Introduction
During the last 25 years scientists and experts all over the world have paid serious consideration to the problem of avalanche risk assessment. Basic principles and conclusions reached in the process of such evaluation can be expressed with the help of the following indices: social (individual and collective risks), economic (possible annual losses, expected percentage of destroyed buildings and other constructions, probability of forced stoppage on railroads and highways) and ecological (possible ecosystem disturbances, probability of death among unique representatives of rare and valuable plant and animal species, etc.). The most commonly used index is individual avalanche risk, which is usually defined as the probability of a person’s death being caused by the impact of a snow avalanche within a certain area during 1 year. Most investigations conducted on this topic are represented by large-scale assessments of individual avalanche risk (e.g. Reference Bohnenblust and TroxlerBohnenblust and Troxler, 1987; Reference Andreev, Bozhinskiy and SidorovaAndreev and others, 1997; Reference Wilhelm and HestnesWilhelm, 1998; Reference Jónasson, Sigurðsson and ArnaldsJónasson and others, 1999; Reference Keylock, McClung and MagnússonKeylock and others, 1999; Reference KazakovKazakov, 2000; Reference Margreth, Stoffel and WilhelmMargreth and others, 2002; Reference Arnalds, Jónasson and SigurðssonArnalds and others, 2004; Reference Bell and T.Bell and Glade, 2004; Reference Zischg, Fuchs, Keiler and StötterZischg and others, 2005; Reference KeilerKeiler and others, 2006). A review of such publications shows that existing methodologies and techniques of individual avalanche risk assessment and calculation are based mainly on careful consideration of snow avalanche characteristics and analysis of the degrees of a person’s vulnerability to avalanches. The index of vulnerability may vary depending on a person’s location in a building (in which case it is necessary to take into account the building’s type and basic engineering features), in a car or in open space. All formulae proposed for individual risk estimation include parameters which are practically impossible to define in order to serve the purpose of small-scale assessment, or the assessment of uncertainty might be extremely high. In this context, the development and adjustment of methodologies and techniques for avalanche risk assessment and mapping, given that large areas of Russia are avalanche-prone, are of vital importance for solving both theoretical and applied tasks. The present paper is devoted to the analysis of corresponding problems using the example of two regions with relatively developed economic and infrastructure systems which can be classified as the most avalanche-prone areas of the country: the northern Caucasus and Sakhalin island.
During the last 25 years scientists and experts all over the world have paid serious consideration to the problem of avalanche risk assessment. Basic principles and conclusions reached in the process of such evaluation can be expressed with the help of the following indices: social (individual and collective risks), economic (possible annual losses, expected percentage of destroyed buildings and other constructions, probability of forced stoppage on railroads and highways) and ecological (possible ecosystem disturbances, probability of death among unique representatives of rare and valuable plant and animal species, etc.). The most commonly used index is individual avalanche risk, which is usually defined as the probability of a person’s death being caused by the impact of a snow avalanche within a certain area during 1 year. Most investigations conducted on this topic are represented by large-scale assessments of individual avalanche risk (e.g. Reference Bohnenblust and TroxlerBohnenblust and Troxler, 1987; Reference Andreev, Bozhinskiy and SidorovaAndreev and others, 1997; Reference Wilhelm and HestnesWilhelm, 1998; Reference Jónasson, Sigurðsson and ArnaldsJónasson and others, 1999; Reference Keylock, McClung and MagnússonKeylock and others, 1999; Reference KazakovKazakov, 2000; Reference Margreth, Stoffel and WilhelmMargreth and others, 2002; Reference Arnalds, Jónasson and SigurðssonArnalds and others, 2004; Reference Bell and T.Bell and Glade, 2004; Reference Zischg, Fuchs, Keiler and StötterZischg and others, 2005; Reference KeilerKeiler and others, 2006). A review of such publications shows that existing methodologies and techniques of individual avalanche risk assessment and calculation are based mainly on careful consideration of snow avalanche characteristics and analysis of the degrees of a person’s vulnerability to avalanches. The index of vulnerability may vary depending on a person’s location in a building (in which case it is necessary to take into account the building’s type and basic engineering features), in a car or in open space. All formulae proposed for individual risk estimation include parameters which are practically impossible to define in order to serve the purpose of small-scale assessment, or the assessment of uncertainty might be extremely high. In this context, the development and adjustment of methodologies and techniques for avalanche risk assessment and mapping, given that large areas of Russia are avalanche-prone, are of vital importance for solving both theoretical and applied tasks. The present paper is devoted to the analysis of corresponding problems using the example of two regions with relatively developed economic and infrastructure systems which can be classified as the most avalanche-prone areas of the country: the northern Caucasus and Sakhalin island.
