Next Article in Journal
Sociodemographic and Work-Related Variables Affecting Knowledge of, Attitudes toward, and Skills in EBNP of Nurses According to an EBPPQ
Next Article in Special Issue
Spatio-Temporal Pattern of Green Agricultural Science and Technology Progress: A Case Study in Yangtze River Delta of China
Previous Article in Journal
The Psychological Impact of the COVID-19 Pandemic on Postsecondary Students: An Analysis of Self-Determination
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
IJERPH
Volume 19
Issue 14
10.3390/ijerph19148549
ijerph-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Valuation of Ecosystem Services for the Sustainable Development of Hani Terraces: A Rice–Fish–Duck Integrated Farming Model

by
Yuan Yuan
,
Gangchun Xu
,
Nannan Shen
,
Zhijuan Nie
,
Hongxia Li
,
Lin Zhang
,
Yunchong Gong
,
Yanhui He
,
Xiaofei Ma
,
Hongyan Zhang
,
Jian Zhu
,
Jinrong Duan
* and
Pao Xu
*
Key Laboratory of Freshwater Fisheries and Germplasm Resources Utilization, Key Laboratory of Integrated Rice-Fish Farming Ecology, Ministry of Agriculture and Rural Affairs, Freshwater Fisheries Research Center, Chinese Academy of Fishery Sciences, Wuxi 214081, China
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Int. J. Environ. Res. Public Health 2022, 19(14), 8549; https://doi.org/10.3390/ijerph19148549
Submission received: 9 May 2022 / Revised: 4 July 2022 / Accepted: 7 July 2022 / Published: 13 July 2022
(This article belongs to the Special Issue Agricultural Green Transformation and Sustainable Development)
Browse Figures
Review Reports Versions Notes

Abstract

:
As a complementary and symbiotic agro-ecological cycle system, a nature-based integrated rice–fish–duck farming ecosystem was developed in the Honghe Hani Rice Terraces. The main research objective was to evaluate the ecosystem services based on case studies of the Hani integrated rice–fish–duck terraced farming system and determine its potential and its importance as an ecological asset. We developed a valuation model to assess the value of the integrated farming system based on the three aspects of provisioning, regulation and maintenance, and cultural services; we selected eight groups and 10 indictors to evaluate the ecosystem services of the integrated ecosystem in Honghe Hani Rice Terraces was 3.316 billion CNY, of which the provisioning service value was 1.76 billion CNY, the regulation and maintenance service value was 1.32 billion CNY, and the cultural services value was 230.85 million CNY. The evaluation will be useful as a theoretical reference for poverty alleviation policy makers in similar poverty-stricken areas, enabling them to better protect and promote this mode of farming and further promote the protection of the natural environment and cultural heritage alongside the sustainable development of natural resources and human well-being.

1. Introduction

The concept of ecosystem services (ES) first attracted the attention of academia in the 1970’s (MIT, 1970; Westman, 1977) [1,2]. In the 1990s, there was a general realization that a systematic approach was required to evaluate the relationship between humans and nature (Schulze, 1993; Daily, 1997) [3,4]. To effectively manage the frequent occurrence of disasters caused by climate change, water shortages, and environmental crises, as well as threats to human survival and sustainable socio-economic development, the United Nations launched the Millennium Ecological Assessment Project in 2000 to promote the awareness and popularity of ecosystem services (Powledge, 2016) [5], taking into account the increasing human demand for ecosystem services (MEA, 2005) [6]. Subsequently, the concept of nature-based solutions was developed, with innovative solutions proposed to protect biodiversity and promote sustainable development, while mitigating and adapting to the impacts of climate change (World Bank, 2008) [7].
Integrated agro-aquaculture farming has become widely used as a sustainable and nature-based solution to food production. Fish farming in rice fields is a traditional Chinese ecological agricultural model, with a history dating back more than 1300 years (Lu and Li, 2006; Liu et al., 2015) [8,9]. This model places rice and fish in the same field, which not only utilizes the mutualistic symbiosis between rice and fish to achieve the purpose of ecological farming, but can also continuously produce food crops and freshwater products (Stankus and Halwart, 2017) [10] and enhances biodiversity conservation (Frei and Becker, 2005) [11]. The service of the integrated agro-aquaculture system can be divided into three categories. The first is the provisioning service, which refers to the conditions of the natural environment and the utility it provides for human survival through the combination of ecological processes in rice fields and human activities. The second is the ecological service, which includes actions such as maintaining and improving the atmospheric regulation of the natural environment, soil and water conservation, and purifying the environment (Agus et al., 2006) [12]. The third is the social service, which includes actions such as promoting rural economic development and rural area vitality, cultural protection, social security, and food security (Costanza R, 2017) [13].
The Honghe Hani Rice Terraces in Yunnan are famous for their widely distributed rice terrace landscape, especially the well-preserved traditional agricultural system. The terraces have also played an important wetland function in regulating climate, preserving water and soil, and maintaining biodiversity (Tsuruta et al., 2011) [14]. In 2010, the Yunnan Honghe Hani rice terrace system was designated by the United Nations Food and Agriculture Organization as a Globally Important Agricultural Cultural Heritage (GIAHS) (Yuan et al., 2014) [15]. In 2013, it was selected in the first batch of China’s important agricultural cultural heritage (China-NIAHS) sites by the Ministry of Agriculture, and it was successfully included in the United Nations Educational, Scientific and Cultural Organization (UNESCO) World Cultural Heritage List in the same year (Chan et al., 2016) [16]. However, the economic, scientific and aesthetic values of the Hani terraces were not fully realized at the time due to a lack of systematic, effective protection and management. The profits generated by farming the terraces were low compared with other income-generating activities, and most of the local young and mid-aged labor force chose to work elsewhere while a few others took up dry farming, which was relatively more profitable. As a result, many paddies were abandoned and became wasteland, bringing devastating changes to the original appearance, cultivation traditions, and ecosystems of the Hani terraced fields. To maintain the unique ecosystem of the Hani terraces, which cover a complex range of ecosystems incorporating forests, rice fields, water bodies, and villages, since 2015 the Hani local government has encouraged local farmers to carry out integrated rice–fish–duck faming over the whole Hani terraced area.
Academic studies of ecosystem services have mainly focused on four aspects. (1) Research on the concept (Costanza et al., 1997, 2014, 2017) [13,17,18], connotation (Daily, 1997) [4], and classification system of ecosystem services (Fisher and Turner, 2008; Reid and Mooney, 2016) [19,20], which has attempted to quantify and systematize the scientific theory of ecosystem service value. (2) Research on the changing mechanisms of ecosystem services and their interaction with biodiversity (Wang et al., 2013; Pascual et al., 2017; Wood et al., 2018) [21,22,23]. (3) Research on the evaluation techniques used to value ecosystem services (He et al., 2018; Hardaker et al., 2020) [24,25]. (4) The use of different methods to evaluate a single ecosystem or single service in different regions (Richards and Tunçer, 2018; Schirpke et al., 2018; Taffarello et al., 2020; Castonguay et al., 2014, 2016; Burkhard et al., 2015; Horgan et al., 2016, 2017; Dang et al., 2018a, 2018b, 2019; Gu et al., 2012; Liechti and Rodewald., 2020 and Jiao et al., 2019; Jiao et al., 2014 focus on Hani terrace) [26,27,28,29,30,31,32,33,34,35,36,37,38,39,40]. Ecosystem service value evaluations have evolved from a single quantitative calculation to more dynamic, mechanistic, and application-based comprehensive research. These previous studies provide a theoretical basis for the present analysis. Most previous studies have focused on the protection and development of cultural heritage, and only a few studies have attempted to evaluate the ecosystem service value of the integrated agro-aquaculture ecosystems in the Honghe Hani Rice Terraces.
As a complementary and symbiotic agro-ecological circular system, it aims to ensure improvements in the output of rice, and the quality of rice, fishery and poultry products to increase output and add value to terraced fields, and to unify economic, social, and ecological benefits. Although the integrated rice–fish–duck farming practiced in the Hani terraces has these functional values, there is no perfect system to express these values in monetary terms, which affects the choice of land use methods. Against this background, the establishment of an evaluation system for the Hani terraces could enable its value to be realized and form the basis for terraced field resource planning. An evaluation of the ecosystem services provided by the integrated rice–fish–duck ecosystem will also provide a research basis for the establishment of an ecological compensation mechanism, which can protect the inheritance and development of the world agricultural cultural heritage, realize and improve human well-being, and create a better natural environment to meet ecological needs, providing new ideas for the sustainable development of people and nature.
This study considered integrated rice–fish–duck farming in the Honghe Hani Rice Terraces as a case study. It adopted the market price, replacement costs, and equivalence factor methods to establish the value of provisioning services, gas regulation, climate regulation, air purification, pest control, maintaining biodiversity, water regulation, soil conservation, soil organic accumulation, and cultural services, i.e., a total of 10 service value analysis indicators. A driving force, pressure, state, impact, and response (DPSIR) analysis model was developed to analyze the driving factors and responses of the Hani terraces rice–fish–duck ecosystem more comprehensively and systematically. The potential future social and economic developments were also considered, as well as their contribution to the achievement of sustainable development and nature-based solutions for terraced fields in other plateau areas of the world.

