche fracture line with fresh cornice, Lochnagar. Photograph by E. Langmuir.

Fig. 3. Snow-pit section at 700 m on the north of Cairngorm, April 1979. The snow-pack was isothermal.

Weaknesses arise in the snow-pack for a number of reasons: Slush layers have been mentioned and these may form at the base of the snow, above rock slabs for example, as well as internally. Another source of weakness is the incorporation of cohesionless grains into the snow. This may happen as a result of fresh snow falling onto a layer of surface hoar following a frost, or due to the inclusion of a layer of hail into the snow during a storm. Hail is common in Scotland, particularly late in the season and, for example, fell on each of the first six days in May 1979. A hail-lubricated avalanche has been reported from the northern Cairngorms (personal communication from R. Barton and Reference BeattieB. Beattie, 1976). Reference BeattieBeattie (unpublished) has also reported very early depth-hoar formation and Langmuir states that, although practically unknown in Scotland "it may occasionally be found in the space created when loose snow settles below a hard slab" (Reference LangmuirLangmuir, 1969, p. 208–09). However, no evidence of depth hoar was found in 1978 and 1979, and, as temperatures are never sufficiently low for sufficiently long to permit significant temperature-gradient metamorphism, it is unlikely to be a major cause of avalanches in Scotland. It is, however, fair to say that the absence of depth hoar in 1978–79 may be attributable to the particularly heavy snow-falls that occurred.

Using the snow-pit data from 1978–79, together with results obtained by Reference BeattieBeattie (unpublished) as representative of Scottish snow-pack conditions, comparison can be made between Scottish and alpine snow. Work by Reference KeelerKeeler (1969), Reference ArmstrongArmstrong and others (1974), and Reference MartinelliMartinelli (1971) has been taken to be typical of alpine conditions. Three differences emerge:

1. (1) Depth hoar very probably does not contribute to avalanche formation in Scotland but occurs widely in alpine regions, encouraged by long periods of cold weather.

2. (2) Average ram penetrometer values are higher in Scotland, and snow densities are higher as well. Individual maximum and minimum values are the same in both areas.

3. (3) Ice layers appear to be more common in Scotland throughout the winter.

Warmer temperatures and frequent freeze–thaw cycles in Scotland are responsible for these differences which are most marked in mid-winter, when the alpine snow-pack is most continental, and which disappear towards the alpine spring.

Avalanches: types, location, and frequency

Altogether about 800 avalanches have been recorded, of which nearly 600 come from 1978 and 1979. Most of these were seen during two flights on 17 April and 6 May 1979. Avalanches were classified either as wet or dry stuffs or wet or dry slabs. Often the humidity of the snow at the time of release could not be ascertained: in such cases the adjectives wet or dry are omitted. Airborne powder avalanches have not been seen in the Cairngorms although one has been reported from Ben Nevis (personal communication from H. McInnes, 1978). Unless otherwise stated all avalanches are surface avalanches.

(2) Stuffs

Stuffs were first recorded on 7 January 1978 and on 11 December 1978, just prior to the 1979 winter season. On 9 February 1978, 14 dry sluffs were seen near Loch Avon as well as one in the Lairig Ghru and two in Coire an Lochan. All other stuffing activity has involved wet snow. In 1979 about 500 wet sluffs were seen throughout the Cairngorms during two air flights; on open slopes they often occurred in clusters of four or five, lying side by side like sardines in a tin. A few that issued from gullies were dirty with entrained regolith. On 17 and 19 April 1979, wet sluffs were observed in motion above Loch Avon and in Coire an Lochan. A shallow layer of snow was involved and flow lasted for several minutes at low speed. Both wet and dry sluffs are typically small with a width of only a few metres and run-outs of 50 to 150 m. Where they have been started by a large cornice collapse they may be much larger, building levees (Fig. 4).

Fig. 4. Wet-snow avalanche and cornice activity in Coire an Lochan, Cairngorm, April 1979.

Correlation of avalanches with topography and weather

All the avalanches recorded in 1978–79 started on slopes with gradients greater than 30°, although in many cases run-outs extended onto much gentler slopes (Fig. 5). Slab avalanches were initiated on slopes of about 35° and fracture lines occurred either a few metres below the base of cliffs or near the top of talus slopes. Dry and wet slufls occurred on slopes of all angles above 30°, many of them issuing from gullies.

Fig. 5. Relationships between slope angle and type of avalanche activity.

Another important determinant of avalanche location was found to be surface cover and roughness. Slab fractures were seen above smooth rock slabs near Loch Avon and in Coire an Lochan, and a large avalanche falls from the rock slabs near the Devils Point into Glen Geusachan in many years (Scottish Mountaineering Club, 1908; Reference Baird and TranquairBaird and Tranquair, 1931; Reference SmithSmith, 1965). Where the talus is particularly coarse full-depth avalanches have not been seen; for example, on the southern spur of Ben Macdui where boulders and isolated pinnacles stand three or four metres clear of the general surface, both wet and dry sluffs were found to follow the channels of debris flows and were constrained by the levees on either side.

