Regionalization Research of Mountain-Hazards Developing Environments for the Eurasian Continent
Abstract
:1. Introduction
2. Theoretical Construction of Root Factor Selecting for Mountain-Hazards Developing Environments
3. Study Area and Materials
3.1. Study Area
3.2. Representative Significance of PPR on Mountain-Hazards Developing Environments
- (1)
- Peak ground acceleration (PGA) represents the intensity of seismic activities and is an important index to measure the intensity of seismic actions [40]. Seismic activities can make rock and soil produce cracks and even faults, which can create conditions for the developing of mountain-hazards [41,42]. For geological factors, PGA, which represents the strength of seismic activity, may be more representative than other related indicators, such as lithology, faults, rock strength, distance from faults and etc.
- (2)
- Temperature and precipitation are two elements that reflect the characteristics of the climate [43]. For mountain hazards, precipitation could provide water conditions for the developing of mountain hazards [44]. The formation of hazards-developing environments is the result of the interaction of geographical elements over a long time. With the impact of precipitation on hazards-developing environments on a long-time scale, its effect on vegetation growth and soil development could be better explained [45,46]. Based on the above considerations, the annual average precipitation was selected to characterize the impact of climate factors on the formation of hazards-developing environments of mountain hazards.
- (3)
- The most important role of geomorphic factors in the formation of hazards-developing environments of mountain hazards is to provide potential energy conditions for the developing of mountain hazards (such as absolute height) and the transformation conditions from potential energy to kinetic energy (such as slope or topographic relief). In contrast, the transformation condition from potential energy to kinetic energy is particularly important for the developing of mountain hazards [47,48]. For this condition, topographic relief emphasizes the difference between the highest and lowest altitude in a certain area, which can reflect the characteristics of elevation change [49]. Compared with the slope emphasizing the steepness and flatness of the ground at a certain point, topographic relief can better show the regional characteristics of the landform, so it may be more suitable to be selected as a representative indicator to reflect the geomorphic elements of the hazards-developing environments.
3.3. Materials
3.3.1. PGA Data
3.3.2. Annual Average Precipitation
3.3.3. Elevation
4. Methods
4.1. Data Standardization
4.2. Geospatial Data Band Synthesis
4.3. Spatial Clustering Algorithm ISODATA
- ①
- Firstly, some initial values are selected as the clustering centers, and the pixels to be classified are allocated according to the index;
- ②
- Calculate the distance of various ground objects in the sample;
- ③
- The cluster group splits and merges to form a new cluster center;
- ④
- Continue to iterate and recalculate, then end the operation when the result converges. At present, this method has many applications in remote sensing image classification, image retrieval, voice conversion, multi-agent task allocation and other fields [57,58,59,60]. The method is also relatively mature.
4.4. Spatial Stratified Heterogeneity Analysis Using Geodetector
5. Results
5.1. Data Standardization and PPR Band Synthesis
5.2. PPR Automatic Classification of 3D Geo-Information Spatial Data
5.3. Cartographic Generalization and Regionalization Results
5.4. Analysis on the Ability of Hazards-Developing Environment Regionalization to Explain the Spatial Stratified Heterogeneity of PPR Factors
5.5. Characteristic Analysis of PPR Factors in Each Subregion
- (1)
- The subregion with higher PGA values (mainly distributing above the mean value) include 4 Alps–Mediterranean subregion, 6 Baikal–Altai subregion, 8 Iranian plateau subregion, 9 Pamirs subregion, 13 Himalayan–Hengduan subregion and 14 Tibetan Plateau subregion.
- (2)
- The subregions with high annual average precipitation (mainly distributing above the mean value) include 1 high-latitude plain subregion, 4 Alps–Mediterranean subregion, 7 Northeast Asia subregion, 12 Deccan Plateau subregion, 13 Himalayan–Hengduan subregion and 15 low-latitude monsoon subregion.
- (3)
- In terms of topographic relief, the areas with large variation range of topographic relief mainly include 3 East-Siberia mountainous subregion, 4 Alps–Mediterranean subregion, 6 Baikal–Altai subregion, 7 Northeast Asia subregion, 8 Iranian plateau subregion, 9 Pamirs subregion, 11 Arabian Peninsula subregion, 12 Deccan Plateau subregion, 13 Himalayan–Hengduan subregion, 14 Tibetan Plateau subregion, and 15 low-latitude monsoon subregion.
5.6. Analysis of Mountain-Hazards Susceptibility in Each Hazard-Developing Environment Subregion
- ①
- ②
- ③
- When there is only the relief condition or rainfall condition, or both conditions are not available, it is not conducive to the developing of mountain hazards;
- ④
- A certain amount of precipitation and a certain amount of relief are the favorable conditions for the developing of mountain hazards;
- ⑤
- Geological activities can break rocks and develop fissures, which are conducive to the infiltration of water, promote the developing of landslide hazards, and also provide material source conditions for debris flow hazards so as to form a good mountain-hazards developing environment in places with relief conditions but relatively little rainfall [76].
6. Discussion
- (1)
- Arid and active-geologic regions: this category includes the Baikal–Altai subregion, Iranian plateau subregion, Pamirs subregion and Tibetan Plateau subregion. The characteristics of such regions are that the PGA value and relief value are relatively high [82,83]. Although the precipitation value is relatively low, the active geological activities break the rocks and soil mass, which is conducive to the infiltration of precipitation along the cracks [84,85]. It is conducive to the developing of landslides and other mountain-hazards, and the broken rocks and soil mass also provides rich solid source conditions for the developing of debris flow hazards [86].
- (2)
- Humid and active-geologic regions: this category mainly includes the Alps–Mediterranean subregion and the Himalayan–Hengduan subregion. All PPR values of such regions are high. In these subregions, the active geological activities make the rocks and soil broken. The infiltration and softening for rocks and soil by abundant precipitation can reduce the strength of rocks and soil and provide rich water source conditions for the developing of mountain hazards, while the large relief provides basic potential energy transformation conditions for the developing of mountain hazards [87,88]. It can be seen that this kind of hazards-developing environments is most conducive to the developing of mountain hazards, compared with the other two types of hazard-developing environments [89].
- (3)
- Humid and inactive-geologic regions: the subregions involved in this category include the Northeast Asia subregion, Deccan Plateau subregion and low-latitude monsoon subregion. In terms of precipitation characteristics, the above subregions are affected by monsoons [90,91], and the precipitation is relatively rich. There is large topographic relief in these subregions, which can provide the most basic potential energy conversion conditions for the developing of mountain hazards. However, the geological activities in these areas are relatively weak, so the developing of rock and soil fissures in these subregions is weaker than the first two categories [92].
7. Conclusions
- (1)
- Based on unsupervised classification, small patch elimination and merging operations, 15 mountain-hazards developing environment subregions with their own characteristics were obtained.
- (2)
- The analysis based on geodetectors shows that the regionalization results have the best interpretation ability for PGA spatial stratified heterogeneity (q = 0.61), followed by the annual average precipitation spatial stratified heterogeneity (q = 0.58) and the topographic relief spatial stratified heterogeneity (q = 0.30). Overall, the regionalization results can reflect the spatial stratified heterogeneity of PPR to a certain extent and reflect the regional characteristics of mountain-hazards developing environments.
- (3)
- The strength characteristics of PPR values in 15 subregions were analyzed, and the susceptibility of mountain hazards in each subregion was preliminarily identified according to the listed judgment rules. Nine subregions, including Alps–Mediterranean subregion, Baikal–Altai subregion, Northeast Asia subregion, Iranian Plateau subregion, Pamirs subregion, Deccan Plateau subregion, Himalayan–Hengduan subregion, Tibetan Plateau sub-region, and low-latitude monsoon subregion, were preliminarily identified as the overall high susceptibility regions of mountain hazards.
- (4)
- Through the classification of nine mountain hazards’ overall high-susceptibility regions, three different types of areas were obtained. They are arid and active-geologic regions, humid and active-geologic regions, and humid and inactive-geologic regions.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Subregion Name | PGA | Precipitation | Relief | Susceptibility Characteristics | Rules |
---|---|---|---|---|---|
1 High-latitude plain subregion | Local high value | Local high value | Overall low susceptibility, local high susceptibility | ③, ④ | |
2 Mid-Siberia plateau subregion | Local high value | Overall low susceptibility | ③ | ||
3 East-Siberia mountainous subregion | Local high value | Local high value | Overall low susceptibility, local high susceptibility | ③, ④ | |
4 Alps-Mediterranean subregion | Overall high susceptibility | ④ | |||
5 Central Asia subregion | Overall low susceptibility | ③ | |||
6 Baikal-Altai subregion | Overall high susceptibility | ⑤ | |||
7 Northeast Asia subregion | Local high value | Overall high susceptibility | ④ | ||
8 Iranian plateau subregion | Local high value | Overall high susceptibility | ⑤ | ||
9 Pamirs subregion | Local high value | Overall high susceptibility | ⑤ | ||
10 Mongolia-Xinjiang subregion | Local high value | Overall low susceptibility | ③ | ||
11 Arabian Peninsula subregion | Local high value | Overall low susceptibility, local high susceptibility | ③, ⑤ | ||
12 Deccan Plateau subregion | Local high value | Overall high susceptibility | ④ | ||
13 Himalayan-Hengduan subregion | Overall high susceptibility | ④ | |||
14 Tibetan Plateau subregion | Overall high susceptibility | ⑤ | |||
15 Low latitude monsoon subregion | Local high value | Overall high susceptibility | ④ |
Model Type | Applicability |
---|---|
Arid and active-geologic region model | Areas with low precipitation and high PGA |
Humid and active-geologic region model | Areas with high precipitation and PGA values |
Humid and inactive-geologic region model | Areas with low PGA value but relatively abundant precipitation |
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Cheng, D.; Gao, C. Regionalization Research of Mountain-Hazards Developing Environments for the Eurasian Continent. Land 2022, 11, 1519. https://doi.org/10.3390/land11091519
Cheng D, Gao C. Regionalization Research of Mountain-Hazards Developing Environments for the Eurasian Continent. Land. 2022; 11(9):1519. https://doi.org/10.3390/land11091519
Chicago/Turabian StyleCheng, Deqiang, and Chunliu Gao. 2022. "Regionalization Research of Mountain-Hazards Developing Environments for the Eurasian Continent" Land 11, no. 9: 1519. https://doi.org/10.3390/land11091519
APA StyleCheng, D., & Gao, C. (2022). Regionalization Research of Mountain-Hazards Developing Environments for the Eurasian Continent. Land, 11(9), 1519. https://doi.org/10.3390/land11091519