2. Materials and Methods

2.1. Study Area

2.1.1. Geographic Location

Honghe Hani and Yi Autonomous Prefecture is located in the southeast of Yunnan Province and is traversed in the east-to-west direction by the Tropic of Cancer. The prefecture has a total area of 32,931 km2, with four county-level cities, six counties, and three autonomous counties under its jurisdiction (Shu et al., 2021) [41]. The Hani terraces have a history dating back more than 1300 years (Bai, 2013) [42] and are located in the south of Honghe Hani and Yi Autonomous Prefecture (22°26′–23°26′ N, 101°48′–103°38′ E). They include the four counties of Honghe, Yuanyang, Lvchun, and Jinping (Figure 1), with a total area of about 56,666 hm2. This area is located to the south of the Tropic of Cancer, with an altitude of 88 to 3053 m. It has a subtropical plateau humid monsoon climate, with distinct dry and wet seasons, during which foggy and rainy weather can be experienced. The region has an annual precipitation of 1344 mm and annual sunshine of more than 2000 h (Liu et al., 2010) [43].

2.1.2. Unique Topography

The Hani people have created a spectacular terraced civilization by exploiting the special geographical terrain through the concept of “as high as the mountains are, as high as the waters”. This has resulted in the development of a “forest-village-terrace field-water system” agricultural ecosystem (Figure 2), which is a composite agricultural ecosystem with an intelligent structure, complete functionality, diverse values, and strong self-regulating ability. Forests grow on the mountain tops and villages are built under the forests. Water flows from the mountain tops and is slowed by the forests, a process that is conducive to irrigation and water conservation, with the result that mountain springs and streams have water all year round. A water supply for humans, animals, and terrace irrigation is guaranteed, and the local biodiversity is preserved (Liu et al., 2014) [44]. The vertical character of the Hani terraces is an important reason for the formation of a benign ecological circular system. The construction of the terraces completely follows the contour line, which reduces the amount of earthwork used and prevents soil erosion. This structure realizes a high degree of integration between man and nature and reflects the characteristics of ecological agriculture with an intelligent structure, complete functionality, diverse values, and strong self-regulating ability (Min and Tian, 2015) [45].

2.1.3. Local Method of Rice–Fish–Duck Integrated Faming

The light, climate, water source, water quality, soil, water temperature, and humidity (hardness) in the Hani terraces provide good conditions for the implementation of integrated rice–fish–duck farming. According to a survey of the Bureau of Statistics, there are 17,640 hm2 of terraced fields in Honghe Prefecture, including 13,687 hm2 of red rice planting area (with an output of 73,600 tons), and 13,373 hm2 of rice–fish–duck integrated farming projects. The typical circle-shaped sump in the rice field is 0.6–1.0 m deep, and 30 cm above the soil level of the paddy field (Figure 3).

2.2. Data Collection

Three sources of data were used in this study. First, through face-to-face questionnaire-based interviews conducted from September to December 2021, we obtained the yields and prices of rice, fish, and duck products from 100 farmers using a random sampling method. In the same period, we conducted a field survey to obtain the organic matter, total nitrogen, total phosphorus, and total potassium content in the soil tillage layer. Second, some monitoring data, such as the number of the growth periods of rice, the number of days of standing water for rice, the number of hot days in summer, the price of agricultural water and coal, the number of tourists, and the tourism revenue were obtained directly from the relevant authorities and official websites. Third, the ecological parameters of the rice–fish–duck ecosystem (water evaporation, soil permeability, and average sulfur dioxide (SO2), oxides of nitrogen (NOx), hydrogen fluoride (HF), and dust concentrations absorbed by the terraces were obtained from the published literature. The questionnaire (supplementary material) requested basic information regarding the farming households, including socioeconomic characteristics, asset ownership, education levels, the area of the integrated rice–fish–duck faming system, the input cost of production materials and sales, and the understanding of terrace services. Where the required data could not be obtained through field studies, the information was extracted from the published literature. The relevant data for the single-rice system was obtained from historical data provided by local government departments. All required data were shown in Table 1.

2.3. Construction of the Valuation Model

The Hani terrace integrated rice–fish–duck farming ecosystem produces fish and duck products alongside rice and has the functions of maintaining water and soil quality, regulating the climate, maintaining the ecological value of ecosystem biodiversity, maintaining social harmony and stability, and intelligently integrating nature (Zhan and Jin, 2015) [46]. There is also scientific value to the ecosystem, and the aesthetic value of the landscape is considerable (Jiao et al., 2012) [47]. We developed a valuation model to assess the integrated rice–fish–duck faming system based on the Common International Classification of Ecosystem Services (CICES) V5.1 (2018), which was designed to help measure, account for, and assess ecosystem services and is accepted internationally. We selected eight groups and 14 indictors from the provisioning, regulation and maintenance, and cultural service aspects, to evaluate the ecosystem services of the integrated rice–fish–duck system in the Honghe Hani Rice Terraces depending on data availability and method feasibility (Table 2).

2.4. The DPSIR Model of the Integrated Rice–Fish–Duck Farming Ecosystem

Model localization is an important link in the quantification-balance-decision approach when applying ES models. A DPSIR model (Weber, 2007) [48] was developed to effectively integrate the social, economic, and environmental systems of the Hani terraces (Hou et al., 2014) [49]. A DPSIR model can comprehensively and systematically analyze the interacting processes in human–environmental systems (Feld et al., 2010) [50]. Because DPSIR models can explain the cause–effect relationships between the different sectors of economic, ecological, and social systems (Kristensen, 2004) [51], they have been widely used to improve the application of ecosystem services and provide more comprehensive and systematic results. In this study, we used a DPSIR model (Svarstad et al., 2008) [52] to identify the driving factors and responses of the Hani terraces rice–fish–duck ecosystem.
The meanings of the terms used in the DPSIR model are as follows. Driving force represents the existing reasons for the development of the Hani terraces ecosystems. Pressure represents the direct impact of any existing problems on the development of the Hani terraces. State represents all the factors affecting the development of the Hani terraces. Impact represents the impact of the state on the natural environment and social economy during the integration of rice–fish–duck farming. Response represents the countermeasures taken by different stakeholders to mitigate the drivers of change.

2.5. Estimation of the Ecosystem Service Values of the Integrated Rice–Fish–Duck Farming Ecosystem

In the following ecosystem service value estimates, the market value and replacement cost methods for determining ecological value were used to measure the values of gas regulation, water regulation, and other aspects. Gas regulation is comprised of carbon fixation, oxygen release, and greenhouse gas emissions, and its service value was estimated by the afforestation cost method and global warming potential (GWP) (Xiao et al., 2019) [53]. The equivalence factor method was used to estimate the value of maintaining biodiversity (Xie et al., 2015) [54]. The reference parameters were converted to 2020 prices according to the price index published by the National Bureau of Statistics (https://www.ceicdata.com/zh-hans/china/agricultural-production-price-index, accessed on 1 December 2021) because price fluctuations occurred during the long research period. Table 3 shows the 10 service values and the corresponding formulas used for their calculation, with reference to previous studies (Zheng et al., 2018; Jiang et al., 2016) [55,56], together with an explanation of the parameters.

3. Results

3.1. Provisioning Service Value of the Hani Terrace Ecosystem

The provisioning service value of providing primary products, such as rice, fish, duck, and duck eggs, was estimated by the market value method. The field survey determined that the rice varieties were mainly high-yield, high-quality, disease-resistant, cold-resistant, and adaptable, such as Hongyang No. 2 and No. 3. The fish species were mainly loach and common carp. The ducklings were local species, which can generate a considerable profit. The average yield of red rice was 5370 kg/hm2 and the price was 6 CNY/kg, giving a total economic value of rice of 430.89 million CNY. The average output of fish (common carp) products was 750 kg/hm2 and the price was 50 CNY/kg, these fish being preferred by consumers due to their ecologically farmed credentials, giving a total value provided by fish products of 501.5 million CNY. Typically, there were 150 drakes and 225 female ducks/hm2, laying 21,600 eggs/hm2. The price of each duck egg was 2 CNY and the price of each duck was 50 CNY. The total value of duck products was therefore 828.48 million CNY. The rice, fish and duck are all produced from the GIAHS areas, and consumers consider this a trustworthy source. The average provisioning service value was 131,670 CNY/hm2, and the total provisioning service value was 1.76 billion CNY.

3.2. Regulation and Maintenance Service Value of the Hani Terrace Ecosystem

3.2.1. Gas Regulation

The total value of gas regulation in the evaluation area was the sum of the total value of CO2 fixation, O2 release, and the value of greenhouse gas emissions. The rice yield in the evaluation area was 73,600 t. We adjusted the afforestation cost to 327.32 CNY/t C according to the forestry price index released by the National Bureau of Statistics in 2020 based on a previous study (Dahowski et al., 2009) [63]. Following the forestry industry standard of the People’s Republic of China, we adjusted the cost of industrial oxygen to 1072.21 CNY/t O2, according to the price index in 2020 based on a previous study (Liu et al., 2021) [64]. The CO2 fixation service value was 5.35 million CNY. The O2 release service value was 46.95 million CNY. The total value of CO2 fixation and O2 release was 52.30 million CNY.
The greenhouse gases emitted in the evaluation area mainly comprise CH4 and CO2. The methane (CH4) and CO2 emissions in the rice field ecosystem were converted into total CO2 emissions.
The evaluation area was 13373.33 hm2, and the rice growing period in the evaluation area was generally 180 days. The average emission fluxes of CH4, rice CO2, and soil CO2 from rice fields in Yunnan Province were 0.334, 272.04, and 102.35 kg/(hm2/d), respectively. The greenhouse effect produced by 1 kg of CH4 was equivalent to the greenhouse effect produced by 24.5 kg of CO2. Total CH4 emissions were 585,315 kg, and total CO2 emissions were 788,577,460 kg, so the CH4 and CO2 emissions in the rice field ecosystem were equivalent to a total of 802,917.69 t of CO2 emissions. The total value of greenhouse gas emissions was 71.67 million CNY. The value of greenhouse gas emissions was greater than the combined value of CO2 fixation and O2 release, so the total value of gas regulation was −19.36 million CNY.