Due to the failure of several experimental and standard high-level automatic weather stations, only tentative conclusions may be drawn concerning the relationships between prevailing weather and avalanche release. Furthermore, the avalanche data were recorded only when the remains were seen, which may differ from the release date by several days. This is especially true of 1979 and the period between 31 January and 9 February 1978. The main associations are:

1. (1) Between 28 January and 4 February 1978, a deep depression to the south-west gave rise to very strong winds (27 m s⁻¹ to 32 m s⁻¹, gusting to 45 m s⁻¹) from the northeast, accompanied by an exceptionally heavy snow-fall of about three metres. It is likely that intense dry slab and dry-slab activity characterized this period, although the hills were unapproachable until 9 February, when a few dry sluffs were seen. Perla and Martinelli (Reference Perla and Martinelli1976, p. 35) state "It is an observed fact that the vast majority of avalanches release during or after storm periods".

2. (2) Between 8 February and 21 February 1978, very cold temperatures prevailed (minimum recorded, −20°C in the Spey valley), and avalanches fell between 19 and 21 February. These were large dry-slab avalanches.

3. (3) Between 22 and 24 February freezing level rose by 2 000 m and wet slab avalanches fell on 23 and 24 February. Wet sluffs fell between 23 February and 10 March, and wet slab avalanches fell infrequently between 3 March and the end of May.

4. (4) In 1979 there was no big snow-fall as in the previous year and predominantly warm weather persisted from the middle of February. Snowy, warm weather lasted from 28 February until 9 April and a "thaw cycle" emerged after the latter date. In general terms the cycle had three phases:

   1. (i) Small partial collapses of cornice occur. No entrainment of snow from lower down takes place.

   2. (ii) Sluffs begin to form as cornice falls entrain snow from the lower slopes. Probably some wet slab avalanches fell at this time.

   3. (iii) Spontaneous initiation of sluffs begins and full-depth fracture lines appear above rock slabs.

Throughout this period there was large-scale movement of free water giving the snow a stained appearance throughout the hills.

The most significant factors governing avalanche release in 1978 and 1979 appeared to be the period of cold weather immediately following the heavy snow-fall in 1978, thus inhibiting the consolidation of the snow mass, and the extent of thawing in 1979 which permitted the development of several slush layers and which promoted extensive drainage of free water through the snow and along ice layers.

Towards avalanche forecasting

Avalanche forecasting has both scientific and human aspects. Existing scientific data are very limited and suffer from spatial and temporal biases. The above results, from 1978 and 1979, were obtained during unusually snowy winters and therefore may not constitute a reliable sample from which to draw general conclusions. Furthermore, the differences between Scottish and alpine snow suggest that forecasting techniques developed in alpine areas may require some modification before they can be applied successfully in Scotland. However, since work began in the Cairngorms, particularly hazardous slopes have been identified and general relationships between weather conditions and avalanche release are emerging. More research is now required to build upon these preliminary results.

It is here that social factors become important. Due to a lack of interest and financial support, a previous suggestion to provide a scientific avalanche-forecasting service as part of the Countryside Commission's "Speyside Project" was rejected (personal communication from J. Porter, 1979). The lack of support was based on the view that the effort involved was not justified by the likely benefit, which, as has already been established, would only be enjoyed by mountaineers and the occasional cross-country skier. Response towards proposed forecasting services was, and still is, mainly negative.

The antipathy of mountaineers towards avalanche forecasting does not extend to research in general. Specific answers to specific questions, such as the rate at which cornices weaken and strengthen during melt–freeze cycles, would be welcomed (personal communication from W. R. Brooker, 1979), but there are two reasons why forecasting would not. The first is that existing forecasts, issued by the Inverness Constabulary and on the basis of informed local opinion, do more harm than good. They are blanket warnings and once given are rarely retracted. A notice stating "Avalanche Danger—Acute" was displayed at the Forestry Commission Information Centre continuously for two months between March and May 1979. Although correct in general terms, for avalanches occurred throughout the Cairngorms over the duration of the notice, obviously for most of the time individual slopes and gullies were quite safe. Such notices acquire a "crying-wolf" character, as supposedly unstable slopes can be safely negotiated, with the result that accurate forecasts may be ignored.

The second problem is more personal and derives from the motives that cause people to climb or ski the remoter slopes. One of these motives is the freedom to go where one chooses, without being answerable to some authority, and the other motive is to expose oneself to a degree of risk. How big a risk depends upon the individual's character and experience, but the right to take risks is a basic mountaineering ethic, and the existence of a risk essential to the enjoyment of the sport. The fear that a large-scale research project may violate these essentials has been clearly expressed by the vice-principal of Scotland's foremost Outdoor Sports Centre:

Perhaps a more typical reaction to proposals for avalanche forecasting is that expressed by a local mountain-rescue team leader: "Mountaineers are molly-coddled enough!" Though less violently opposed to avalanche forecasting than O'Donovan's view, it is no more favourable. For the present avalanche research remains low-key, but initiatives taken at the Outdoor Sports Centre have resulted in two national avalanche seminars attended by police, mountain-rescue team leaders, and other interested parties. Until useful avalanche forecasting becomes a reality this approach should curb the increase in avalanche accidents by helping hill-users to make their own judgements in an informed way.

Acknowledgements

I would like to thank all those who volunteered their help in this project, particularly Jo Porter, Eric Langmuir, the late Ben Beattie, and Fred Harper and his staff, as well as many members of the Scottish Mountaineering Club, the Mountain Rescue Committee of Scotland, and other Scottish climbing clubs. David Sugden made helpful suggestions to improve the manuscript. I am very grateful to the Natural Environment Research Council for a studentship to carry out this research.