Vulnerability assessment of rural social-ecological system to climate change: a case study of Yunnan Province, China

Yueyue He (Faculty of Management and Economics, Kunming University of Science and Technology, Kunming, China)
Changchun Zhou (Faculty of Management and Economics, Kunming University of Science and Technology, Kunming, China)
Tanveer Ahmed (Faculty of Management and Economics, Kunming University of Science and Technology, Kunming, China)

International Journal of Climate Change Strategies and Management

ISSN: 1756-8692

Article publication date: 7 May 2021

Issue publication date: 25 June 2021

2564

Abstract

Purpose

The purpose of this paper is to quantitatively measure the vulnerability level of the whole rural social-ecological system in Yunnan Province and to analyze the spatial differences of the vulnerability in different regions.

Design/methodology/approach

Based on the “exposure-sensitivity-adaptability” vulnerability assessment framework, this paper establishes the index system of rural social-ecological system vulnerability to climate change. Combined with the questionnaire survey and meteorological data, the entropy method was used to measure and analyze the vulnerability level and influencing factors of the overall rural social-ecological system in Yunnan Province. At the same time, the vulnerability level of social-ecological system in Yunnan Province is divided into five levels, and the spatial differences of vulnerability level of 16 states (cities) in Yunnan Province are analyzed.

Findings

The results show that: the social-ecological system has high exposure to climate change (0.809), strong sensitivity (0.729), moderate adaptability (0.297) and overall system vulnerability is at a medium level (0.373). Yunnan Province is divided into five levels of social-ecological system vulnerable areas. The areas of extreme, severe, moderate, mild and slight vulnerability account for 21.45%, 24.65%, 36.82%, 13.18% and 3.90% of the whole province, respectively. The geographical division and vulnerability division of Yunnan Province are basically consistent in space.

Originality/value

Comprehensive evaluation of the vulnerability of the social-ecological system of Yunnan Province to climate change is the scientific basis for the country to formulate countermeasures against climate change, and it is also the need to improve the adaptability of the social and economic system of the fragile area, reduce the vulnerability and realize the sustainable development of national social economy. The research results can provide a basis for decision-making of climate adaptation in Yunnan and other regions and provide methods and indicators for the assessment of social-ecological system vulnerability under the background of climate change.

Keywords

Citation

He, Y., Zhou, C. and Ahmed, T. (2021), "Vulnerability assessment of rural social-ecological system to climate change: a case study of Yunnan Province, China", International Journal of Climate Change Strategies and Management, Vol. 13 No. 2, pp. 162-180. https://doi.org/10.1108/IJCCSM-08-2020-0094

Publisher

:

Emerald Publishing Limited

Copyright © 2021, Yueyue He, Changchun Zhou and Tanveer Ahmed.

License

Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode


1. Introduction

Climate change research is the first to spotlight on intense actions and long-term climate change, focusing on scenario analysis under different emission conditions. Researchers and policymakers pay more attention to emanation reduction. Nevertheless, the effect of emission reduction will not be seen until at least several decades, and the contribution of adaptation to plummeting the risk of climate change can be realized on the regional scale (Pielke and Sarewitz, 2005). Hence, study lying on adaptation has involved extra concentration from researchers and policymakers. After the conference of the parties to the “United Nations Framework Convention on Climate Change” in 1995, there have been a lot of studies on how to improve the adaptability of climate change (Thomalla et al., 2010). Effective adaptation requires two premises: one is to have information about what and how to adapt; the other is to have resources to implement adaptation strategies. The former is the research content of vulnerability, that is, it provides information about the exposure, sensitivity and adaptability of the social-ecological system to climate change. To enhance the ability to adapt to climate change, it is necessary to understand the current state of vulnerability. As a result, vulnerability and adaptability assessments have been carried out by the World Bank, the United Nations Development Programme, the United Nations Environment Programme and many non-governmental organizations.

Global climate change has brought extraordinary challenges to rural social-ecological systems. It has a great impact on rural ecosystems, human health, agricultural development, farmers’ livelihoods and foodstuff manufacturing along with the use of natural resources (Adger et al., 2005). With the increase of a series of uncontrollable extreme climate events (such as drought, flood, snow disaster, etc.), the vulnerability of human society and ecosystem to climate change is gradually exposed, that is, the vulnerable nature of social-ecological system to climate change disturbance and pressure, which shows that the system is developing in a direction that is not conducive to its own stability and human interests. Yunnan Province is an important ecological barrier and strategic channel in Southwest China, which plays a vital role in stabilizing and supporting national development. However, because of the special geographical environment and historical reasons, the gap between the development of Yunnan Province and that of the whole country is still widening, which needs further support from the state (Ding et al., 2014). Under its important position, it is of great implication to the study regarding vulnerability and spatial pattern of social-ecological system in Yunnan Province for the sustainable development of Yunnan Province in the future.

As a hot spot and frontier in the study of global environmental change and regional sustainable development, many scholars have carried out a lot of research on vulnerability (Jia et al., 2018; Amos et al., 2015; Bardsley and Wiseman, 2012; Gumming et al., 2005). The research perspective mainly focuses on the vulnerability of climate change system (Mcdowell et al., 2016; Pandey and Bardsley, 2015; Ford and Smit, 2004; Mendoza Maria et al., 2014) and the vulnerability of sustainable livelihoods (Below et al., 2012; Preston et al., 2011). Scholars at home and abroad have not yet reached an agreement on the vulnerability analysis framework and evaluation system. According to different research objects and purposes, the analysis framework and indicator system adopted are different. Many scholars have put forward vulnerability analysis framework based on different perspectives such as sustainable science and social geography. Turner et al. (2003) proposed an interactive vulnerability analysis framework for the coupled human-environment system and introduced the application process of the framework in combination with three cases. Lures et al. (2003) analyzed and measured the vulnerability and adaptability of different regions based on local scale. Some scholars choose to use the vulnerability framework of the International Panel of Climate Change (IPCC) to assess vulnerability from three aspects: exposure-sensitivity-adaptability. Ahsan and Warner (2014) measured the socioeconomic vulnerability of the coastal areas in southwest Bangladesh. Hahn et al. (2009) used the IPCC’s sustainable livelihood framework to separately measure the livelihood vulnerability of Mozambique. Morzaria-Lina et al. (2014) studied the social vulnerability of fishing communities in the Gulf of Mexico in Northern California to climate change. Some scholars made an evaluative analysis on the ecosystem vulnerability of climate change from the perspective of risk and sensitivity (Sisira et al., 2018). Some evaluated vulnerability of the social-ecological system of scenic spots from the compassion of the system to exterior intervention and the flexibility to risk (Fedele et al., 2019).