3.2.2. Climate Regulation

The climate regulation of the Hani terraces field ecosystem was mainly reflected in the degree of cooling effect on the surrounding areas. Honghe has an average of 60 hot summer days. Its local climate is arid with abundant sunshine, and the average daily water evaporation in terraced fields is 3.83 mm/day. The total cooling effect was therefore 229.8 mm.
The quantity of heat consumed when water evaporated from terraced fields was equivalent to 140.50 tons of standard coal per year. The value of climate control, calculated using the standard coal price based on the coal price in 2020 (600 RMB/t), was 1127 billion CNY/hm2/year.

3.2.3. Air Purification

The average SO2, NOx, HF, and dust concentrations absorbed by terraced fields were 45, 33.3, 0.57, and 33,200 kg/hm2/year, respectively (Tang, 2019) [65]. According to the forestry industry standards of the People’s Republic of China, the cost of SO2 removal is 1.44 RMB/kg, the cost of NOx removal is 0.76 RMB/kg, the cost of HF removal is 0.83 RMB/kg, and the cost of dust removal is 0.18 RMB/kg. Therefore, the air purification value of the Hani terraces was 6066.36 yuan/hm2 (2004). Based on the price index of the National Bureau of Statistics, this value was adjusted to 8968.61 CNY/hm2 (2020). The total air purification value of the Hani terraces was therefore 119.94 million CNY.

3.2.4. Pest Control

According to our survey data and the results of Li F et al. (2021) [66], the integrated rice–fish–duck system in the Hani terraces could reduce pesticide costs by approximately 50%. The pesticide cost under the rice monoculture system was approximately 750 RMB/hm2/year in 2020. We used the replacement price method to calculate the pest control value of the integrated rice–fish–duck in the Hani terraces, and arrived at a figure of 375.00 RMB/hm2/year (Wang et al., 2020) [67]. The total pest control value was therefore 5015 million CNY.

3.2.5. Maintaining Biodiversity

The equivalence factor for maintaining biodiversity in paddy fields was 0.21. Based on the weighted average income from wheat, maize, and rice, the value of biodiversity in each unit was 628 CNY/hm2. However, we adjusted this price to 911.98 RMB/hm2 (Liu et al., 2021) [64] for 2020 based on the price index. The value of maintaining biodiversity was therefore 12.20 million CNY.

3.2.6. Water Regulation

The market price of agricultural water was 0.2 CNY/m3, and the number of days of standing water during the growth period of rice was 160 d. The water regulation value was therefore 3.09 million CNY.

3.2.7. Soil Conservation

According to our investigation of the Hani terraces, the organic matter, total nitrogen, total phosphorus, and total potassium contents in the soil tillage layer were 44.61, 1.32, 0.43, and 14.9 g/kg, respectively. The price of fertilizer was 2.75 CNY/kg, according to our field survey. The soil thickness in the tillage layer was 0.2 m and the soil bulk density was 1.09 g/cm3. The soil conservation value was therefore 491,140 CNY.

3.2.8. Soil Organic Matter Accumulation

Because of the lack of available rice and straw biomass and carbon content data for the Hani terraces, data was extracted from a study in Jingzhou City by Jiang (2016) [56]. Straw biomass was estimated to be 1.24 × 104 kg/hm2, the straw carbon content was estimated to be 41.4%, the rice root biomass was estimated to be 0.21 × 104 kg/hm2, and the root carbon content was estimated to be 34.6%. Therefore, the input of organic carbon due to straw and rice roots was 4198 kg/hm2.
For the output of soil organic matter (OSOC), we also extracted data from Jiang (2016) [56]. The amount of CO2 released from the terraced fields was 2123.63 kg/hm2, and the annual CH4 emissions were 29.64 kg/hm2. The amount of organic matter released from the terraced fields was 595.61 kg/hm2 and the net soil organic matter accumulation was 3602.09 kg/hm2. The market price of organic fertilizer calculated by the amount of pure carbon was 1.53 RMB/kg C based on the 2020 price index. Finally, the value of soil organic matter accumulation was determined to be 75.63 million CNY/year.

3.3. Cultural Services

Because it is difficult to take into account the daily travel expenses incurred when visiting the integrated rice–fish–duck farming ecosystem, the evaluation of the cultural value referred to the income generated from tourists participating in the rice-fish cultural festival in the Yuanyang and Samaba terraces. From the tourism data in the Honghe Hani and Yi Autonomous Prefecture Yearbook, it was calculated that the unit area value of Hani terrace landscape tourism in Yunnan was 17,262 CNY/hm2, and the value of cultural services was 230.85 million CNY.

3.4. Analysis of DPSIR Model of the Hani Rice–Fish–Duck Integrated Farming

Driving force of our study is the low production levels and benefits of the terraces. Because only one crop of red rice is planted every year, an annual yield of 5100 kg/hm2 generates a net profit of less than 6000 CNY/hm2 for a family, and therefore poverty remains a serious issue. Due to the specific geography and impossibility of fully mechanizing farming in the region, it is very difficult for people to farm on terraces, and considerable manpower is required for all farming tasks. Pressure facing Hani terrace development is that infrastructure construction lags behind (Figure 4), which led to the poor condition of producing and living. As a result, most of the young and strong labor force choose to work elsewhere, while those left behind to continue agricultural production in the village are mainly elders and less educated women. The Heritage protection has been affected. State represents all the factors affecting the development of the Hani terraces. Because of the driving force and pressure components, the terraces cannot be effectively managed and may even be abandoned. Some farmers have decided to switch directly to other high value dry-farmed plants, such as sugar cane, vegetables, and herbs that do not require constant watering. Therefore, conducting integration of rice–fish–duck farming was one of the impacts. Because this farming mode can potentially result in high economic returns, with good ecological and social benefits, it can ensure heritage protection, the sustainable development of the Hani terraces, and food security together with human well-being. Response represents the countermeasures taken by different stakeholders to mitigate the drivers of change, including local government development of sustainable integrated rice–fish–duck faming and provision of policy support, creating enterprises to develop a rice–fish–duck value chain, and helping research institutes to study the species involved and build collaborative innovation platforms in response to the various factors involved.

3.5. Comparison of ES Value of Rice Monoculture Systems

Table 4 shows that the economic value of the rice–fish–duck farming ecosystem was the largest factor, followed by the ecological value, and the social value, which was the smallest. The proportional values of provisioning services, gas regulation, climate regulation, air purification, pest control, biodiversity maintenance, water regulation, soil conservation, soil organic matter accumulation, and cultural services were 53.10%, −0.58%, 34.00%, 3.62%, 0.15%, 0.37%, 0.09%, 0.02%, 2.28%, and 6.96%, respectively.
The biggest differences between rice monoculture and integrated rice–fish–duck farming were in the value of provisioning services, which increased by 208.66% due to the added value of fish and ducks, and their provision of animal protein to local people. Moreover, integrated rice–fish–duck farming increased the value of cultural services, especially in terms of tourism development, by 135.82%. Finally, the value of gas regulation increased by 54.41% due to integrated rice–fish–duck farming, which reduced greenhouse gas emissions by 14.70%. The integrated rice–fish–duck farming ecosystem could be considered an example of climate adaptation, which was consistent with the conclusions of previous studies. After the analysis, it was found that the net income of the integrated rice–fish–duck system was significantly higher than that of the rice monoculture system. The integrated farming system had higher comprehensive benefits, including increased income and indirect environmental protection value. Compared with the rice monoculture system, the construction of integrated farming systems in different ecological niches accelerates the absorption and metabolism of various substances in the terraces (Nie et al., 2020) [68]. Table 4 shows the values of each part of the system, which were obtained by performing conversions based on similar formulas.

4. Discussion

4.1. Comparison with the Ecosystem Service Value of Other Wetlands

One unit of terraced area equaled 247,971 CNY/hm2, while Zheng et al. (2018) [55] reported a value of 227,500 CNY/hm2 for a rice paddy in Yuanyang County. The value of the Honghe Hani Rice Terraces was slightly less than reported by Liu et al. (2020) [57], who reported a value of 255,529 CNY/hm2 for a rice-fish co-culture system in Ruyuan County, China. This was largely due to the differences in water regulation. Because Ruyuan County is a hilly area, the water storage and flood control capacity of the rice-fishing system was more obvious. The reported value of the plain area of the Sanyang wetland was 55,332 CNY/hm2 (Tong et al., 2007) [69]. The annual ecosystem value of the Ghodaghodi wetland in Nepal was estimated to be 0.67 million US dollars by Aryal et al. (2021) [70], but this study only considered wetland goods, tourism, irrigation, carbon sequestration, existence and bequest, and religious and cultural values. Zuze (2013) [71] found that the contribution of a wetland to the surrounding communities had an estimated annual value of 17.2 million USD in Malawi, which was also due to different value aspects, with the non-use value not estimated.