Background
Avalanche-prone areas include all mountain lands where a combination of two factors exists: (1) slope angles are 17˚ or more; and (2) snow cover of 30 cm depth or more is in steady state for 1 month or more (Reference Institut Geografii RAN.Institut Geografii RAN, 1997). In Russia, avalanche-prone areas occupy a total of 3.1× 106 km2, which is 18% of the total territory. A further 4.8% of the country may be considered as potential hazard zones, where under present natural conditions no avalanching takes place but, due to possible increasing snowiness or reduction of forestation, avalanche formation can start. Many large mountain systems, such as the Khibiny mountains, the northern Caucasus, the Urals, the Altai, the Sayan, the Lake Baikal and trans-Baikal regions, the Putorana plateau, the Byrranga mountains and the mountainous areas of the Far East, including Kamchatka, Sakhalin and the Kurile Islands, belong to avalanche-prone territories. The highest values of avalanche fatality rate and economic damage are registered in the northern Caucasus and Sakhalin. We estimate that more than 6 200 000 people live in avalanche-prone areas of Russia. The average population density in areas characterized by the probability of avalanche impact is less than 2 personskm–2; in the northern Caucasus this index rises to 22 personskm–2. We have collected reliable information about 218 victims of snow avalanches in Russia, recorded during the period 1996–2007 (Fig. 1). Avalanche catastrophes have also occurred regularly in Russia in the more remote past. In the mid-20th century, fatalities occurred mostly among settlement dwellers when avalanches caught them in their houses and other buildings. For example, on 5 December 1935 two avalanches from Yukspor mountain in the Khibiny mountains caused 88 fatalities and substantial damage in a miners’ township. On 9 February 1945 an avalanche destroyed several houses in the township of Middle Medvezhka, Sakhalin, and killed 169 people. In the Seymchan river basin, located in the Magadan region, an avalanche on 28 March 1951 caused many deaths and totally destroyed the Gulag penitentiary camp. High levels of fatalities have also been typical among those who travel by mountain roads. In January–February 1993, 200 avalanches struck the trans-Caucasian highway in the Republic of North Ossetia–Alania; 54 car drivers and passengers were killed as a result of avalanche deposits obstructing the road. In general, the trans-Caucasian highway is the most avalanche-prone road in Russia (Fig. 2). Avalanche fatalities occur regularly among the local population in mountain settlements and their environs. They are also quite common events in mountain recreation, tourism and active leisure zones, where there is a high incidence of deaths of skiers, snowboarders and climbers (Fig. 3).
Avalanche activity is also economically damaging. At the end of the 1980s the annual overall material losses in the USSR caused by snow avalanches were estimated at US$10–15m (Reference Kurbatova, Miagkov and ShniparkovKurbatova and others, 1997). In recent years, considerable damage has been recorded in Dagestan, Kabardino-Balkaria and Karachayevo-Cherkessia. At the beginning of April 2003, six avalanches destroyed several public buildings in Tsakhur, a settlement in Dagestan. The preliminary estimate of the cost of the damage was more than US$300,000. Following a serious avalanche accident in the township of Terskol, northern Caucasus, on 2 March 2005, about US$500,000 was spent on reconstructing an electric power station. Destruction of avalanche protection structures on roads and railways in various mountain regions of the country also entails large expenditures.
Thus, snow avalanches are a real and undoubted menace for people living, working and holidaying in many mountain areas of Russia. The most fatalities and the most serious economic damage are now registered in the northern Caucasus. Catastrophic avalanches followed by large numbers of deaths also often occur in Sakhalin.
