1. Introduction
Urban agglomeration (UA), which plays an important role in integrating regional coordinated development, building competitive industry clusters, and promoting industrial transfers between different areas, has gradually become the principal geographic unit for countries to participate in global competition and China’s international division of labor [
1,
2]. However, over the past three decades the development of the UA has had profound effects on the sustainability of the ecosystem. As one of populous social-economic-natural complex ecosystem, the UA ecosystem is more fragile, which is further aggravated by the large demand of resources for industrial production, human consumption, and pollutant emissions [
3,
4]. A considerable amount of factors and its related complex interactions bring a deep impact on ecosystem health and human health with the growth of economy, population, industrialization and urbanization [
5]. Sustained and intensive human activities in the UA have caused serious problems, such as water shortages, air and soil pollution, a decline in biodiversity, depletion of natural resources, and the degradation of major ecosystems. These problems have not only placed considerable burdens upon the development quality of the UA and human life, they have also hindered sustainable ecosystem development and threatened regional and national securities [
6]. With awareness of eco-environmental protection enhancing, studies on the health and security of ecosystems in the UA cities have drawn more attention.
The study of urban ecosystem health (UEH) originated from natural resource management, environmental sciences, ecosystem ecology, and applied ecology [
7,
8,
9,
10,
11]. Several scholars have established the theoretical and methodological foundations of studying the health of a natural ecological system [
8,
9,
10,
12,
13,
14] since the 18th century, which laid the theoretical foundation for the healthy development of the urban ecosystem. As research on UEH increased during the 2000s, more scholars have recognized the UEH’s characteristics of uncertainty and fuzziness [
15,
16] and have actively discussed its assessment method and practical applications [
3,
15,
17,
18,
19,
20]. As the foundation of UEH research, the UEH evaluation is qualitative or quantitative assessment and classification for quality status of complex ecosystem, which the purpose is to understand the underlying stress or health of ecosystems so that can provide scientific basis for the resource utilization, eco-environment protection and the social construction and development [
7,
8,
21]. Extensive efforts have been made to measure UEH by using the health state of the natural ecological system, the socioeconomic system, and human health [
9,
15,
17,
18,
22]. However, although considerable research has been conducted in cities like Beijing, Shanghai, and Guangzhou [
18,
19,
21], studies regarding the UEH of metropolis areas in China remain scarce until now.
At present, many methods have been used to satisfy a health assessment, including the methods of energy analysis [
23], the fuzzy optimal assessment model [
24], the attribute theory model [
25], and the catastrophe progression method [
26]. Although these methods pay attention to the characteristics of UEH [
3] and have played a certain role in promoting the research of UEH, there are some weaknesses, such as information omissions in the process of calculation and the computation processes are quite complicated [
27,
28]. The matter-element extension model is a new method to deal with the incompatibility problems from the quantitative and qualitative perspectives. The model consisted of objects, characteristics and values. In solving problems, it can directly establish a formal model and quantitative analysis methods for an incompatible problem, according the matter-element extension set and correlation function [
29]. Therefore, the content and the relationship between the quantity and the quality of the comprehensive evaluation can be clearly illustrated [
30]. At the same time, the structure of the model is simple, the calculation is easy, and the calculating result is accurate. Crucially, if the health index exceeds the health grading standard, the model can still be calculated by using the comprehensive correlation degrees, which is barely achieved by using other methods.
This study used the 31 cities of UA in the middle reaches of the Yangtze River as its case and generated an entropy weight extension decision model to diagnose the performance of the UA ecosystem health. It cannot only avoid subjectivity in determination of the index weight, it can also effectively overcome the incompatibility of the evaluation index of UEH. The evaluation results are reasonable and enrich the methods of UEH assessment, and calculations are simple and easy. Furthermore, it provides important practical guidance for promoting the healthy, sustainable, and stable development of the city clusters in Central China.