4.2. The Importance of the Ecosystem Service Values in the Hani Terraces

Among the different service values, the total production values of rice, fish, and especially duck products were the highest, accounting for nearly half (47%) of the total economic value, and could improve a farmer’s livelihood greatly. Sasmal et al. (2020) [72] found that Khaki Campbell ducks performed well in integrated rearing systems and laid 17.64% more eggs than the local duck breed (Pati duck). The provisioning service value therefore made the greatest contribution to the overall ecosystem service value. This was the largest difference between the present study and other published studies, such as Dai et al. (2022) [73] who found that the impacts of ecological factors on the ES supply were greater than the socioeconomic factors.
Climate regulation was the second largest (34%) contributor to the overall value, with an obvious cooling effect on terraced ecosystems, which has positive effects on the Hani terraces. This result was similar to previous studies of the Yuanyang Terraces, where climate regulation accounted for 35.2% of the overall ecosystem value (Zheng et al., 2018) [55]. However, Dai et al. (2021) [74], Liu et al. (2020) [57] and Liu et al. (2021) [64] found that climate regulation had a greater effect compared with the other service values. The absorption of heat and regulation of temperature play a role in alleviating the heat island effect, and the Hani-integrated farming system had a significant cooling effect in summer during periods of high temperature, consistent with the findings of Yoshida (2001) [75].
As a world cultural heritage site, the Hani terraces have beautiful scenery and large cultural service value, which accounted for the third part of the ecosystem value contribution. The Hani terraces have an important landscape aesthetic value (Wang and Marafa, 2021) [76]. The Hani people have interesting customs, production methods, and landscape design, and the layout of the terraces and villages is designed in sympathy with ecological and ethical values, creating a spectacular landscape and cultural tourism resource. The “Terraces on the Cloud·Dream of Red River” is becoming an increasingly popular brand. Through careful planning, based on the protection of this famous world cultural heritage, a sustainable tourist economy can be developed, highlighting the natural geographical conditions and local traditional culture, a fact also recognized by Tekken et al. (2017) [77] and Tilliger et al. (2015) [78].
The Hani terraces also provide an artificial wetland which improves the environment, retains water, reduces pesticide use, and maintains soil and biodiversity (McLaughlin and Cohe, 2013) [79]. The terraced field ecosystem acts to purify the air of dust, SO2, HF and NOx, which helps to improve air quality in the surrounding areas. The service value of environmental purification of the terrace ecosystem in the evaluation area was mainly a consequence of this air purification (3.62%). The Hani terraces contain a large volume of water, due to their unique water distribution pattern. The terraced wetlands at higher altitudes store water year-round, with a water depth of about 0.25–0.3 m. The terraces can maintain a certain volume of water throughout the year, and their soils have strong water retention and permeability properties, which play an important role in water regulation, as also demonstrated by Bai et al., 2016 [62]. Repair and reconstruction of the terraces and ditches has greatly increased their water storage capacity and conserved groundwater resources. Through predation, fish reduce the numbers and occurrence of pests and limit the damage they cause (Lansing et al., 2011) [80], so achieving an ecologically balanced farming practice is important. In the integrated rice–fish–duck farming system, microorganisms in the rice exchange nutrients with the soil (Zhang et al., 2018) [81] and the activities of aquatic animals and ducks help to loosen the soil, enabling more oxygen to penetrate and so promote the growth of rice. In addition, fish manure provides nutrients to fertilize the crop (Nayak et al., 2018) [82]. All of this can improve the soil structure. Fish and duck farming on the terraces has reduced the degree of soil compaction, increased soil bulk density and porosity, and improved soil nutrient and organic matter content. Integrated rice–fish–duck farming plays an important role in maintaining ecological balance, including support for more than 200 paddy weed species, a large number of invertebrates, and cranes and ibises (Zhang et al., 2016) [83]. Rice field ecosystems can enrich biodiversity, and further research on the biodiversity of these ecosystems is required.
Finally, we should point out that the value of O2 released by the terrace ecosystem in the evaluation area was greater than that of CO2 fixed, which is consistent with the study of Zheng et al., 2018, who focused on the Yuanyang terraces. However, the negative gas regulation value generated by the terrace field ecosystem needs further attention in order to make future changes to minimize its potential for harm.

4.3. Benefit Analysis of the Integrated Rice–Fish–Duck Ecosystem in the Hani Terraces

The integrated rice–fish–duck farming ecosystem in the Hani terraces not only protects the terraces but has also increased the income of farmers. Due to its unique cultural and geographical environment, as well as the ecological, replicable, and popular farming methods, the integrated rice–fish–duck farming ecosystem in the Hani terraces has a profound impact on the local economy, ecology, and society. The successful practice of integrated rice–fish–duck farming in the Hani terraces is a useful model for the sustainable development of agriculture and rural economies in other areas with an underdeveloped economy, fragile ecology, and rich culture (Liu et al., 2017; Bene et al., 2016) [84,85]. The purpose of this development was the same as in the Yangtze and Yellow River Basins (Fang et al., 2021) [86], where ecological protection and sustainable economic development were the main demands.
In terms of economic benefits, 13,373.33 hm2 of the rice–fish–duck ecosystem was effectively utilized as terraced field resources, improving the output rate of the Hani terraces, and increasing the economic income of farmers. After deducting the expenditures on seeds, labor, chemical fertilizers (manures), and feeding materials, an average profit of RMB 35,850/hm2 was achieved. The fundamental strategy for the protection of the Hani terraces is to increase farmers’ income. The economic returns for farmers continuing traditional agro-aquaculture production methods could be greatly increased and should encourage farmers to adopt the integrated rice–fish–duck farming system. The results were consistent with the study of Xu et al., 2021 [87], who found that conversion to rice–crayfish co-culture increased the net ES value by 145.3–176.9%.
In terms of the social benefits, the Hani terraces provide employment for fishermen, and their incomes have increased under the integrated rice–fish–duck ecosystem. The promotion and application of integrated rice–fish–duck continuous cropping in the Hani terraces has provided more employment for Hani women, who have received special training in farming technologies. Moreover, due to the development of tourism, there are more jobs for women and their family status has improved due to their increased income. This has contributed to family harmony, promoted better and faster development in remote areas, and assisted revitalization projects in rural areas. The integrated rice–fish–duck ecosystem will also ensure food security, promote the increase of grain production and farming incomes, protect the world cultural heritage site, and promote the development of tourism, these conclusions being consistent with those of previous studies (e.g., Sasmal et al., 2020) [71]. Honghe is rapidly becoming the center of tourism in Yunnan, driving the development of the local economy and increasing the income of local people (Zhang et al., 2018) [80].
In terms of ecological benefits, rice fields provide fish and ducks with an abundance of food sources and habitats. Fish and ducks feed on plankton, benthic organisms, aquatic insects, and microorganisms (Liu et al., 2021) [88] in the rice fields, thereby reducing the amount of feed required and saving energy. The swimming, feeding, and waste excretion of fish and ducks contributes to the weeding, fertilizing, and cultivation of rice, with the three processes being mutually beneficial and symbiotic. Organic fertilizers have been applied to inhibit the growth of weeds and loosen the soil structure, reducing the usage of chemical fertilizers and pesticides, and thereby reducing environmental pollution. This has resulted in the formation of a virtuous ecological cycle, with very significant ecological benefits.
Through the development of integrated rice–fish–duck farming, local people will obtain the opportunity to lead a meaningful life, with the efficient and fair use of resources and the environment. Measures need to be taken to effectively maintain the quality and quantity of environmental resources to achieve an equitable distribution, thereby contributing to sustainable well-being goals. The integrated rice–fish–duck farming ecosystem in terraced fields has encouraged farmers to change their production methods, inherit traditional agricultural systems, maintain the balance of the natural environment and social stability, and promote the sustainable development of an ecologically based socio-economic system (Liu et al., 2019) [88].
As more data becomes available, we are planning similar studies to measure and compare the ecosystem service values between high and low altitude environments.

5. Conclusions

In this study, a comprehensive ecological value assessment framework was applied to identify and evaluate the integrated rice–fish–duck farming ecosystem, in which the CICES classification standard played an important role. We determined the value of the integrated rice–fish–duck ecosystem of the Hani terraces from 10 different aspects. Some evaluations could not be obtained, and therefore, the ecosystem service values of the Hani terraces are likely to be higher in terms of actual production activities. The general service value of the integrated rice–fish–duck farming ecosystem in the study area was 3.316 billion CNY (equivalent to 510.09 million USD/hm2/year), of which the provisioning service value was 1.76 billion CNY (equivalent to 270.90 million USD/hm2/year), the regulation and maintenance service value was 1.32 billion CNY (equivalent to 203.76 million USD/hm2/year), and the cultural service value was 230.85 million CNY (equivalent to 3.55 million USD/hm2/year). The positive value of the ecosystem services of the Hani terraces in 2020 was about 513.07 million USD /hm2/year. Among all the positive assessed values, provisioning and temperature regulation were the largest, accounting for 53.11% and 34% of the total, respectively. The other values were ranked in descending order of culture (6.96%) > air purification (3.62%) > soil organic matter accumulation (2.28%) > maintaining biodiversity (0.37%) > pest control (0.15%) > water regulation (0.09%). The value of gas regulation was negative and accounted for −0.58% of the total ecosystem service value of the Hani terraces.
The sustainability of human society is based on the sustainability of ecosystems and their services. Through this investigation of the ecosystem values and market-oriented value of the rice–fish–duck system in the Hani terraces, it was calculated that the integration of traditional ecological models and modern agro-ecological techniques will have a huge impact. By implementing integrated rice–fish–duck farming, production, nutrition, income, environmental conditions, and livelihoods can be improved. The results of this study will further promote the protection of the regional ecological environment, the inheritance of cultural heritage, and the sustainable development of natural resources. This study will also improve public awareness of environmental protection and highlight the contribution of nature to the successful operation of agricultural systems, enabling the value of ecosystems to be correctly evaluated. The findings of the study will enable rapid and lasting progress to be made towards sustainable development for people and the environment. It is also an important reference for other countries and regions of the world with terraced fields, enabling them to achieve better production, nutrition, and livelihoods. Future research requires long-term observations and simulation experiments, and the field measurement of relevant data needs to further understand the internal mechanisms and evolution of the ecological services in terraced areas. This will promote the application of ecosystem service evaluations in policy and decision making.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ijerph19148549/s1, Questionnaire for farmer.