Methods
Integrated investigations, aimed at developing methodologies and techniques of risk assessment and possible damage evaluation connected with various dangerous natural processes and phenomena, have long been conducted in the Research Laboratory of Snow Avalanches and Debris Flows at M.V. Lomonosov Moscow State University (MSU). These methodologies and techniques can be used in different scales and allow risk estimations to be obtained for the local population, migrating people and tourists, as well as for many categories of protected systems (roads, railways, means of transportation, etc.). In this paper, methods of collective and individual avalanche risk assessment for large mountain regions are presented. They are elaborated on the basis of the methodology applied for karst risk evaluation as suggested by Reference YolkinYolkin (2004).
Avalanche risk can be treated as the probability of various losses occurring due to avalanche impact during a specific period of time in a certain area (Reference MiagkovMiagkov, 1995). These losses can be expressed as different indices:
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annual number of dead;
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probability of the death of an individual belonging to a particular group of people living within a given area permanently or staying there temporarily;
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probable damage magnitude;
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probable proportion of destroyed and damaged buildings and other constructions;
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probable cost of disruption to transportation systems as a result of avalanche activity.
The possible damage is evaluated taking into account various social and economic parameters, as well as a number of avalanche activity characteristics which determine the probability of losses (Reference MolotkovMolotkov, 1992; Reference SeliverstovSeliverstov, 1992). Thematic maps from the ‘World Atlas of Snow and Ice Resources’ (Reference Institut Geografii RAN.Institut Geografii RAN, 1997) compiled by researchers of the MSU Faculty of Geography were used as the principal source of snow and avalanche information. Calculations were made with the help of GIS (Geographic Information Systems) MapInfo. All areas under investigation were divided into exact squares (gridcells), each side of which equalled 3 km on the map applied as a basis for estimation.
To obtain the values of avalanche risk indices for all gridcells, subsequent calculations of the following parameters were made:
Population vulnerability in time (Vt )
This index defines the duration of stay (time of exposure) of an individual in avalanche hazard areas during the average day and year. It is estimated as a function of the duration of stay of an individual and their possible location within the dangerous territory:
where t d is the average duration of stay of a typical local individual within the dangerous territory during 1 day and t y is the average duration of stay of a typical local individual within the dangerous territory during 1 year. The values of t d were estimated on the basis of expert evaluation and generalization mainly due to the presence or absence of human settlements and roads in areas under investigation. In this project the following values are applied:
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if there are no roads and human settlements, t d is equal to 1 s;
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if there are some roads, t d is equal to 1 min;
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if there are any human settlements, t d is equal to 1 hour.
The values of t y correspond to the annual duration of avalanche danger period (the number of days). The annual duration of the avalanche danger period is the average number of days with snow-cover depth 30 cm and more.
Population vulnerability in space (Vs )
This index is a function of the degree to which a territory is exposed to the impact of snow avalanches:
where S y is the area of the hazard zone (exposed to the impact of natural disaster) within the territory under investigation and S 0 is the total area of the territory. Small-scale estimation of this index is difficult, so corresponding values were calculated on the basis of the close correlation existing between the susceptibility of a territory to snow avalanches and such parameters as absolute height, relative height and landscape type, as proved by Reference BlagovechshenskiyBlagovechshenskiy (1991). To determine particular values of the index, both hypsometric and landscape maps of different territories under investigation were used.
Complete social (collective) avalanche risk
The complete social (collective) avalanche risk of fatal accidents among the people is a function of population vulnerability in time and space, avalanche frequency and population density:
where F is the average recurrence interval of avalanches for an average size avalanche and d is the density of population in the area under investigation. This index shows the annual number of fatalities resulting from avalanche impact.
Individual avalanche risk
This is the probability of an avalanche leading to the death of an individual member of a particular group within the territory under investigation during a 1 year period. This index is calculated by dividing the complete social risk by the total population of the given area:
where P is the total number of local dwellers.
Following the recommendations of the Russian Ministry of Emergency Situations (Reference VorobievVorobiev, 2005), three types of zones with different levels of individual avalanche risk are distinguished on avalanche risk maps. Values less than 1×10–6 indicate acceptable-risk areas, where no special avalanche protection measures for the population are needed and new buildings and other constructions can be erected without restriction. Values from 1×10–6 to 1×10–4 define the boundaries of admissible-risk areas, where considerable avalanche protection measures for the population must be carried out and the erection of buildings and other constructions is possible only in combination with large-scale avalanche control programs, which may lower individual avalanche risk indices to the acceptable level. Values more than 1×10–4 characterize unacceptable-risk areas, where no new construction projects are permitted and, for existing systems and developed lands, a whole set of avalanche control measures is compulsory to protect the population and lower the level of risk.