With the deepening of human understanding of vulnerability, the concept of vulnerability has gradually expanded to integrate nature, economy, society, humanities, environment and other comprehensive categories. The establishment of vulnerability index system not only focuses on climate and ecological factors but also pays more attention to local social, economic, political background and cultural traditions (Adger et al., 2005; Aryal et al., 2017; Maikhuri et al., 2017; Biggs, 2011). Specific economically easily broken areas and susceptible groups have also received increasing attention. However, there are a small number of existing studies that have methodically assessed the vulnerability of the social-ecological system in micro rural areas to climate change, and case studies on the vulnerability of groups in dissimilar regions of Yunnan Province are even more lacking. In the long-term coexistence with natural ecosystems, Yunnan Province of China has formed a flexible knowledge and practice to cope with climate change, which plays a special role in vulnerability assessment, which provides space for this study.

In the future, climate change will continue for a long time. Under the pressure of climate change, it is urgent to explore whether the rural social-ecological system is vulnerable under the impact of climate change, how to take action to reduce the vulnerability of the system and adapt to the impact of climate change. Therefore, the comprehensive assessment of the vulnerability level of rural social-ecological system to climate change is of great significance to reduce the vulnerability of social-ecological system and improve its adaptability. It is the scientific basis for the country to formulate climate change response strategies, and it is the demand for realizing regional sustainable development.

On the basis of social-ecological system theory, this study establishes a “climate-livelihood” vulnerability analysis framework. According to this source, from the three dimensions of exposure, sensitivity and adaptability, the index system of social ecological system vulnerability is constructed by selecting explanatory indexes, respectively. The entropy process is used to determine the vulnerability index, exposure, sensitivity and adaptability of the social-ecological system in different regions of Yunnan Province and put forward appropriate suggestions.

2. Research framework and index selection

2.1 Research framework

The IPCC believes that vulnerability is the degree to which a system is susceptible but unable to deal with the various adverse effects of climate change. It depends on exposure, sensitivity and adaptability, and is a function of the characteristics, rate, intensity of the external climate change of a certain system, as well as the internal sensitivity and adaptability of the system (Parry et al., 2007). Based on the definition of vulnerability, the IPCC proposes an analysis framework of “exposure-sensitivity-adaptability.” Exposure mainly refers to the characteristics and rate of climate change that disturbs the social-ecological system. Sensitivity is usually defined as the degree to which the system responds to climate change, such as the structure, components, basic functions of an ecosystem and the economic development basis of a social system under certain climate change conditions. Adaptability refers to the degree to which the structure, activities and processes of the system can actively adjust in the face of potential and actual climate change.

The sustainable livelihood vulnerability analysis framework of Pandey et al. (2017) measured the vulnerability of the five major livelihood capitals of human capital, natural capital, physical capital, social capital and financial capital under climate change in the three dimensions of exposure, sensitivity and adaptability. The vulnerability analysis framework of regional human-ground coupling system by Turner et al. (2003) believes that under the pressure of global environmental changes, the adaptive flexibility of ecological system and the carrying capacity of human society are different, and the sensitivity and resilience performance of different subsystems are also different. The framework selects indicators according to different characteristics of each system and analyzes the vulnerability of human-environment coupling system. This study draws on the IPCC’s “exposure-sensitivity-adaptability” vulnerability analysis framework, refers to the five livelihood indicators of human capital, natural capital, physical capital, social capital and financial capital of Pandey’s sustainable livelihood vulnerability evaluation and integrates Turner’s research thoughts on the vulnerability of the human-environment coupling system, which considers the sensitivity characteristics of ecological system and social system, respectively, finally constructing the “climate-livelihood” vulnerability analysis framework of social-ecological system (Figure 1). The integrated vulnerability analysis framework expands the specific index system of the IPCC’s “exposure-sensitivity-adaptability” vulnerability framework, fills the vacancy of the sustainable livelihood vulnerability index system for climate change factors and at the same time makes up for the shortcomings of the human-environment coupling system vulnerability framework that is hard to measure. On the basis of “climate-livelihood” analysis framework, this paper constructs the vulnerability evaluation index system, so as to systematically and comprehensively assess the vulnerability level of the social-ecological system.

2.2 Index system construction

On the basis of “climate-livelihood” vulnerability analysis framework, combined with the research outcomes of well-known scholars and the particular circumstances of the study area (Zhu et al., 2018; Li and Ford, 2019; Armatas et al., 2017; Binita et al., 2015; Stefanie et al., 2019; Zuniga-Upegui et al., 2019; Shinn and Hall-Reinhard, 2019), this paper constructs an evaluation index system from three dimensions of exposure, sensitivity and adaptability (Table 1).

In vulnerability research, exposure generally refers to the degree of stress on the system. The exposure risk in Yunnan Province mainly comes from the interference of climate variability and natural disasters. Therefore, the index factors of climate variability and natural disasters are mainly considered to measure the exposure degree of the study area. Climate variation is the internal change of the characteristics of climate factors. This paper mainly selects two indicators, the mean square deviation of annual average temperature and mean square error of annual average rainfall, to evaluate the climate variability index. Natural disasters refer to extreme climate events, which are the external characteristics caused by the change of climate factors. It mainly includes three indicators: flood frequency, frequency of drought and frequency of heavy snow.

Sensitivity refers to the degree to which the system is changed or affected by interference. The sensitivity is determined by the properties of the system itself, and the relatively stable system is generally less sensitive. The sensitivity of the regional social-ecological system is closely related to the carrying capacity of rural resources and the environment, social factors and so on. It is different from the exposure index which is mostly natural factors. The difference in the sensitivity of the social-ecological system in rural areas of Yunnan Province is largely reflected in the differentiation of social development. Therefore, the sensitivity dimension of this paper mainly comes from the key factors of social subsystem, ecological subsystem and social-ecological system closeness. The social subsystem mainly includes three specific indicators: the proportion of social support, the effective irrigation rate of cultivated land and the proportion of female-dominated households. The ecological subsystem mainly includes two indicators: forest coverage and air quality excellence rate. The social-ecological system closeness refers to the degree of dependence and interaction between the social and ecological system, which determines the system’s ability to withstand climate change. The higher the nearness, the lower the sensitivity and the lower the vulnerability. The social-ecological system closeness is primarily assessed by two indicators: residential stickiness and the extent of deforestation.