Author Contributions

Conceptualization, Y.Y., G.X. and P.X.; methodology, Y.Y., G.X., J.Z. and J.D.; software, N.S., Y.G. and X.M.; validation, P.X., J.D. and J.Z.; formal analysis, Y.Y. and G.X.; investigation, Z.N., H.L. and L.Z.; resources, Y.H. and H.Z.; data curation, N.S. and Y.G.; writing—original draft preparation, Y.Y. and G.X.; writing—review and editing, Y.Y. and G.X.; visualization, Y.G. and X.M.; supervision, P.X.; project administration, J.D.; funding acquisition, P.X. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by Central Public-interest Scientific Institution Basal Research Fund CAFS (2021JBFM10 and 2020TD60).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

In the results section, data supporting reported results can be found.

Acknowledgments

We are sincerely grateful to the government officials of Honghe Government and the local farmers in the Hani Rice Terraces who helped us with our field study. This research was supported by Central Public-interest Scientific Institution Basal Research Fund CAFS (2021JBFM10 and 2020TD60).

Conflicts of Interest

The authors declare no conflict of interest. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. The authors declare the following financial interests/personal relationships which may be considered as potential competing interests. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. MIT Massachusetts. Study of Critical Environmental Problems. In Mans Impacts on the Global Environment; Springer: Berlin/Heidelberg, Germany, 1970. [Google Scholar]
  2. Westman, W.E. How Much Are Nature’s Services Worth? Measuring the social benefits of ecosystem functioning is both controversial and illuminating. Science 1977, 197, 960–964. [Google Scholar] [CrossRef] [PubMed]
  3. Schulze, E.D.; Mooney, H. Biodiversity and Ecosystem Function; Springer: Berlin/Heidelberg, Germany, 1993. [Google Scholar]
  4. Daily, C.G. Nature’s services: Societal dependence on natural ecosystems. Pac. Conserv. Biol. 1997, 6, 220–221. [Google Scholar]
  5. Powledge, F. The millennium assessment. BioScience 2006, 56, 880–886. [Google Scholar] [CrossRef] [Green Version]
  6. Millennium Ecosystem Assessment (MEA). Ecosystems and Human Well-Being; Island Press: Washington, DC, USA, 2005. [Google Scholar]
  7. World Bank. Biodiversity, Climate change and Adaptation: Nature-Based Solutions from the World Bank Portfolio; World Bank Publications: Washington, DC, USA, 2008. [Google Scholar]
  8. Lu, J.; Li, X. Review of rice-fish-farming systems in China-One of the Globally Important Ingenious Agricultural Heritage Systems (GIAHS). Aquaculture 2006, 260, 106–113. [Google Scholar] [CrossRef]
  9. Liu, Y.; Liao, L.W.; Long, H.L.; Qin, J.X. Effects of land use transitions on ecosystem services value: A case study of Hunan province. Geogr. Res. 2015, 34, 691–700. (In Chinese) [Google Scholar]
  10. Stankus, A.; Halwart, M. Rice-Fish Culture: An Integrated Approach to Efficient Resource; FAO: Rome, Italy, 2017; Volume 56, p. 14. [Google Scholar]
  11. Frei, M.; Becker, K. A greenhouse experiment on growth and yield effects in integrated rice-fish culture. Aquaculture 2005, 244, 119–128. [Google Scholar] [CrossRef]
  12. Agus, F.; Irawan, I.; Suganda, H.; Wahyunto, W.; Setiyanto, A.; Kundarto, M. Environmental multifunctionality of Indonesian agriculture. Paddy Water Environ. 2006, 4, 181–188. [Google Scholar] [CrossRef]
  13. Costanza, R.; De Groot, R.; Braat, L.; Kubiszewski, I.; Fioramonti, L.; Sutton, P.; Farber, S.; Grasso, M. Twenty years of ecosystem services: How far have we come and how far do we still need to go. Ecosyst. Serv. 2017, 28, 1–16. [Google Scholar] [CrossRef]
  14. Tsuruta, T.; Yamaguchi, M.; Abe, S.-I.; Iguchi, K. Effect of fish in rice-fish culture on the rice yield. Fish. Sci. 2011, 77, 95–106. [Google Scholar] [CrossRef]
  15. Yuan, Z.; Lun, F.; He, L.; Cao, Z.; Min, Q.; Bai, Y.; Liu, M.; Cheng, S.; Li, W.; Fuller, A.M. Exploring the state of retention of traditional ecological knowledge (TEK) in a Hani rice terrace village, Southwest China. Sustainability 2014, 6, 4497–4513. [Google Scholar] [CrossRef] [Green Version]
  16. Chan, J.H.; Iankova, K.; Zhang, Y.; McDonald, T.; Qi, X. The role of self-gentrification in sustainable tourism: Indigenous entrepreneurship at honghe hani rice terraces world heritage site, China. J. Sustain. Tour. 2016, 24, 1262–1279. [Google Scholar] [CrossRef]
  17. Costanza, R.; d’Arge, R.; de Groot, R.; Farber, S.; Grasso, M.; Hannon, B.; Limburg, K.; Naeem, S.; O’Neill, R.V.; Paruelo, J.; et al. The value of the world’s ecosystem services and natural capital. Nature 1997, 387, 253–260. [Google Scholar] [CrossRef]
  18. Costanza, R.; Chichakly, K.; Dale, V.; Farber, S.; Finnigan, D.; Grigg, K.; Heckbert, S.; Kubiszewski, I.; Lee, H.; Liu, S.; et al. Simulation games that integrate research, entertainment, and learning around ecosystem services. Ecosyst. Serv. 2014, 10, 195–201. [Google Scholar] [CrossRef] [Green Version]
  19. Fisher, B.; Turner, R. Ecosystem services: Classification for valuation. Biol. Conserv. 2008, 141, 1167–1169. [Google Scholar] [CrossRef]
  20. Reid, W.V.; Mooney, H.A. The Millennium Ecosystem Assessment: Testing the limits of interdisciplinary and multi-scale science. Curr. Opin. Environ. Sustain. 2016, 19, 40–46. [Google Scholar] [CrossRef]
  21. Wang, S.; Fu, B.; Wei, Y.; Lyle, C. Ecosystem services management: An integrated approach. Curr. Opin. Environ. Sustain. 2013, 5, 11–15. [Google Scholar] [CrossRef]
  22. Pascual, U.; Balvanera, P.; Díaz, S. Valuing nature’s contributions to people: The IPBES approach. Environ. Sustain. 2017, 26, 7–16. [Google Scholar] [CrossRef] [Green Version]
  23. Wood, S.L.R.; Jones, S.K.; Johnson, J.A.; Brauman, K.A.; Chaplin-Kramer, R.; Fremier, A.; Girvetz, E.; Gordon, L.J.; Kappel, C.V.; Mandle, L.; et al. Distilling the role of ecosystem services in the Sustainable Development Goals. Ecosyst. Serv. 2018, 29, 70–82. [Google Scholar] [CrossRef] [Green Version]
  24. He, S.; Gallagher, L.A.; Su, Y.; Wang, L.; Cheng, H. Identification and assessment of ecosystem services for protected area planning: A case in rural communities of Wuyishan national park pilot. Ecosyst. Serv. 2018, 31, 169–180. [Google Scholar] [CrossRef]
  25. Hardaker, A.; Pagella, T.; Rayment, M. Integrated assessment, valuation and mapping of ecosystem services and dis-services from upland land use in Wales. Ecosyst. Serv. 2020, 43, 101098. [Google Scholar] [CrossRef]
  26. Richards, D.R.; Tunçer, B. Using image recognition to automate assessment of cultural ecosystem services from social media photographs. Ecosyst. Serv. 2018, 31, 318–325. [Google Scholar] [CrossRef]
  27. Schirpke, U.; Meisch, C.; Marsoner, T.; Tappeiner, U. Revealing spatial and temporal patterns of outdoor recreation in the European Alps and their surroundings. Ecosyst. Serv. 2018, 31, 336–350. [Google Scholar] [CrossRef]
  28. Taffarello, D.; Bittar, M.; Sass, K.; Calijuri, M.D.C.; Cunha, D.G.F.; Mendiondo, E. Ecosystem service valuation method through grey water footprint in partially-monitored subtropical watersheds. Sci. Total Environ. 2020, 738, 139408. [Google Scholar] [CrossRef] [PubMed]
  29. Castonguay, A. Assessment of Resilience and Adaptability of Social-Ecological Systems: A Case Study of the Banaue Rice Terraces; University of Kiel: Kiel, Germany, 2014. [Google Scholar]
  30. Castonguay, A.C.; Burkhard, B.; Müller, F.; Horgan, F.; Settele, J. Resilience and adaptability of rice terrace social-ecological systems: A case study of a local community’s perception in Banaue, Philippines. Ecol. Soc. 2016, 21, 15. Available online: https://www.jstor.org/stable/26270372 (accessed on 10 January 2022). [CrossRef]
  31. Burkhard, B.; Müller, A.; Müller, F.; Grescho, V.; Anh, Q.; Arida, G.; Bustamante, J.V.; Van Chien, H.; Heong, K.; Escalada, M.; et al. Land cover-based ecosystem service assessment of irrigated rice cropping systems in southeast Asia: An explorative study. Ecosyst. Serv. 2015, 14, 76–87. [Google Scholar] [CrossRef]
  32. Horgan, F.G.; Ramal, A.F.; Bernal, C.C.; Villegas, J.M.; Stuart, A.M.; Almazan, M.L.P. Applying ecological engineering for sustainable and resilient rice production systems. Procedia Food Sci. 2016, 6, 7–15. [Google Scholar] [CrossRef] [Green Version]