2. Study Area
The UA in the middle reaches of the Yangtze River, also known as the “Triangle of Central China”, centers on the three provincial capital cities of Wuhan, Changsha, and Nanchang and what constitutes the cross-province region by combining the Wuhan Metropolitan Areas, the Ring of Chang-Zhu-Tan City Clusters, and the Poyang Lake Ecological Economic Zone (see
Figure 1). The Erguang highway and multiple high-speed railways (Jingguang, Jingjiu, and Hukun railways) are the ties that form a whole. The UA in the middle reaches of the Yangtze River is situated in Central China and is connected to the Central Plains. This UA area is a gateway to China’s north–south and east–west linkages, and is an important part of the Yangtze River Economic Zone. Meanwhile, the UA in the middle reaches of the Yangtze River is the core area of economic and social development; it plays a crucial role in the urbanization of China, is the fourth pole of China’s regional economic development, and is considered one of the most important UAs. The land area of the UA is 317,000 km
2, accounting for 3.3% of China’s land area. In 2014, the total population was 1.2 million, and the gross domestic product (GDP) was 6 × 10
6 million Yuan (RMB), accounting for 8.8% and 3.3% of the nation, respectively.
The area surrounding the middle reaches of Yangtze River has been extensively recognized for its excellent geographic position, convenient transportation system, solid industrial foundation, and abundant science and technology resources [
2]. Given its significant role in enhancing economic development in central China and integrating regional coordinated development, the Chinese government implemented several national development strategies in the region, such as the Rise of Central China Plan, the National Resource Conservation and Environment-Friendly Society Construction Comprehensive Reform Pilot Area, the Poyang Lake Ecological Economic Zone, and the development planning of the UA in the middle reaches of the Yangtze River. In recent years, the development of UA has entered a new era with the implementation of the above strategies [
31]. With the acceleration of urbanization and industrialization of UA, the coverage of industrial and commercial area expands and the population rises annually.
An increasingly alarming effect of human activity indicates that the ecosystem of the UA will inevitably face profound pressure, which can hinder the healthy, sustainable, and stable development of the ecosystem and consequently threaten regional and national securities. For example, in certain primary bodies of water in city clusters, such as the Poyang and Dongting Lakes, the area decreased, the quality deteriorated because of eutrophication, and the eutrophication levels were further aggravated by the effects of socioeconomic development [
32,
33]. Atmospheric pollution, particularly PM
2.5 pollution, is also serious in the UA. Shortages of quality-induced water and increased soil pollution have also occurred in the region. Cadmium pollution in rice, which occurred in Dongting, has been the focus of significant attention. Transportation pressure, land degradation, and energy shortages have directly affected and threatened the development efficiency of the UA.
5. Assessment and Analysis of UEH in the UA in the Middle Reaches of the Yangtze River
5.1. Determination of the Classical and Segment Domains of the UA
According to the specific conditions of the urban ecosystem, the societal characteristics of economic development in the UA located in the middle reaches of the Yangtze River, and the State Environmental Protection Agency’s policy for UEH, the UEH standards are usually classified into five grades: morbid (grade I), unhealthy (grade II), sub-healthy (grade III), healthy (grade IV), and excellent healthy (grade V). Given that a common standard on the evaluation index value range of UEH in each grade is currently unavailable, the criterion will be established as classical domain in the process of calculation (
Table 2). These standards are combined with the State Environmental Protection Agency’s policy (the proposed regulations on the construction index of eco-county, eco-city, and eco-province), the average level of the six provincial capital cities (Wuhan, Changsha, Nanchang, Taiyuan, Hefei, and Zhengzhou), and previous academic achievements [
17,
23,
45,
46,
47,
48,
49]. At the same time, this study adopted the questionnaire survey and an expert evaluation method to ensure that the standards on the value range of the UEH evaluation index are scientific and reasonable. According to extension theory, both the minimum value and maximum value of classical domain are respectively the value of left and right of segment domains interval.
Table 2 shows the five grades as ranges of the classical domain, which is the basis for calculating correlation function value and comprehensive correlation degrees.
5.2. Result and Analysis of the UA Ecosystem Health
Based on the criterion in
Table 2 (initial value of each indicator see
Appendix A), Equations (4) and (5), we calculated the correlation degree of the evaluation index of the UA ecosystem health. Given the large number of cities in the UA located in the middle reaches of the Yangtze River, this study uses the city of Wuhan as an example and analyzes the parameters of the computation process. The value of energy consumption per 10,000 Yuan of GDP in Wuhan was 0.760. Using Equations (5) and (10), the index’s correlation degree was calculated as follows:
k1(
v1) = −0.493,
k2(
v1) = −0.240,
k3(
v1) = 0.200,
k4(
v1) = −0.073, and
k5(
v1) = −0.321. The energy consumption per 10,000 Yuan of GDP in Wuhan was classified as grade III. The health grades and attributive degrees of other indicators in Wuhan and other cities can be similarly diagnosed, as shown in
Table 3.