Adaptability refers to the system’s response to stress and its adjustment to the consequences of stress. Although both sensitivity and adaptability describe system attributes, the former focuses more on describing the stability of the system’s status quo, whereas the latter more reflects the flexibility of the system after being hit. Consequently, the index of adaptability focuses more on describing the sustainability of the future development of the system. Because the adaptability criterion mainly emphasizes the adaptation of human society to risk, the indicators in this paper are all man-made processes associated with risk response. The dimension of adaptability in this paper is mainly evaluated by two indicators: adaptation willingness and adaptation capital. Adaptation willingness refers to the subjective expression of whether farmers are willing to actively adapt to climate change, including two parameters: climate change perception and the proportion of households actively participating in ditch management. Adaptation capital refers to the various types of capital that farmers need to adapt to climate change, including natural capital, human capital, physical capital, financial capital and social capital. The higher the adaptation capital, the stronger the adaptability to resist risks.

3. Material and methods

3.1 Study area

Yunnan is located in the southwestern border of China (21°8′ N–29°15′ N, 97°31′ E–106°11′ E) (Figure 2). Yunnan is a mountainous plateau terrain. The area with a middle altitude of 1,000–3,500 m accounts for 87.21% of the whole province’s land area. Most areas of Yunnan Province are located in the middle altitude area. The climate of Yunnan basically belongs to subtropical plateau monsoon type. The three-dimensional climate features are remarkable, with numerous types, small annual temperature differences, large daily temperature differences, distinct dry and wet seasons and unusual vertical changes in temperature with the terrain. The annual average temperature is 15–16°C, and the frost-free period is 210–330 days. The annual precipitation is 800–1,200 mm, with abundant rainfall, but the spatial and temporal distribution is uneven. Because of the complexity and diversity of topography, geomorphology and geographical environment, the spatial and temporal distribution of light, heat, water, gas and other natural resources is uneven and greatly different. Coupled with human disturbance (deforestation and land reclamation, steep slope farming, mining and logging and other unreasonable use of resources), the problem of ecological degradation is serious, resulting in a decline in the productivity and recovery capacity of the system, and the ecological environment is very fragile.

In the province’s 394,100 square kilometers of land area, mountains account for 94%, and only 6% are intermountain basins, which belong to low-latitude and high-altitude areas. The characteristics of many mountains, many ethnic minorities, a large number of poor people and diverse climate changes make Yunnan Province a region where ecologically fragile and economically backward coexist. Therefore, it is of great significance to study the vulnerability of social-ecological system in Yunnan Province, which can not only guide the direction of the restoration and reconstruction of the ecological environment, but also provide a basis for regional sustainable development.

3.2 Research method

There are many research methods on vulnerability. Entropy technique is an impartially biased multi-index comprehensive evaluation method. It determines the weight of the index according to the degree of connection of each index or the amount of information provided by each index. It can impartially and exactly assess the research object, so it is adopted by many scholars (Li and Jin, 2019; Jena and Pradhan, 2020; Perera et al., 2019; Zhang, 2019). This paper first uses the entropy technique to acquire the assessment values of the three criteria layers of exposure, sensitivity and adaptability and then uses formula (7) to obtain the vulnerability index. The exact steps are as follows:

  • Standardization of indicators: To eliminate the influence of different index dimensions, this study uses extreme value method to standardize the data of each index:

    (1) Standardization of positive indicators:Zij=Xij-XjminXjmax-Xjmin
    (2) Standardization of negative indicators:Zij=Xjmax-XijXjmax-Xjmin

  • Among them, Xij is the original value of the jth index in the ith functional subset, Xjmax is the maximum value of the jth index and Xjmin is the minimum value of the jth index.

  • Determine the weight of each indicator: In this paper, the entropy method is used to calculate the index weight. The specific steps are as follows:

  • Calculate the index value proportion of the ith functional subset under the jth index:

    (3) Pij=Zij/i=1nZij
    (4) Calculate the entropy value of the jth index:ej=-1/lnni=1nPij  ln  Pij
    (5) Calculate the weight of the jth index:Wj=(1-ej)/j=1n(1-ej)

  • Calculate exposure, sensitivity and adaptability values:

    (6) E=i=15EiWi S=k=17SkWk A=j=112AjWj

    Among them, E, S and A are exposure, sensitivity and adaptability values, respectively; Ei, Sk and Aj are the standardized scores of the ith index of exposure, the kth index of sensitivity and the jth index of adaptability, respectively; Wi, Wk and Wj are the weights of the ith index, the kth index and the jth index, respectively.

  • Calculate the “climate-livelihood” vulnerability index (Hahn et al., 2009):

    (7) VI=E-A*S

    In the formula, VI∈[−1, 1], −1 means the least fragile, 1 means the most fragile and 0 means not fragile. The larger the VI value, the stronger the vulnerability.

3.3 Data sources

Data sources comprise government statistics besides questionnaire surveys. The government statistical data come from the pertinent statistical data from 2015 to 2019, such as Yunnan Statistics Bureau, Agriculture Bureau, Forestry Bureau, Environmental Protection Bureau, Meteorological Bureau, Forestry Ecological Status Bulletin of Yunnan Province and Forest Resources Situation Circular of Yunnan Province, as well as chronological records of the village where the survey site is located.

The data of questionnaire survey come from a sample household survey of rural households in various regions of Yunnan Province in 2019. A total of 480 rural households were selected in this paper. The climate change situation of the chosen regions has convinced differences, and each has its typical representativeness. It is possible to examine the relevant experience, compassion and flexibility status of social-ecological systems in different regions under climate change and then analyze the impact of various indicators on vulnerability.

4. Results

4.1 Vulnerability of social-ecological system to climate change in Yunnan Province

4.1.1 Overall level of vulnerability.

According to the overall vulnerability assessment results (Table 2), the social-ecological system has high exposure to climate change (0.809), strong sensitivity (0.729) and moderate adaptability (0.297). The overall level of social-ecological system vulnerability is moderate (0.373).