Results and Interpretation
Using Equation (3), we estimate the values of complete social (collective) avalanche risk as 26 fatalities for Sakhalin, and 47 fatalities for the northern Caucasus. According to the statistical information available, the corresponding registered annual values for the period 1996–2007 are 1 and 12 fatalities. However, half of the fatalities in the northern Caucasus are composed of tourists, and the data on tourist fatalities are either not collected or are concealed. The final estimates are considerably larger than the real fatal-accident rate. The probable reasons for these differences are as follows:
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for the most part, only short-term records of avalanche catastrophes and victims (including data for the whole years 1996–2007) are available;
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substantial changes (relative reduction) in avalanche activity have occurred in most of the investigated areas, and our estimates are based on meteorological information characterizing the avalanche frequency and the length of the avalanche danger period only during the period 1960–90;
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the efficiency of the measures implemented to protect people from avalanche impact, which plays a crucial role in reducing the fatal-accident rate in any avalanche-prone region, has been underestimated.
Comprehensive analyses and calculations, using Equations (1–4), have resulted in the implementation of individual and collective risk assessments and the compilation of small-scale maps of Sakhalin and the northern Caucasus (Figs 4 and 5). We conclude that the highest values of individual avalanche risk in Sakhalin are typical for areas along the west coast. Although local avalanches are characterized by small volumes, they can cause large numbers of fatalities and considerable economic damage, because a number of thoroughfares, electric power transmission lines and human settlements are situated in the coastal zone under their possible impact. Just in this part of the island, there are several territories with an unacceptable level of individual avalanche risk. In the towns of Kholmsk and Nevel’sk, for example, the values are 1.5×10–4 and 3×10–4 respectively. The highest level of individual avalanche risk, 4×10–3, is observed in the town of Sinegorsk due to an extreme rate of avalanche activity, high population density and the location of many buildings and other constructions within avalanche paths. Relatively high values of individual avalanche risk are also typical for the highway and railroad between Yuzhno-Sakhalinsk and Kholmsk, which cross the Mitsul’skiy and Yuzhno-Kamyshovy mountain ranges.
Our results show that approximately 85.1% of the avalanche-prone territory of Sakhalin consists of areas with an acceptable level of individual avalanche risk. Admissible risk applies to areas comprising about 14.8% of the avalanche-prone territory. Areas with an unacceptable level of individual avalanche risk, concentrated in urbanized zones (e.g. in the vicinity of the towns Kholmsk, Nevel’sk and Tomary), cover only the remaining 0.1% of the avalanche-prone territory.
Major mountain resorts, including Krasnaya Poliana, the Mount Elbrus region and Dombai, densely populated lands in Dagestan, and the trans-Caucasian highway zone, belong to unacceptable-risk areas of the northern Caucasus, which occupy 7% of the avalanche-prone part of the region, while the values for admissible- and acceptable-risk areas are 52% and 41% respectively. These conclusions are illustrated by the map (Fig. 5) showing the sites of some catastrophic avalanche events. Most are located within areas characterized by unacceptable, and few in areas with admissible, levels of individual avalanche risk.
Conclusion
Studies of avalanche processes and events have been conducted in Russia for several decades. Until recently, the basic parameters of the avalanche activity itself, i.e. geophysical characteristics, were mainly considered. The analysis of specfic features of avalanche impact on human society and its mode of life was limited by the registration of disasters that had already occurred and the compilation of an inventory of various systems and structures under threat. Integrated successive appraisal of the avalanche risk assessment undertaken can help mitigate the social and economic consequences of avalanche activity and assist in selecting rational avalanche control measures. The suggested methods of complete social (collective) and individual avalanche risk estimation, using simple and easily obtainable geophysical, social and economic information, allow us to carry out both small- and medium-scale risk evaluation even for insufficiently explored avalanche-prone areas. As the described methods of avalanche risk assessment have been elaborated based on a methodology similar to that applied to karst phenomena and processes research, we believe that such an approach can also be used to study other natural disasters (e.g. debris and slush flows, earthquakes, landslides).