By using Equations (2)–(11), the comprehensive correlation degree of ecosystem health in Wuhan was obtained as follows:
k1(
S) = −0.575,
k2(
S) = −0.530,
k3(
S) = −0.447,
k4(
S) = −0.291, and
k5(
S) = 0.055. Thus, the ecosystem health in Wuhan was classified as grade V. The health grades and attributive degrees of ecosystem health in other cities can be similarly diagnosed. The final results of the ecosystem health assessment for each city in the UA are presented in
Table 4.
The weight, health grade, and attributive degree of each indicator reflect the influence of each index in the ecosystem health status. Per capita gross domestic product (GDP) (I
3), the proportion of science and education expenditures to fiscal expenditures (I
5), the total investment in city maintenance and construction as percent GDP (I
12), the number of public library collections per 100 of the population (I
21), and the number of students enrolled in regular institutions of higher education per 10,000 of the population (I
22), were the first five influencing factors in the UA ecosystem health status based on the weight of each indicator (
Table 1). The five influencing factors were classified under the economic and social subsystems. This implied that the human capital and education, economic development level as well as urban infrastructure have a significant effect on the health states of UA. The limiting factors in different UA cities were based on the correlation degree of the evaluation index of the UA ecosystem health (
Table 3). I
4, I
5, I
12, and I
17 are the limiting factors of most cities in the Wuhan metropolitan areas. The limiting factors of the index system are scattered in various indicators in the Ring of Chang-Zhu-Tan City Clusters and the Poyang Lake Ecological Economic Zone. For example, I
13 is the limiting factor of Changsha, Zhuzhou, and Xiangtan; I
17 is the limiting factor of Changde, Yichun, Shangrao, Fuzhou, and Jian; and I
4 is the limiting factor of Yingtan. Different limiting factors restrict different urban agglomeration ecosystem health. When I
3 and I
12 are the limiting factors of the city simultaneously, the health state of the city will be continuously unwell without the influence of a larger weight factor for an extended period of time. Increasing the investment in urban infrastructure and improving the people’s quality of life are important methods of enhancing the health status of the urban ecosystem.
The results shown in
Table 4 and
Figure 2 reveal the different overall health levels of the 31 UA cities in 2013. Generally speaking, the health status of the UA’s ecosystem was not optimistic. The number of city ecosystems at healthy and excellent healthy levels accounted for only 16.13% of the area. The cities with healthy and excellent healthy levels are scattered throughout the study area in a triangular pattern or, more exactly, like the three vertices of a triangle (see
Figure 2). In combination with the special conditions of the cities in the UA, five basic findings have been summarized as follows:
- (1)
The ecosystem health grades for Wuhan, Changsha, and Nanchang are excellent or converting to excellent health zones, accounting for 9.68% of the total number of cities in the UA. These cities are provincial capital cities with rapid economic development, relatively free social environments, and an abundance of science and technology resources, particularly in comparison with other cities in the UA. The health states of the three cities are good because of the superior urban infrastructure and excellent environmental protection.
- (2)
The ecosystem health grades for Zhuzhou and Xiangtan are healthy or converting to healthy zones, indicating that ecosystem health in Zhuzhou and Xiangtan is improving. Xiangtan and Zhuzhou are two major industrial cities in the country; they are the industrial centers of South China, and are also heavily polluted areas [
50,
51]. The government has spent a considerable amount of money and material resources on environmental pollution control in the past decade, which has significantly influenced the improvement of the health states of Xiangtan and Zhuzhou.
- (3)
The ecosystem health grades for Huangshi, Yichang, Jiujiang, and Xinyu are sub-healthy or converting to sub-healthy zones. Huangshi and Xinyu are resource transformation pilot cities, while Yichang and Jiujiang are tourist cities. All four cities have undergone economic restructuring and upgrading. Natural resource endowments promote economic development and increase environmental pressure.
- (4)
The ecosystem health grades for Ezhou, Huanggang, Xiaogan, Xianning, Xiantao, Qianjiang, Xiangyang, Jingzhou, Jingmen, Yueyang, Yiyang, Changde, Hengyang, Loudi, Jindezhen, Yingtan, Yichun, Pingxiang, Fuzhou, and Jian are unhealthy or converting to unhealthy zones, accounting for 64.52% of the total number of cities in the UA. Rapid economic development in these central cities occurred because of the country’s increasing attention and support for the development of the central city. However, the social infrastructure and protection, and the environmental protection measures for small and medium cities have not matched the pace of economic development.