  33. Horgan, F.G.; Ramal, A.F.; Villegas, J.M.; Almazan, M.L.P.; Bernal, C.C.; Jamoralin, A.; Pasang, J.M.; Orboc, G.; Agreda, V.; Arroyo, C. Ecological engineering with high diversity vegetation patches enhances bird activity and ecosystem services in Philippine rice fields. Reg. Environ. Chang. 2017, 17, 1355–1367. [Google Scholar] [CrossRef]
  34. Dang, K.B.; Windhorst, W.; Burkhard, B. A Bayesian Belief Network-based approach to link ecosystem functions with rice provisioning ecosystem services. Ecol. Indic. 2018, 100, 30–44. [Google Scholar] [CrossRef]
  35. Dang, K.B.; Burkhard, B.; Müller, F.; Dang, V.B. Modelling and mapping natural hazard regulating ecosystem services in Sapa, Lao Cai province, Vietnam. Paddy Water Environ. 2018, 16, 767–781. [Google Scholar] [CrossRef]
  36. Dang, K.B.; Burkhard, B.; Windhorst, W.; Müller, F. Application of a hybrid neural-fuzzy inference system for mapping crop suitability areas and predicting rice yields. Environ. Model. Softw. 2019, 114, 166–180. [Google Scholar] [CrossRef]
  37. Gu, H.; Jiao, Y.; Liang, L. Strengthening the socio-ecological resilience of forest-dependent communities: The case of the Hani Rice Terraces in Yunnan, China. For. Policy Econ. 2012, 22, 53–59. [Google Scholar] [CrossRef]
  38. Liechti, K.; Rodewald, R. Towards a framework for long-term conservation of terraced landscapes in Switzerland: Case studies of recultivated former vineyard and crop terraces. Pirineos 2020, 175, 175002. [Google Scholar] [CrossRef]
  39. Jiao, Y.; Okuro, T.; Takeuchi, K.; Liang, L.; Gao, X. Comparative Studies on Pattern and Ecosystem Services of the Traditional Rice Agricultural Landscapes in East Asia. World Terraced Landsc. Hist. Environ. Qual. Life 2019, 9, 225–238. [Google Scholar] [CrossRef]
  40. Jiao, Y.; Liang, L.; Okuro, T.; Takeuchi, K. Ecosystem Services and Biodiversity of Traditional Agricultural Landscapes: A Case Study of the Hani Terraces in Southwest China//Biocultural Landscapes; Springer: Dordrecht, Germany, 2014; pp. 81–88. [Google Scholar] [CrossRef]
  41. Shu, Y.; Song, W.; Ma, J. Construction of health evaluation index system of Hani terraced wetland ecosystem. Chin. J. Ecol. 2021, 41, 9292–9304. (In Chinese) [Google Scholar] [CrossRef]
  42. Bai, Y.; Min, Q.; Liu, M.; Yuan, Z.; Xu, Y.; Cao, Z.; Li, J. Resilience of the Hani rice terraces system to extreme drought. J. Food Agric. Environ. 2013, 11, 2376–2382. [Google Scholar]
  43. Liu, M.; Zhang, D.; Li, W. A comparative study on the comprehensive benefits of fish farming in terrace fields and conventional terrace farming modes—Taking Qingtian County, Zhejiang Province as an example. Chin. J. Ecol. Agric. 2010, 18, 164–169. (In Chinese) [Google Scholar] [CrossRef]
  44. Liu, M.-C.; Xiong, Y.; Yuan, Z.; Min, Q.-W.; Sun, Y.-H.; Fuller, A.M. Standards of ecological compensation for traditional eco-agriculture: Taking rice-fish system in Hani terrace as an example. J. Mt. Sci. 2014, 11, 1049–1059. [Google Scholar] [CrossRef]
  45. Min, Q.; Tian, M. Yunnan Honghe Hani Rice Terrace System; China Agricultural Press: Beijing, China, 2015. (In Chinese) [Google Scholar]
  46. Zhan, G.; Jin, Z. Hani rice terraces of honghe-the harmonious landscape of nature and humans. Landsc. Res. 2015, 40, 655–667. [Google Scholar] [CrossRef]
  47. Jiao, Y.; Li, X.; Liang, L.; Takeuchi, K.; Okuro, T.; Zhang, D.; Sun, L. Indigenous ecological knowledge and natural resource management in the cultural landscape of China’s Hani Terraces. Ecol. Res. 2012, 27, 247–263. [Google Scholar] [CrossRef]
  48. Weber, J.L. Implementation of land and ecosystem accounts at the European Environment Agency. Ecol. Econ. 2007, 61, 695–707. [Google Scholar] [CrossRef]
  49. Hou, Y.; Zhou, S.; Burkhard, B.; Müller, F. Socioeconomic influences on biodiversity, ecosystem services and human well-being: A quantitative application of the DPSIR model in Jiangsu, China. Sci. Total Environ. 2014, 490, 1012–1028. [Google Scholar] [CrossRef]
  50. Feld, C.K.; Sousa, J.P.; Da Silva, P.M.; Dawson, T.P. Indicators for biodiversity and ecosystem services: Towards an improved framework for ecosystems assessment. Biodivers. Conserv. 2010, 9, 2895–2919. [Google Scholar] [CrossRef]
  51. Kristensen, P. The DPSIR Framework, Workshop on a Comprehensive/Detailed Assessment of the Vulnerability of Water Resources to Environmental Change in Africa using River Basin Approach; UNEP Headquarters: Nairobi, Kenya, 2004. [Google Scholar]
  52. Svarstad, H.; Petersen, L.K.; Rothman, D.; Siepel, H.; Wätzold, F. Discursive biases of the environmental research framework DPSIR. Land Use Policy 2008, 25, 116–125. [Google Scholar] [CrossRef]
  53. Xiao, Q.; Zhu, S.; Zheng, X.; Wang, W.; Min, Q.; Li, R. Ecosystem service value analysis of Youxi Union Terrace. Res. Subtrop. Agric. 2019, 15, 73–79. (In Chinese) [Google Scholar]
  54. Xie, G.D.; Zhang, C.-X.; Zhang, L.-M.; Chen, W.-H.; Li, S.-M. Improvement of ecosystem service valueization method based on unit area value equivalent factor. J. Nat. Resour. 2015, 30, 1243–1254. (In Chinese) [Google Scholar]
  55. Zheng, C.; Guo, X.; Zu, Y.; He, Y.; Xu, Y. Evaluation of ecosystem service value of Yuanyang terraced rice fields. Ecol. Sci. 2018, 37, 124–130. (In Chinese) [Google Scholar]
  56. Jiang, Z. Economic Value Evaluation of Paddy Ecosystem’s Services and Functions in Jingzhou; Yangtze University: Jingzhou, China, 2016; pp. 126–128. (In Chinese) [Google Scholar]
  57. Liu, D.; Tang, R.; Xie, J.; Tian, J.; Shi, R.; Zhang, K. Valuation of ecosystem services of rice–fish coculture systems in Ruyuan County, China. Ecosyst. Serv. 2020, 41, 101054. [Google Scholar] [CrossRef]
  58. Zu, Z. Evaluation of Ecosystem Service Value of No-Till Rice-Duck Ecological Breeding Model. Ph.D. Thesis, Hunan Agricultural University, Changsha, China, 2007. (In Chinese). [Google Scholar]
  59. Bai, Y.; Li, H.; Wang, X.Y.; Alatalo, J.M.; Liu, W.J. Evaluating natural resourceassets and gross ecosystem products using ecological accounting system: A case study in Yunnan Province. J. Nat. Resour. 2017, 32, 1100–1112. [Google Scholar]
  60. Sun, J. Study on reference crop evapotranspiration and its climatic impact factors in Ningxia Yellow River Irrigation Area. J. Irrigat. Drain. 2006, 61, 4–57. (In Chinese) [Google Scholar]
  61. Zhou, X.; Li, F.; Xu, C.; Fang, F. Evaluation of Ecosystem Service Value of Rice Field Constructed Wetland in Zhejiang. Zhejiang Agric. Sci. 2009, 5, 971–974. (In Chinese) [Google Scholar]
  62. Bai, Y.; Min, Q.; Li, J. Analysis of forest soil water conservation function in Hani terrace ecosystem. Res. Soil Water Conserv. 2016, 23, 166–170. (In Chinese) [Google Scholar] [CrossRef]
  63. Dahowski, R.; Li, X.; Davidson, C.; Wei, N.; Dooley, J.; Gentile, R. A preliminary cost curve assessment of carbon dioxide capture and storage potential in China. Energy Proced. 2009, 1, 2849–2856. [Google Scholar] [CrossRef] [Green Version]
  64. Liu, D.; Feng, Q.; Zhang, J.; Zhang, K.; Tian, J.; Xie, J. Ecosystem services analysis for sustainable agriculture expansion: Rice-fish co-culture system breaking through the Hu Line. Ecol. Indic. 2021, 133, 108385. [Google Scholar] [CrossRef]
  65. Tang, R. Research on the Value Analysis of the Integrated Rice and Fish Farming System in Ruyuan County. Ph.D. Thesis, Hunan University, Changsha, China, 2019. (In Chinese). [Google Scholar]
  66. Li, F.; Gao, J.; Xu, Y.; Nie, Z.; Fang, J.; Zhou, Q.; Xu, G.; Shao, N.; Xu, D.; Xu, P.; et al. Biodiversity and sustainability of the integrated rice-fish system in Hani terraces, Yunnan province, China. Aquac. Rep. 2021, 20, 100763. [Google Scholar] [CrossRef]
  67. Wang, J.; Shan, Q.; Liang, X.; Guan, F.; Zhang, Z.; Huang, H.; Fang, H. Levels and human health risk assessments of heavy metals in fish tissue obtained from the agricultural heritage rice-fish-farming system in China. J. Hazard. Mater. 2020, 386, 121627. [Google Scholar] [CrossRef]
  68. Nie, Z.; Li, F.; Zhao, W.; Xu, G.; Liu, B.; Wang, Y.; Shao, N.; Hu, J.; Xu, P. Microbial community structure under the rice-carp co-culture systems in Hani Terraces. J. Fish. 2020, 44, 469–479. (In Chinese) [Google Scholar]