For the secondary indicators, according to the research results and the actual situation of Yunnan Province, it is generally considered that if the exposure is greater than 0.5, it is relatively high; if the sensitivity is greater than 0.1, it is relatively high; if the adaptation capital is less than 0.3, it is relatively low. The social-ecological system exposure in Yunnan Province is relatively high. In the past five years, although the rate of climate variability is not significant (0.291), natural disasters are significant (0.518), which has increased the vulnerability of the region to climate change to a certain extent. Yunnan, located in the southwest border of the motherland, is a combination of frontier, nationality, mountainous area and poverty. The ecological foundation is relatively weak, making the local ecological sensitivity higher (0.150), and the closeness between the social-ecological system is poor, with the sensitivity of 0.232. To a large extent, the traditional natural resource management has failed to form a good interaction between social systems and ecosystems. It has not only failed to make rational use of local natural resources but also increased the sensitivity of the region to climate change. At the same time, because the local social public service supply is not very sound, the sensitivity of social system is strong (0.347), and the adaptation capital is low (0.225), which increases the vulnerability of social-ecological system to climate change to a certain extent. The impact way and amount of the exact indicators regarding the vulnerability of the social-ecological system of Yunnan Province will be carried out in the study regarding influencing factors of vulnerability

4.1.2 Analysis of the influencing factors of vulnerability.

4.1.2.1 Exposure assessment results.

The social-ecological system exposure of Yunnan Province is 0.809, which is at a relatively high level. In recent five years, the distinction intensity of annual average rainfall is 0.132. In a short period of time, the variability level of climate factors in Yunnan Province is not high (0.291). However, the natural disasters caused by climate variation are significant (0.518), and extreme climate events such as flood, drought and heavy snow occur every year. Climate change, variability and extreme climate events have the most serious impact on the farming besides forestry production of the social-ecological system. In the spring of 2020, Yunnan suffered the worst drought in nearly 10 years, and 4.6 million mu of crops were affected. The higher the social-ecological system’s exposure to climate change, the greater the vulnerability of Yunnan’s livelihoods. While other conditions remain unchanged, for every 0.1 increase in climate change exposure, the vulnerability of livelihoods will amplify by 0.073. The assessment chart regarding the index values of the social-ecological system’s exposure to climate change is shown in Figure 3.

4.1.2.2 Sensitivity assessment results.

The social-ecosystem sensitivity level of Yunnan Province is relatively high (0.729). According to Table 2, the sensitivity of the social subsystem is 0.347. The effective irrigation rate of cultivated land is 0.068. The proportion of social support (0.131) and the proportion of female-dominant households (0.148) have higher index values, which have a greater impact on sensitivity. It is manifested in the serious aging of the social population, and the proportion of elderly over 60 years old is as high as 12.4%. In addition, part of the male labor force goes out to work, and almost half of the households are dominated by women. As a vulnerable group, women have to bear the burden of caring for the elderly and children when carrying out production activities such as planting and breeding, which leads to the lack of local human capital to cope with climate change and increase vulnerability. The ecological subsystem has a low sensitivity of 0.150. The index values of forest coverage rate and air quality excellence rate are 0.082 and 0.068, respectively. On the one hand, the forest coverage rate and air quality excellence rate of Yunnan Province are higher, which makes it more resistant to climate change and less sensitive. On the other hand, the local ecosystem is well managed and protected, which makes it more resilient when impacted by extreme climate events. In addition, when encountering extreme weather events such as drought, local farmers will flexibly adjust planting types and varieties such as changing paddy fields to dry fields and plant corn instead of rice, stabilize food production under the impact of climate change, maintain livelihoods and reduce vulnerability risks. The closeness of the social-ecological system is general, with a sensitivity of 0.232. Human activities are less destructive to the ecological environment and have a stronger sense of belonging. The degree of deforestation is only 0.087, and the residential viscosity is 0.145, which can effectively reduce the vulnerability of the social-ecological system. On the whole, for every 0.1 decrease in sensitivity, the vulnerability decreases by 0.051. The assessment chart of the index values of the social-ecological system’s sensitivity to climate change is shown in Figure 4.

4.1.2.3 Adaptability assessment results.

As for adaptability, it is generally considered that if the value of adaptation willingness is greater than 0.02, the value of the index is higher. On the whole adaptability of Yunnan Province is 0.297, which is generally lower level. Because of the high perception of climate change in Yunnan Province (0.042), the initiative of local villagers to participate in the maintenance of village ditches is strong (0.030), and the local willingness to adapt is higher (0.072), which provides an action basis for effective adaptation and response to climate change. However, all kinds of adaptation capital in Yunnan Province are relatively low, which greatly limits the adaptability and increases the livelihood vulnerability of Yunnan Province to climate change. The index values of natural capital, physical capital, human capital, social capital and financial capital are 0.019, 0.044, 0.048, 0.047 and 0.067, respectively. Among them, natural capital is the lowest. Through the investigation, it is found that the arable land resources available to farmers are relatively small, which is closely related to the land distribution system. In addition, because of the limitation of terrain and soil conditions, the output value of cultivated land per mu is relatively low. When extreme weather events occur, farmers’ livelihoods are severely affected by climate change, and their vulnerability is low. As for social capital, the proportion of households participating in cooperatives is very small (0.005), and its role in climate change response is limited. Rural cooperatives can reduce farmers’ production costs and disaster risks, but most of the cooperative systems are not yet complete. In addition, human capital is also relatively low. The family’s average labor capacity is 0.032, and the family’s population structure is dominated by the elderly and children, with limited labor capacity. The education level of the head of the household is low (0.016). As rural areas in Yunnan Province are generally located in remote mountainous areas, the number of local primary and secondary schools is small, the conditions are simple and the number and quality of teachers are insufficient, which severely restricts the level of education. The low level of education is one of the important factors that restrain the improvement of human capital. Among the five types of capital, the financial capital is relatively high. Because of the local good social network, residents with common beliefs carry forward the local mutual help mechanism. Free assistance from relatives and friends can help to reduce the cost of climate change adaptation, thereby reducing vulnerability. Generally, for every 0.1 increase in adaptability, the vulnerability will decrease by 0.073. The comparison chart of the five types of adaptation capital is shown in Figure 5.

4.2 Spatial difference analysis of vulnerability

The previous research principally analyzes the general vulnerability level of Yunnan Province. To estimate the reliability of the area, this research takes the municipal administrative region as the assessment element, studies and analyzes the social-ecological system vulnerability of different regions in Yunnan Province (Table 3). By analyzing the susceptibility category of different regions in Yunnan Province, we can propose social-ecological system re-establishment and maintenance countermeasures for different vulnerability degree and characteristics, which can make available a scientific basis for the country and the world to formulate policies related to climate change. According to Table 3, Zhaotong has the highest vulnerability (0.613), and Yuxi has the lowest vulnerability (0.194). The social-ecological system vulnerability of eight regions is higher than the overall average level of Yunnan Province (0.373).

According to the beyond computational results, on the basis of related study and collective along with the authentic state of the study area, the social-ecological system vulnerability of Yunnan Province is divided into five levels: extremely vulnerable, severely vulnerable, moderately vulnerable, mildly vulnerable and slightly vulnerable. If VI > 0.50, it is extremely vulnerable, 0.40 < VI < 0.50 is severely vulnerable, 0.30 < VI < 0.40 is moderately vulnerable, 0.20 < VI < 0.30 is mildly vulnerable and VI < 0.20 is slightly vulnerable. The detailed dissection results are shown in Table 4 and Figure 6.

4.2.1 Extremely vulnerable area.

The distinctiveness of the social-ecological system of this level are: the social-ecological system is extremely delicate, the system is under great pressure, the stability is extremely weak and the resilience is extremely weak or even irreversible. The results of the study show (Table 4 and Figure 6) that extremely vulnerable areas are mainly distributed in Zhaotong in the northeast of Yunnan, Qujing in the east and Wenshan in the southeast. The total area is 84,164 km2, accounting for 21.45% of the total area of the province. As part of the area is located in the hot and dry valley of the Jinsha River, the climate is arid, the water and heat are extremely unbalanced, the population density is high, the forest coverage rate is low and the ecological damage caused by people is serious, so it is difficult to recover vegetation. The per capita gross domestic product is at a low level, and the overall economy of urban and rural residents is not rich. This area is mainly based on agriculture, the soil fertility is low and the grain yield per mu is little. Therefore, it leads to higher exposure and sensitivity, as well as lower adaptability.

4.2.2 Severely vulnerable area.

The social-ecological system distinctiveness of this level is as follows: social-ecological system vulnerability is strong; the system has great changes, strong instability and weak coping ability. The severely vulnerable areas are mainly distributed in Honghe in southern Yunnan and Dali, Nujiang and Baoshan areas in the west. The total area is 96,730 km2, accounting for 24.65% of the total area of the province. The geological environment of this type of area is extremely complex, and most of the areas belong to the strong geological activity zone. Geological disasters such as landslides and mudslides occur frequently. At the same time, the forest coverage rate is generally low, people’s living standard is not high and the ecological environment is greatly disturbed. The per capita arable land area is at a medium level, the overall economy of urban and rural residents is still not rich and the closeness of the social-ecological system is low, which is also an important reason for the fragile social-ecological system.

4.2.3 Moderately vulnerable area.

The distinctiveness of the social-ecological system at this level are: the social-ecological system is highly vulnerable, and system disorders have already occurred; the system pressure approaches the threshold value, the volatility becomes stronger and the recovery ability decreases. The moderately vulnerable areas are mainly distributed in Kunming in central Yunnan, Chuxiong in the west, Diqing in the northwest and Lincang and Puer in the southwest. The total area is 144,455 km2, accounting for 36.82% of the total area of the province. It can be seen that the overall vulnerability of Yunnan Province is moderate and severe. The climate in this region is relatively humid, the vegetation coverage rate is high and the per capita water resources are relatively high, which is higher than that of the extremely vulnerable and severely vulnerable areas. However, the problems of low per capita cultivated land, low grain yield per unit area and low education level of residents are still prominent.

4.2.4 Mildly vulnerable area.

The distinctiveness of the social-ecological system at this level are: the vulnerability of social-ecological system is low and there are potential problems; the internal and external changes of the system are small, moderately stable and have strong modification capabilities. The mildly vulnerable areas are mainly distributed in Dehong in western Yunnan, Lijiang in the northwest and Xishuangbanna in the southwest. The total area is 51,708 km2, accounting for 13.18% of the total area of the province. This type of area has less rainfall and higher population density, which has a certain pressure on the ecological environment but has a better recovery capacity.

4.2.5 Slightly vulnerable area.

The social-ecological system distinctiveness of this level is as follows: the vulnerability of social-ecological system is low, the internal and external changes of the system are small and stable and the regulation capability is strong. The slightly vulnerable areas are mainly disseminated in Yuxi in central Yunnan. The total area is 15,285 km2, accounting for 3.90% of the total area of the province. This type of area is better for the operation and maintenance of the social-ecological system. The social-ecological system is less sensitive and more resilient to climate change, thereby reducing the vulnerability of livelihoods. In addition, the adaptation capitals of these regions are relatively high. These adaptation capitals play an important role in the practice of climate change adaptation. The more adaptation capital, the less vulnerable to climate change.

5. Discussion

The research on regional vulnerability has been continuously deepened at home and abroad (Thiault et al., 2017). The evaluation of vulnerability is also constantly developing, and new evaluation methods are constantly being explored and are gradually used by the majority of scholars at home and abroad, such as regression analysis (Barreteau et al., 2020), analytic hierarchy process (Hagenlocher et al., 2018), artificial neural network (Naylor et al., 2019), fuzzy evaluation (Frazier et al., 2014) and so on. Each evaluation method has its advantages and disadvantages. According to the real situation of the study area, this paper selects the entropy method as the evaluation method of the rural social-ecological system in Yunnan Province. The cause is that the entropy technique can intensely imitate the utility value of the index information entropy value and thus determine the weight. This approach is consistent with the vulnerability assessment method. In addition, the entropy method is an objective weighting method, so the weights of indicators derived from it are more intention, with moderately high reliability and accuracy (Winkler et al., 2018). Taking Yunnan Province as an example, this paper not only evaluates the overall vulnerability of the social-ecological system of Yunnan Province from the perspective of vulnerability but also analyzes the spatial differences in the vulnerability of 16 states (cities) in Yunnan Province. The assessment results are basically reliable with the actual geological environment of Yunnan Province. It shows that the research results have very high reliability.

Though this study holds convinced limitations. Constructing an entire assessment index system is the basis for the vulnerability assessment of the rural social-ecological system. Starting from the regional scale, this paper selects typical cases and observes it as a social-ecological system. On the Basis of “climate-livelihood” vulnerability analysis framework, an inclusive vulnerability evaluation index system composed of 24 indicators is constructed. Because of the complexity of the factors that affect system vulnerability and their interrelationships, as well as the limitations in understanding the connotation of vulnerability, additional explorations will be made in index selection, theoretical cognition, mechanism analysis and so on to construct a more scientific and reasonable rural social-ecological system vulnerability assessment index system, focusing on the relationship between the components of vulnerability. In addition, limited by the availability of data, this paper only assesses the vulnerability of rural social-ecological systems in Yunnan Province from a single time and space. Though the vulnerability of the study area is the result of time accumulation, its vulnerability will also evolve over time. Future research also needs to pay attention to the dynamic changes and evolutionary laws of vulnerability. Research on adaptation strategies needs to combine dynamic changes in vulnerability and dynamically adjust plans and actions based on the feedback results of practice to improve the regional adaptability to climate change.

6. Conclusions

The entropy technique is used to assess the vulnerability of the social-ecological system in Yunnan Province. First, make an overall assessment of the vulnerability of the social-ecological system in Yunnan Province. Second, it is divided into five major levels according to the size of vulnerability. The valuation results are steady along with the distinctiveness of the ecological environment besides social economy of each region, which proves the feasibility of the evaluation method. This method can be used to evaluate the vulnerability of social-ecological systems in other regions.

On the whole, the vulnerability of the social-ecological system in Yunnan Province is at a medium level. First, irregular temperature and rainfall climatic factors, intense natural disasters such as droughts and floods frequently occur, which threaten the production and life of rural communities and show the way to higher exposure to climate change. Second, the social-ecological system compassion is strong. The effective irrigation rate of cultivated land, the proportion of social support and the proportion of female-dominant households are important factors that affect the sensitivity of the social-ecological system. Finally, the adaptability of the social-ecological system in Yunnan Province is general, and the participation in drain management is not high. Natural capital, physical capital and social capital are important factors that confine adaptability.

Dividing Yunnan Province into five levels of social-ecological system vulnerable areas will be able to provide supremacy instructions for the reinstatement and building of the social-ecological system. The extremely vulnerable areas and the severely vulnerable areas should be treated with priority. Strengthen supervision and governance in moderately vulnerable areas. Mildly vulnerable areas and slightly vulnerable areas should spotlight on strengthening and take matching measures to restore the social-ecological system. In short, only by continuously strengthening regional ecological construction, improving the level of adaptability, scientifically and rationally planning and effectively reducing exposure can we maintain and promote the stability and sustainable development of the social-ecological system in Yunnan Province.

Figures

Analysis framework of “climate-livelihood” vulnerability of social-ecological system

Figure 1.

Analysis framework of “climate-livelihood” vulnerability of social-ecological system

Geographical location of the study area

Figure 2.

Geographical location of the study area

Comparison chart of each index value of exposure

Figure 3.

Comparison chart of each index value of exposure

Comparison chart of each index value of sensitivity

Figure 4.

Comparison chart of each index value of sensitivity

Comparison chart of five kinds of adaptation capital

Figure 5.

Comparison chart of five kinds of adaptation capital

Schematic diagram of the classification of social-ecological system vulnerability in Yunnan Province

Figure 6.

Schematic diagram of the classification of social-ecological system vulnerability in Yunnan Province

Social-ecological system vulnerability index system

First-level indicators Secondary indicators Third-level indicators
Exposure Climate variability Mean square deviation of annual average temperature
Mean square error of annual average rainfall
Natural disasters Flood frequency
Frequency of drought
Frequency of heavy snow
Sensitivity Social subsystem Proportion of social support
Effective irrigation rate of cultivated land
Proportion of female-dominated households
Ecological subsystem Forest coverage
Air quality excellence rate
Social-ecological system closeness Residential stickiness
Extent of deforestation
Adaptability Adaptation willingness Proportion of households involved in ditch management
Climate change perception
Natural capital Per capita cultivated land area
Output value per mu of cultivated land
Physical capital Types of fixed assets
Per capita housing area
Human capital Household labor force
Education level of adult labor force
Social capital Social network support
Proportion of families participating in cooperative organizations
Financial capital Annual household income
Proportion of families receiving unpaid financial help

Evaluation results of social-ecological system vulnerability

First-level
indicators
Mean
value
Secondary indicators Mean
value
Third-level indicators Mean
value
Exposure 0.809 Climate variability 0.291 Mean square deviation of annual average temperature (0.2042) 0.159
Mean square error of annual average rainfall (0.1621) 0.132
Natural disasters 0.518 Flood frequency (0.1744) 0.164
Frequency of drought (0.2838) 0.206
Frequency of heavy snow (0.1755) 0.148
Sensitivity 0.729 Social subsystem 0.347 Proportion of social support (0.1123) 0.131
Effective irrigation rate of cultivated land (0.0845) 0.068
Proportion of female-dominated households (0.1308) 0.148
Ecological subsystem 0.150 Forest coverage (0.1344) 0.082
Air quality excellence rate (0.1258) 0.068
Social-ecological system closeness 0.232 Residential stickiness (0.1842) 0.145
Extent of deforestation (0.2280) 0.087
Adaptability 0.297 Adaptation willingness 0.072 Proportion of households involved in ditch management (0.0645) 0.030
Climate change perception (0.0581) 0.042
Natural capital 0.019 Per capita cultivated land area (0.1021) 0.015
Output value per mu of cultivated land (0.0636) 0.004
Physical capital 0.044 Types of fixed assets (0.0848) 0.021
Per capita housing area (0.1021) 0.023
Human capital 0.048 Household labor force (0.0956) 0.032
Education level of adult labor force (0.1214) 0.016
Human capital 0.047 Social network support (0.0687) 0.042
Proportion of families participating in cooperative organizations (0.1123) 0.005
Financial capital 0.067 Annual household income (0.0603) 0.036
Proportion of families receiving unpaid financial help (0.0665) 0.031
Vulnerability 0.373
Note:

Numbers in brackets are index weights

Source: Compiled from research data result

Vulnerability values of social-ecological systems in different regions of Yunnan Province

Study area Exposure Sensitivity Adaptability Vulnerability
Kunming 0.784 0.692 0.325 0.318
Qujing 0.883 0.815 0.242 0.522
Yuxi 0.667 0.608 0.348 0.194
Zhaotong 0.946 0.853 0.227 0.613
Chuxiong 0.797 0.703 0.314 0.340
Honghe 0.845 0.773 0.272 0.443
Wenshan 0.914 0.826 0.231 0.564
Puer 0.809 0.718 0.318 0.353
Dali 0.841 0.783 0.286 0.435
Baoshan 0.826 0.776 0.301 0.407
Dehong 0.742 0.654 0.315 0.279
Lijiang 0.713 0.628 0.341 0.234
Nujiang 0.867 0.801 0.248 0.496
Diqing 0.766 0.683 0.321 0.304
Lincang 0.838 0.741 0.313 0.389
Xishuangbanna 0.698 0.613 0.344 0.217

Source: Compiled from research data result

Classification and area of social-ecological system vulnerability in Yunnan Province

Grades Regions Areas (km2) Area proportion (%)
Extremely vulnerable Zhaotong, Wenshan, Qujing 84,164 21.45
Severely vulnerable Nujiang, Honghe, Dali, Baoshan 96,730 24.65
Moderately vulnerable Lincang, Puer, Chuxiong, Kunming, Diqing 144,455 36.82
Mildly vulnerable Dehong, Lijiang, Xishuangbanna 51,708 13.18
Slightly vulnerable Yuxi 15,285 3.90

Source: Compiled from research data result

References

Adger, W.N., Arnell, N.W. and Tompkins, E.L. (2005), “Successful adaptation to climate change across scales”, Global Environmental Change, Vol. 15 No. 2, pp. 77-86.

Ahsan, M.N. and Warner, J. (2014), “The socioeconomic vulnerability index: a pragmatic approach for assessing climate-change led risks- a case study in southwestern coastal Bangladesh”, International Journal of Disaster Risk Reduction, Vol. 8, pp. 32-49.

Amos, E., Akpan, U. and Ogunjobi, K. (2015), “Households’ perception and livelihood vulnerability to climate change in a coastal area of Akwa Ibom state, Nigeria”, Environment, Development and Sustainability, Vol. 17 No. 4, pp. 1-22.

Armatas, C., Venn, T. and Watson, A. (2017), “Understanding social–ecological vulnerability with Q-methodology: a case study of water-based ecosystem services in Wyoming, USA”, Sustainability Science, Vol. 12 No. 1, pp. 105-121.

Aryal, S., Cockfield, G. and Maraseni, T.N. (2017), “Globalisation and traditional social-ecological system: understanding impacts of tourism and labor migration to the transhumance systems in the Himalayas”, Environmental Development, Vol. 25, pp. 73-84.

Bardsley, D.K. and Wiseman, N.D. (2012), “Climate change vulnerability and social development for remote indigenous communities of South Australia”, Global Environmental Change, Vol. 22 No. 3, pp. 713-723.

Barreteau, O., Anderies, J.M., Guerbois, C., Quinn, T. and Bousquet, F. (2020), “Transfers of vulnerability through adaptation plan implementation: an analysis based on networks of feedback control loops”, Ecology and Society, Vol. 25 No. 2.

Below, T.B., Mutabazi, K.D., Kirschke, D., Franke, C., Sieber, S. and Siebert, R. (2012), “Can farmers’ adaptation to climate change be explained by socio-economic household-level variables?”, Global Environmental Change, Vol. 22 No. 1, pp. 223-235.

Biggs, D. (2011), “Understanding resilience in a vulnerable industry: the case of reef tourism in Australia”, Ecology and Society, Vol. 16 No. 1, p. 30.

Binita, J., Marshall, S. and Cassandra, J.G. (2015), “Climate change vulnerability assessment in Georgia”, Applied Geography, Vol. 62, pp. 62-74.

Ding, W., Ren, W., Li, P., Hou, X., Sun, X. and Li, X. (2014), “Evaluation of the livelihood vulnerability of pastoral households in Northern China to natural disasters and climate change”, The Rangeland Journal, Vol. 36 No. 6, pp. 535-543.

Fedele, G., Donatti, C.I., Harvey, C.A., Hannah, L. and Hole, D.G. (2019), “Transformative adaptation to climate change for sustainable social-ecological systems”, Environmental Science and Policy, Vol. 101, pp. 116-125.

Ford, J.D. and Smit, B. (2004), “A framework for assessing the vulnerability of communities in the Canadian arctic to risks associated with climate change”, ARCTIC, Vol. 57 No. 4, pp. 389-400.

Frazier, T.G., Thompson, C.M. and Dezzani, R.J. (2014), “A framework for the development of the SERV model: a spatially explicit resilience-vulnerability model”, Applied Geography, Vol. 51, pp. 158-172.

Gumming, G.S., Barnes, G., Perz, S.G., Schmink, M. and Holt, T.V. (2005), “An exploratory framework for the empirical measurement of resilience”, Ecosystems, Vol. 8 No. 8, pp. 975-987.

Hagenlocher, M., Renaud, F.G., Haas, S. and Sebesvari, Z. (2018), “Vulnerability and risk of deltaic social-ecological systems exposed to multiple hazards”, Science of the Total Environment, Vols 631/632, pp. 71-80.

Hahn, M.B., Riederer, A.M. and Foster, S.O. (2009), “The livelihood vulnerability index: a pragmatic approach to assessing risks from climate variability and change: a case study in Mozambique”, Global Environmental Change Human Change, Vol. 19 No. 1, pp. 74-88.

Jena, R. and Pradhan, B. (2020), “Earthquake social vulnerability assessment using entropy method”, IOP Conference Series: Earth and Environmental Science, Vol. 540, p. 012079.

Jia, C., Xinjun, Y., Sha, Y., Kongsen, W., Mengqi, D. and Xin, W. (2018), “The vulnerability evolution and simulation of social-ecological systems in a semi-arid area: a case study of Yulin city, China”, Journal of Geographical Sciences, Vol. 28 No. 2, pp. 152-174.

Li, A. and Ford, J. (2019), “Understanding socio-ecological vulnerability to climatic change through a trajectories of change approach: a case study from an indigenous community in panama”, Weather, Climate, and Society, Vol. 11 No. 3.

Li, B. and Jin, X. (2019), “Spatio-temporal evolution of marine fishery industry ecosystem vulnerability in the Bohai rim region”, Chinese Geographical Science, Vol. 29 No. 6, pp. 1052-1064.

Lures, A.L., Lobell, D.B. and Sklar, L.S. (2003), “A method for quantifying vulnerability, applied to the agricultural system of Yaqui valley Mexico”, Global Environmental Change, Vol. 13 No. 4, pp. 255-267.

Mcdowell, G., Ford, J. and Jones, J. (2016), “Community-level climate change vulnerability research: trends, progress, and future directions”, Environmental Research Letters, Vol. 11 No. 3, p. 033001.

Maikhuri, R.K., Nautiyal, A., Jha, N.K., Rawat, L.S., Maletha, A. and Phondani, P.C. (2017), “Socio-ecological vulnerability: assessment and coping strategy to environmental disaster in Kedarnath valley Uttarakhand, Indian Himalayan region”, International Journal of Disaster Risk Reduction, Vol. 25, pp. 111-124.

Mendoza Maria, E.T., The, B.D., Naret, H. and Arias, J.K.B. (2014), “Assessing vulnerability to climate change impacts in Cambodia, the Philippines and Vietnam: an analysis at the commune and household level”, Journal of Environmental Science and Management, Vol. 17 No. 2, pp. 78-91.

Morzaria-Lina, H.N., Turk-Boyer, P. and Moreno-Baez, M. (2014), “Social indicators of vulnerability for fishing communities in the Northern Gulf of California, Mexico: implications for climate change”, Marine Policy, Vol. 45 No. 2, pp. 182-193.

Naylor, L.A., Brady, U., Quinn, T., Brown, K. and Anderies, J.M. (2019), “A multiscale analysis of social-ecological system robustness and vulnerability in Cornwall, UK”, Regional Environmental Change, Vol. 19 No. 7, pp. 1835-1848.

Pandey, R. and Bardsley, D.K. (2015), “Social-ecological vulnerability to climate change in the Nepali Himalaya”, Applied Geography, Vol. 64, pp. 74-86.

Pandey, R., Jha, S.K. and Alatalo, J.M. (2017), “Sustainable livelihood framework-based indicators for assessing climate change vulnerability and adaptation for Himalayan communities”, Ecological Indicators, Vol. 79, pp. 338-346.

Parry, M.L., Canziani, O.F. and Palutikof, J.P. (2007), “Climate change 2007: impacts, adaptation and vulnerability”, Working Group II Contribution to the Fourth Assessment Report of the IPCC, Cambridge University Press.

Perera, E.N.C., Jayawardana, D.T., Jayasinghe, P. and Ranagalage, M. (2019), “Landslide vulnerability assessment based on entropy method: a case study from Kegalle district, Sri Lanka”, Modeling Earth Systems and Environment, Vol. 5 No. 4, pp. 1635-1649.

Pielke, R.A. and Sarewitz, D. (2005), “Bringing society back into the climate debate”, Population and Environment, Vol. 26 No. 3, pp. 255-268.

Preston, B.L., Yuen, E.J. and Westaway, R.M. (2011), “Putting vulnerability to climate change on the map: a review of approaches, benefits, and risks”, Sustainability Science, Vol. 6 No. 2, pp. 177-202.

Shinn, J.E. and Hall-Reinhard, A. (2019), “Emphasizing livelihoods in the study of social-ecological systems: insights from fishing practices in the Okavango Delta, Botswana”, South African Geographical Journal, Vol. 101 No. 1, pp. 121-139.

Sisira, W., Ilia, K., Giorgi, G., Rami, A.S., Teo, U. and Angelika, P. (2018), “Farmers’ perception of water quality and risks in the Mashavera river basin, Georgia: analyzing the vulnerability of the social-ecological system through community perceptions”, Sustainability, Vol. 10 No. 9, p. 3062.

Stefanie, M., Backhaus, N., Nagabovanalli, P. and Abiven, S. (2019), “A social-ecological system evaluation to implement sustainably a biochar system in South India”, Agronomy for Sustainable Development, Vol. 39 No. 4, p. 43.

Thiault, L., Marshall, P., Gelcich, S., Collin, A., Frédérique, C. and Claudet, J. (2017), “Space and time matter in social-ecological vulnerability assessments”, Marine Policy, Vol. 88 No. 2, pp. 213-221.

Thomalla, F., Downing, T., Erika, S. and Han, G. (2010), “Reducing hazard vulnerability: towards a common approach between disaster risk reduction and climate adaptation”, Disasters, Vol. 30 No. 1, pp. 39-48.

Turner, B.L.I., Kasperson, R.E., Matson, P.A., Mccarthy, J.J. and Schiller, A. (2003), “A framework for vulnerability analysis in sustainability science”, Proceedings of the National Academy of Sciences, Vol. 100 No. 14, pp. 8074-8079.

Winkler, K.J., Scown, M.W. and Nicholas, K.A. (2018), “A classification to align social-ecological land systems research with policy in Europe”, Land Use Policy, Vol. 79, pp. 137-145.

Zhang, L. (2019), “Analysis of TJ economic vulnerability based on set pair analysis”, Journal of Service Science and Management, Vol. 12 No. 2, pp. 116-125.

Zhu, J., Yu, Y., Zhou, S., Wang, X. and Lv, L. (2018), “Simulating sustainable urban development by incorporating social-ecological risks into a constrained CA model”, Chinese Geographical Science, Vol. 28 No. 4, pp. 600-611.

Zuniga-Upegui, P., Arnaiz-Schmitz, C., Herrero-Jauregui, C., Smart, S.M., Lopez-Santiago, C.A. and Schmitz, M.F. (2019), “Exploring social-ecological systems in the transition from war to peace: a scenario-based approach to forecasting the post-conflict landscape in a Colombian region”, Science of the Total Environment, Vol. 695, pp. 1-15.

Acknowledgements

This research was funded by National Natural Science Foundation of China (Grant No. 71940015), Achievements of Key Projects of Yunnan Philosophy and Social Science Planning (Grant No. ZDZZD201907) and Scientific Research Fund Project of Yunnan Provincial Department of Education (Grant No. 2020Y0093). The authors thank the journal editors and the anonymous reviewers for the in-depth review and comments that have greatly improved this paper.

Corresponding author

Changchun Zhou can be contacted at: kmlgdxgjxy@126.com

About the authors

Yueyue He is currently a PhD scholar at the Faculty of Management and Economics, Kunming University of Science and Technology. Her research areas are social sciences, farmers’ livelihood, ecological economy, natural resource management and climate change and social ecosystem vulnerability.

Changchun Zhou received PhD degree from Sun Yat-sen University, Guangzhou. Currently, she is working as Full Professor in the Faculty of Management and Economics, Kunming University of Science and Technology. Her areas of research are social sciences, ecological economy, resource development, tourism management, changes in resources and environment.

Tanveer Ahmed is currently a PhD scholar at the Faculty of Management and Economics, Kunming University of Science and Technology, Kunming City, Yunnan Province China. His areas of research are management sciences, economics, social sciences, knowledge management and natural resources management system. He also worked on different motivational perspectives containing motivational theories with their impact at organizational level along with the areas of knowledge management assessment practices besides different parameters of technology, leadership, organization and learning pillars. He has also worked on supply chain management and innovative theories of leadership. Currently, he is working on new perspectives of empowering leadership with dynamic mediating and moderating parameters for organizational development.

Related articles