- (5)
The ecosystem health grades for Tianmen and Shangrao are morbid or converting to morbid zones. Industrial structure, infrastructure, and cultural education significantly affect the health state of the urban ecosystem. For instance, I4, I12, I17, I20, and I22 are the limiting factors of ecosystem health. If this situation continues, it is bound to negatively affect economic development without reasonable industrial structure and supporting infrastructure.
5.3. Discussion
The UA in the middle reaches of the Yangtze River is located in the basin of the Yangtze River Valley, Dongting Lake Valley and Poyang Lake Valley, where water resources occupy an important position. In order to protect the ecological environment, the orientation of the UA is to create the “China Eco-Green Heart”. However, the case study results show that only five out of 31 cities have a healthy and excellent healthy ecosystem. We can diagnose that the health status of the UA’s ecosystem is not optimistic. One of the most effective methods to improve the level of urban ecosystem health is to overcome major limiting factors. First of all, with the development of science, technology and society, the way of maintaining and improving urban ecosystem health should change from the simple environment protection in the past to deep thinking of the historical pattern of urban development and their future. The UA ought to advance their total amount of economic development while transforming the forms of economic development and upgrading of its industrial structure and seeking for a new development model of circular economy. For example, the UA should adopt policies to enhance future ecosystem health by utilizing clean, regenerated energy as much as possible, improve the rate of energy consumption, and reduce the environmental impact on the region. In the second place, more investments are expected to be made by UA for improving urban infrastructure, especially environmental protection facilities. Last and most important, improving the access to quality education, increasing educational input, setting up a regional talent sharing system, and letting talents flow in the UA according to the need for urban ecosystem health development are important.
The regional differences between the ecosystem health levels in these 31 cities are significant. The reason for this originates from an imbalance in economic development and city development policy guidance. Beijing, Tianjin, Shenyang, Taiyuan and Lanzhou experienced eco-environment treatment after pollution and spent a lot of time and wealth to adjust the relationship between the economy and the environment, which has served as a useful reference for other cities. The developed cities, such as Wuhan, Changsha and Nanchang actively explore an effective balance between economic development and environmental protection, with the overall goal of saving resources and developing an environmentally friendly society. Thus, the health levels of these three cities are the best, benefitting from the advantages of superior urban infrastructure and excellent environmental protection. Underdeveloped cities generally have an urgent need to improve the eco-environment instead of focusing on simple economic growth. However, such cities still pay more attention to the rapid economic increases. Obviously, different purposes eventually lead to a contradiction of strategy within city development. It is difficult to shift away from the “grow first, clean up later” approach towards green growth for underdeveloped cities without the support that comes with policy, economy, or industry. Thus, it is also necessary to break free of each departments’ limitations to establish a regional system, and to speed up the integration process to promote coordinated regional development.
6. Conclusions
Research in UEH assessment is driven by both the rapid pace of urbanization and the increasingly deteriorating urban environment it covers [
7]. The extension theory-based methodology was proposed for the evaluation of urban ecosystem health; it circumvents the incompatibility of individual indicators in the evaluation process and avoids the uncertainty of the index weight, thereby generating precise and reasonable the evaluation results.
In the present study, the urban ecosystem health of the UA’s 31 cities in the middle reaches of the Yangtze River were evaluated and compared using the entropy weight extension decision model, in which the health levels of Wuhan, Changsha, and Nanchang were determined superior, whereas majority of the cities were unhealthy or on the verge of being unhealthy, accounting for 64.52% of the total number of cities in the urban agglomeration. Human, economic, and social developments of the UA have a significant effect on health states. However, the power of environmental governance technology is limited. Enhancing the quality of urbanization is an important approach for maintaining a healthy ecosystem and improving urban infrastructure and environmental protection facilities.
Spatial differentiation analysis and dynamic comparisons are important for understanding changes in urban ecosystem health. This study is limited in a time series analysis. Due to the limited data, this work only selected some indexes and data from 2013 for this analysis. Thus, future research will focus on establishing a complete data support system and perfecting environmental monitoring record standards, which will provide more practicable references for urban managers.