  69. Tong, C.; Feagin, R.A.; Lu, J.; Zhang, X.; Zhu, X.; Wang, W.; He, W. Ecosystem service values and restoration in the urban Sanyang wetland of Wenzhou, China. Ecol. Eng. 2007, 29, 249–258. [Google Scholar] [CrossRef]
  70. Aryal, K.; Ojha, B.R.; Maraseni, T. Perceived importance and economic valuation of ecosystem services in Ghodaghodi wetland of Nepal. Land Use Policy 2021, 106, 105450. [Google Scholar] [CrossRef]
  71. Zuze, S. Measuring the Economic Value of Wetland Ecosystem Services in Malawi: A Case Study of Lake Chiuta Wetland; University of Zimbabwe: Harare, Zimbabwe, 2013; Available online: http://hdl.handle.net/10646/1401 (accessed on 5 February 2022).
  72. Sasmal, D.; Borah, B.K.D.; Kumar, S.; Borah, D.; Bora, M.S.; Kalita, H. Improvement of farmer’s livelihood through rice-fish-duck integration at Namsai District of Arunachal Pradesh. J. Entomol. Zool. Stud. 2020, 8, 1582–1585. [Google Scholar]
  73. Dai, X.; Wang, L.; Yang, L.; Wang, S.; Li, Y.; Wang, L. Predicting the supply–demand of ecosystem services in the Yangtze River Middle Reaches Urban Agglomeration. Prog. Phys. Geogr. Earth Environ. 2022, 03091333221074490. [Google Scholar] [CrossRef]
  74. Dai, X.; Wang, L.; Tao, M.; Huang, C.; Sun, J.; Wang, S. Assessing the ecological balance between supply and demand of blue-green infrastructure. J. Environ. Manag. 2021, 288, 112454. [Google Scholar] [CrossRef]
  75. Yoshida, K. An economic evaluation of the multifunctional roles of agriculture and rural areas in Japan. Tech. Bull. 2001, 154, 409. [Google Scholar]
  76. Wang, Z.; Marafa, L. Tourism Imaginary and Landscape at Heritage Site: A Case in Honghe Hani Rice Terraces, China. Land 2021, 10, 439. [Google Scholar] [CrossRef]
  77. Tekken, V.; Spangenberg, J.H.; Escalada, M.; Burkhard, B.; Stoll-Kleemann, S.; Truong, D.T.; Settele, J. Things are different now: A qualitative assessment of farmer perceptions of cultural ecosystem services of traditional rice landscapes in Vietnam, and the Philippines. Ecosyst. Serv. 2017, 25, 153–166. [Google Scholar] [CrossRef]
  78. Tilliger, B.; Rodríguez-Labajos, B.; Bustamante, J.V.; Settele, J. Disentangling values in the interrelations between cultural ecosystem services and landscape conservation: A case study of the Ifugao Rice Terraces in the Philippines. Land 2015, 4, 888–913. [Google Scholar] [CrossRef] [Green Version]
  79. McLaughlin, D.L.; Cohen, M.J. Realizing ecosystem services: Wetland hydrologic function along a gradient of ecosystem condition. Ecol. Appl. 2013, 23, 1619–1631. [Google Scholar] [CrossRef]
  80. Lansing, J.S.; Kremer, J.N. Rice, fish, and the planet. Proc. Natl. Acad. Sci. USA 2011, 108, 19841–19842. [Google Scholar] [CrossRef] [Green Version]
  81. Zhang, Y.; Min, Q.; Li, X.D. Evaluation of spatial differences in tourism resources values in Honghe Hani Rice Terrace Systems. Zhongguo Shengtai Nongye Xuebao/Chin. J. Eco-Agric. 2018, 26, 971–979. (In Chinese) [Google Scholar] [CrossRef]
  82. Nayak, P.; Panda, B.; Lal, B.; Gautam, P.; Poonam, A.; Shahid, M.; Tripathi, R.; Kumar, U.; Mohapatra, S.; Jambhulkar, N. Ecological mechanism and diversity in rice based integrated farming system. Ecol. Indic. 2018, 91, 359–375. [Google Scholar] [CrossRef]
  83. Zhang, Y.; Min, Q.; Jiao, W.; Liu, M. Values and conservation of Honghe Hani Rice Terraces System as a GIAHS site. J. Resour. Ecol. 2016, 7, 197–204. [Google Scholar]
  84. Liu, S.; Jiao, W.; Min, Q.; Yin, J. The influences of production factors with profit on agricultural heritage systems: A case study of the rice-fish system. Sustainability 2017, 9, 1842. [Google Scholar] [CrossRef] [Green Version]
  85. Béné, C.; Arthur, R.; Norbury, H.; Allison, E.H.; Beveridge, M.; Bush, S.; Campling, L.; Leschen, W.; Little, D.; Squires, D.; et al. Contribution of fisheries and aquaculture to food security and poverty reduction: Assessing the current evidence. World Dev. 2016, 79, 177–196. [Google Scholar] [CrossRef]
  86. Fang, L.; Wang, L.; Chen, W.; Sun, J.; Cao, Q.; Wang, S.; Wang, L. Identifying the impacts of natural and human factors on ecosystem service in the Yangtze and Yellow River Basins. J. Clean. Prod. 2021, 314, 127995. [Google Scholar] [CrossRef]
  87. Xu, Q.; Liu, T.; Guo, H.; Dou, Z.; Gao, H.; Zhang, H. Conversion from rice–wheat rotation to rice–crayfish coculture increases net ecosystem service values in Hung-tse Lake area, east China. J. Clean. Prod. 2021, 319, 128883. [Google Scholar] [CrossRef]
  88. Liu, M.; Liu, W.; Yang, L.; Jiao, W.; He, S.; Min, Q. A dynamic eco-compensation standard for Hani Rice Terraces System in southwest China. Ecosyst. Serv. 2019, 36, 100897. [Google Scholar] [CrossRef]
Ijerph 19 08549 g001 550
Figure 1. (a) Map of Yunnan province; (b) Map of Honghe Hani and Yi Autonomous Prefecture; (c) A map of study area showing topography with waterways.
Figure 1. (a) Map of Yunnan province; (b) Map of Honghe Hani and Yi Autonomous Prefecture; (c) A map of study area showing topography with waterways.
Ijerph 19 08549 g001
Ijerph 19 08549 g002 550
Figure 2. Forest-village-terrace field-water system.
Figure 2. Forest-village-terrace field-water system.
Ijerph 19 08549 g002
Ijerph 19 08549 g003 550
Figure 3. Integrated rice–fish–duck farming model in Honghe Hani terraced field.
Figure 3. Integrated rice–fish–duck farming model in Honghe Hani terraced field.
Ijerph 19 08549 g003
Ijerph 19 08549 g004 550
Figure 4. DPSIR model of the Hani rice–fish–duck integrated farming.
Figure 4. DPSIR model of the Hani rice–fish–duck integrated farming.
Ijerph 19 08549 g004
Table
Table 1. Required data.
Table 1. Required data.
Some monitoring dataevaluation area
number of the growth periods of rice
the number of days of standing water for rice
the number of hot days in summer
price of agricultural water and coal
ProvisioningRed rice yield and market price
Common carp yield and market price
Duck and duck egg yield and market price
Regulation and Maintenanceaverage emission fluxes of CH4, rice CO2, and soil CO2 from rice fields
average daily water evaporation in terraced fields
average SO2, NOx, HF, and dust concentrations absorbed by terraced fields
the cost of SO2 removal, NOx removal, HF removal and dust removal
pesticide costs/hm2
soil water infiltration rate
market price of agricultural water
organic matter, total nitrogen, total phosphorus, and total potassium contents in the soil tillage layer
cost of fertilizer
soil thickness in the tillage layer
Soil bulk density
Biomass of straw and rice root
Carbon content of Straw and rice root
annual CO2 and CH4 emissions
market price of organic matter calculated as pure carbon
Culturalthe number of visitors
the total number of tourists throughout the year
total tourism revenue
Table
Table 2. The values of the ecosystem services classification of the Hani terraces rice–fish–duck integrated faming system (according to CICES V5.1).
Table 2. The values of the ecosystem services classification of the Hani terraces rice–fish–duck integrated faming system (according to CICES V5.1).
CICESV5.1
Section		DivisionGroupEcosystem Services of the Rice–Fish–Duck SystemGoods and Benefits Valued EconomicallyEstimation Method
ProvisioningBiomassCultivated Plants, Reared aquatic and animals for nutrition, materials or energy1. Red rice, fish and duck for nutritionProvisioning servicemarket price method
Regulation & MaintenanceRegulation of physical, chemical, biological conditionsAtmospheric
composition and
conditions		2. Carbon dioxide fixation from photosynthesisCarbon fixation and oxygen releaseafforestation cost method and industrial oxygen
3. Oxygen release from rice photosynthesis
4. Reduced greenhouse gas emissionsGreenhouse gas reductionGWP-Global Warming Potentials
5. Regulation of temperature and humidity, including ventilation and transpirationClimate controlreplacement costs method
6. Rice absorbs SO2, HF, NOx, and dustAir purificationreplacement costs method
Pest and disease control7. Reducing pesticides and herbicidesPest controlreplacement costs method
Lifecycle maintenance and habitat and gene pool protection8. Increase of fauna diversity and micro-organismsBiodiversityequivalent factor method
Water conditions9. Recharging groundwaterWater storage and retentionreplacement costs method
Regulation of soil quality10. Reducing land abandonmentSoil conservationopportunity cost
11. organic accumulationMaintaining soil nutrientsreplacement costs method
CulturalDirect, in-situ, and outdoor interactions with living systems that depend on presence in the environmental settingSpiritual, symbolic and other interactions with natural environment12. Elements of living systems used for entertainment or representationDevelopment of tourismsimulated market approach
Intellectual and
representative
interactions with natural
environment		13. Cultural value and heritage
14. Characteristics of living systems that enable aesthetic experiences
Table
Table 3. Values of the various ecosystem services of the Hani terraces rice–fish–duck integrated faming system.
Table 3. Values of the various ecosystem services of the Hani terraces rice–fish–duck integrated faming system.
Ecosystem Service ValueEquationExplanation of Parameters
V1: The value of providing primary product functions in terraced rice–fish–duck ecosystems (CNY);V1 = Tr × Pr + Tf × Pf + Td × PdTr: The yield of rice in the evaluation area (t);
Pr: Market price of rice in the evaluation area (CNY/t);
Tf: The yield of common carp in the evaluation area (t);
Pf: Market price of common carp in the evaluation area (CNY/t);
Td: The yield of duck and duck egg in the evaluation area (individual);
Pd: Market price of duck and duck egg in the evaluation area (CNY/ individual)
V2 represents the total value of greenhouse gas emissions V C O 2   = Tr × a × b × MC × CafforestationC V C O 2 represents the CO2 fixation service value; a is the economic coefficient of rice. In our study, a value of 0.5 was used (Liu et al., 2020) [57].
b is one rice field can fix 1.63 g of CO2 according to the photosynthesis equation;
Mc: CO2 consists of 27.27% C;
Cafforestation was 327.32(CNY/t)
V O 2   = Tr × a × c × CafforestationO V O 2 represents the release O2 service value
c is that produce 1.19 g of O2 for every gram of rice in the form of dry matter.
G C H 4   = A × D × g1 G C H 4 represents the total CH4 emissions (kg)
A was the evaluation area of the integrated rice–fish–duck ecosystem (hm2);
D was the growing period of rice (d).
g1 was the average emission flux of CH4 in rice field ecosystem in Yunnan Province(kg·hm2/d) (Zu, 2007) [58]
G C O 2   = A × D × (g2 + g3) G C O 2 represents the total CO2 emissions (kg)
g2 was the average emission flux of rice CO2 in the rice field ecosystem in Yunnan Province;
g3 was the average emission flux of soil CO2 in the rice field ecosystem in Yunnan Province (kg·hm2/d) (Zu, 2007) [58]
G T C O 2   = ( G C O 2   + d ×   G C H 4 )/1000 G T C O 2 represents the CH4 and CO2 emissions in the rice field ecosystem were converted into total CO2 emissions (t)
d was the coefficient of conversion of CH4 to CO2
V 2 = G T C O 2   × MC × CafforestationC (Bai et.al., 2017) [59]
V3 represents value of climate regulation (CNY)Qt = E × TnQt represents the total cooling effect (mm);
E represents average daily water evaporation in terrace fields (mm/d), that is, 3.83 mm/day (Sun et al., 2006) [60]
Tn represents the number of hot days in summer
V3 = Qt × A × e × Pe represents the amount of heat consumed on evaporating 50 mm water in a 1 hm2 in terraces field is equal to the heat required to burn 30.57 tons of standard coal (Zhou et al., 2009) [61]; P represents the price of coal
V4 represents value of the air purification (CNY)V4 = (Qd × Pd + Qs × Ps + Qh × Ph + Qn × Pn) × AQd, Qs, Qh Qn and represents the average flux of dust, SO2, HF and NOx absorbed by terraced ecosystems (kg/hm2); Pd, Ps, Ph, Pn represents the cost of dust, SO2, HF and NOx removal (CNY/kg)
V5 represents value of the pest control (CNY)V5 = Qp × AQp represents the reduced pesticide costs per hm2 by integrated rice–fish–duck farming ecosystem
V6 represents value of the maintaining biodiversity (CNY)V6 = PWC × APWC represents value of biodiversity in each unit of integrated rice–fish–duck farming ecosystem.
V7 represent the value of water regulation (CNY)V7 = f × A × PW × Twf represents the soil water infiltration rate in terrace field (mm/d), that is 7.22 mm/d (Bai et al., 2016) [62]); PW represents market price of agricultural water, and that is 0.2 CNY/m3 according to the survey data. Tw represents the number of days of standing water during the growth period of rice (d)
V8 represents the value of soil conservation of Hani terraces (CNY)V8 = A × ST × SBD × ∑(SOM + TN + TP + TK) × PFST represents soil thickness in the tillage layer; SBD represents soil bulk density; ∑(SOM + TN + TP + TK) represents sum of organic matter, total nitrogen, total phosphorus and total potassium content in soil; PF represents fertilizer price.
V9 represents value of soil organic accumulation;Isoc = Nt × 5 × Cr + Ns × 11% × CsIsoc represents the soil organic matter input (kgC/hm2); Nt and Ns are the biomass of rice roots and straw, respectively (kg/hm2); Cr and Cs are the carbon content of rice roots and straw, respectively.
Osoc = R C O 2   × 0.27   +   R C H 4   × 0.75Osoc represents the soil organic matter output (kgC/hm2); R C O 2 and R C H 4 are the annual CO2 and CH4 emissions from terrace fields, respectively; 0.27 and 0.75 are the coefficients for converting CO2 and CH4 to pure carbon.
Bsoc = IsocOsoc
V9 = Bsoc × PsocPsoc is the market price of organic matter calculated as pure carbon (1.53 CNY/kg C) (Jiang (2016) [56])
V10 represents value of cultural serviceV10 = (Nrff/Nt) × RzNrff is the number of visitors to the rice-fish Culture Festival; Nt was the total number of tourists throughout the year according to the yearbook of Honghe; Rz was the total tourism revenue (CNY/year)
Table
Table 4. Comparison of the valuations of the integrated rice–fish–duck farming ecosystem and the rice monoculture system (2020).
Table 4. Comparison of the valuations of the integrated rice–fish–duck farming ecosystem and the rice monoculture system (2020).
SectionEcosystem Services of the Rice–Fish–Duck SystemValue (10
Thousand)		(%)Rice-Monoculture
System		Added ValueAdded
Proportion
Provisioning
Service value		red rice, fish and duck176,086.6853.10%43,088.88132,997.8208.66%
Gas regulationcarbon fixation and oxygen release5230.84 5230.84--
greenhouse gas reduction7166.86 8220.231053.3714.70%
gas regulation−1936.02−0.58%−2989.391585−1053.37−54.41%
Climate regulationcooling effect112,737.1734.00%112,737.17--
Air purificationpurification of air quality11,994.023.62%11,994.02--
Pest controlreduce the pesticide501.500.15%---
Maintaining biodiversitymaintaining ecological balance and biodiversity1219.620.37%1219.62--
Water regulationconserve of groundwater sources308.980.09%308.98--
Soil conservationimprove the soil structure58.57640.02%60.361.782.96%
Soil organic accumulationaccumulation of organic matter7562.992.28%7562.99--
Cultural servicelandscape aesthetic value and tourism23,085.336.96%9789.2813,296.05135.82%
CNY331,619.5452100%183,771.9128147,847.632480.45%
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Yuan, Y.; Xu, G.; Shen, N.; Nie, Z.; Li, H.; Zhang, L.; Gong, Y.; He, Y.; Ma, X.; Zhang, H.; et al. Valuation of Ecosystem Services for the Sustainable Development of Hani Terraces: A Rice–Fish–Duck Integrated Farming Model. Int. J. Environ. Res. Public Health 2022, 19, 8549. https://doi.org/10.3390/ijerph19148549

AMA Style

Yuan Y, Xu G, Shen N, Nie Z, Li H, Zhang L, Gong Y, He Y, Ma X, Zhang H, et al. Valuation of Ecosystem Services for the Sustainable Development of Hani Terraces: A Rice–Fish–Duck Integrated Farming Model. International Journal of Environmental Research and Public Health. 2022; 19(14):8549. https://doi.org/10.3390/ijerph19148549

Chicago/Turabian Style

Yuan, Yuan, Gangchun Xu, Nannan Shen, Zhijuan Nie, Hongxia Li, Lin Zhang, Yunchong Gong, Yanhui He, Xiaofei Ma, Hongyan Zhang, and et al. 2022. "Valuation of Ecosystem Services for the Sustainable Development of Hani Terraces: A Rice–Fish–Duck Integrated Farming Model" International Journal of Environmental Research and Public Health 19, no. 14: 8549. https://doi.org/10.3390/ijerph19148549

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop