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Article

Effectivity and Efficiency of Best Management Practices Based on a Survey and SWAPP Model of the Xiangxi River Basin

State Key Laboratory of Water Environment Simulation, School of Environment, Beijing Normal University, Beijing 100875, China
*
Author to whom correspondence should be addressed.
Water 2021, 13(7), 985; https://doi.org/10.3390/w13070985
Submission received: 10 March 2021 / Revised: 26 March 2021 / Accepted: 31 March 2021 / Published: 3 April 2021

Abstract

:
A questionnaire survey was conducted among farmers in the Xiangxi River Basin to investigate the local livestock situation and the farmers’ understanding of and attitude towards pollution. The results showed that local farmers lacked environmental awareness and few livestock and poultry pollution treatment measures had been implemented. However, once farmers understood that livestock pollution would greatly influence their lives and interests, they would act to prevent Agricultural non–point source (ANPS) pollution. The farmers’ education level and satisfaction with the environment were the main factors affecting their awareness regarding ANPS pollution. The “Comprehensive Environmental Optimization Tool SWAT–APEX Interface” model (SWAPP) was used to simulate the reduction of ANPS by different best management practices (BMPs) and the construction cost was calculated. The results showed that compound bedding and piping systems and ponds were the most effective and economic measures for reducing ANPS pollution. Spatially, implementing BMPs in the upstream region was better for improving water quality. The nitrate reduction rate in upstream sub–basins reached 90%, which is 30% larger than that in downstream sub–basins with combined bedding and piping systems. Combining the farmers’ awareness of and engagement in livestock pollution with cost–effective BMPs can improve the BMPs’ effectivity and efficiency.

1. Introduction

With the rapid socioeconomic development in recent decades, the issue of water pollution has become increasingly serious. Water pollution sources can be categorized as point source (PS) or non–point source (NPS) [1,2,3]. With the improvement of PS pollution control, NPS pollution has become more notable and difficult to control as it disperses easily, is difficult to detect, varies widely, and is hysteretic [4]. NPS pollution is primarily caused by local agricultural activities, such as the use of fertilizers and pesticides, livestock and poultry breeding, and rural household waste [5,6,7,8]. Agricultural NPS (ANPS) pollution has become a major cause of water quality degradation in many rivers [9,10,11] and identifying and controlling it has become key to improving the quality of the aquatic environment [12].
Among the various agricultural activities, livestock and poultry waste has become the largest ANPS pollutant in China as the total nitrogen (TN), total phosphorus (TP), and chemical oxygen demand (COD) of livestock and poultry waste accounted for 38%, 56%, and 96% of those of all agricultural sources, respectively [13,14,15,16]. Feces, sewage, and odor are the main pollutants produced by livestock and poultry farming [13,17,18]. In areas with a high livestock intensity, the spreading of manure on land could cause nitrogen and phosphorus to leach into water, causing eutrophication [19,20]. Furthermore, harmful gaseous substances, such as ammonia, produced by feces are a main source of air pollution, which not only affects people’s health and delays the growth of livestock, but also increases the concentration of ammonia in the air, causing the amount of acid precipitation to increase by three to five times [21]. Therefore, preventing and controlling livestock pollution is imperative for protecting the aquatic environment in China.
Many measures of reducing livestock pollution have been developed in China and other countries. Best management practices (BMPs) are widely used to reduce NPS pollution, including livestock waste [6,7,22]. Research on practices for controlling and decreasing the negative impacts of ANPS pollution has been conducted for many decades, and the main practices include land–use change, reducing the use of pesticides and fertilizers, and terracing [23,24]. The implementation of these measures is affected by the local conditions, including economic, social, and environmental factors, and the preferences of farmers [25,26], who are the main stakeholders in the implementation of BMPs. It is difficult to manage agricultural practices while excluding farmers and not considering whether they are willing to participate [27,28]. Therefore, the awareness and willingness of farmers to participate in pollution–reduction measures are also crucial issues in controlling agricultural pollution.
Prior to implementing BMPs, models should be used to simulate pollution loads and evaluate the effects of these practices [7]. Reliable environmental and economic models need to be integrated to select low–cost and highly effective environmental practices for agricultural watersheds [29,30]. The automated “Comprehensive Environmental Optimization Tool SWAT–APEX Interface Program” (SWAPP) was developed with funding from the U.S. Environmental Protection Agency [31]. The SWAPP model has been used to simulate the environmental impacts of different policies and management measures [32,33], and model has been widely applied to simulating livestock and poultry pollution and planning the maximum daily pollution loads of basins [33,34,35,36]. However, the SWAPP model does not consider the effectivity and efficiency of BMPs.
In this study, the Xiangxi River watershed, located in the Three Gorges Reservoir Region, was selected as the research area. A questionnaire survey was conducted to investigate the awareness and willingness of farmers to pay for agricultural environmental pollution–reduction measures, and the factors influencing their understanding were further analyzed. The economic and environmental benefits of several BMPs were then simulated using the SWAPP model. By combining the results of the questionnaire survey and SWAPP model, the effectivity and efficiency of different BMPs were discussed.

2. Materials and Methods

2.1. Study Area

The Xiangxi River watershed is located in the western part of Hubei Province, China (30°57′–31°34′ N, 110°25′–111°06′ E). The area is approximately 3200 km2 and is the largest tributary of the Hubei Reservoir in the Three Gorges Reservoir Region (Figure 1). The watershed divides into three major tributaries, i.e., the Nanyang, Gufu, and Gaolan Rivers. The terrain in this area is complex, and the elevation varies between 110 and 3088 m. The region experiences a humid subtropical continental monsoon climate. The average annual rainfall in the basin reaches 1100 mm, and the average temperature is 15.6 °C. The high amount of rainfall and complex terrain make the region liable to NPS pollution.
The Xiangxi River watershed crosses Xingshan County from north to south. Xingshan County is a typical agricultural planting area with a high level of unmanaged chemical fertilizer and pesticide usage that pollutes groundwater and rivers and exacerbates eutrophication [37]. Agricultural planting, livestock farming, and domestic sewage are the main pollution sources in this region, and livestock farming (swine, cattle, and broiler) contributes the most to TN and TP discharge [38,39]. Furthermore, with the development of the livestock and poultry industry, the production of livestock and poultry manure is growing rapidly, while its utilization rate is low [3,38]. Therefore, the lost nutrients, such as nitrogen and phosphorus, enrich and pollute nearby water bodies. Thus, identifying the most appropriate and effective measures of controlling and decreasing pollution by livestock and poultry waste is urgent.

2.2. Questionnaire Survey

In this study, livestock and poultry breeding in the Xiangxi River Basin, including eight towns and 109 administrative villages, was surveyed (Figure 1). The survey area was concentrated in Xingshan County. A questionnaire survey was conducted and supplemented by consultation and communication with local farmers. Basic information about the farmers included their age, sex, profession, and education level. All respondents were asked if they had ever reared livestock and poultry, and further information, such as the animal species, quantities, waste treatment methods, and the farmer’s understanding of and attitude towards pollution, was collected from farmers who had raised livestock.
Farmers with an awareness of environmental problems may be more willing to participate in environmental prevention and management measures. A farmer’s understanding of environmental problems can be regarded as a binary variable: has recognized (=1) or has not recognized (=0). Based on the survey, a binary logistic regression model was used to analyze the factors influencing the farmers’ cognition. The form of the binary logistic model is as follows:
P = F ( Z ) = 1 1 + e Z
Z = b 0 + b 1 X 1 + b 2 X 2 + + b n X n
where P was the probability of the farmer’s understanding of environmental problems, Xi = (i = 1, 2, …, n) is the independent variable (influencing factor), bi = (i = 1, 2, …, n) is the regression coefficient of the ith influencing factor, and e is a random error term. b0 and b1 can be estimated following the maximum likelihood method.
Cognition was used as the dependent variable when analyzing the binary logistic regression model. Meanwhile, the individual characteristics and environmental satisfaction of the farmers were selected as the independent variables (Table 1).

2.3. SWAPP Model

The SWAPP model was used to analyze the environmental effects of different BMPs. SWAPP modeling systems incorporate the following environmental models: (1) Soil and Water Assessment Tool (SWAT) and (2) Agricultural Policy/Environmental Extender (APEX). SWAPP converts SWAT files to–and–from APEX format and simultaneously simulates SWAT and APEX. This arrangement of the SWAT and APEX models allows us to simulate scenarios, such as filter strips, at the field–level using APEX, which is not feasible in SWAT [32].
The Soil and Water Assessment Tool (SWAT) is a semi–distributed, process–based hydrological model used for continuous simulations of various processes that was developed by the United States Department of Agriculture Agricultural Research Service [40]. SWAT can be used to predict the impacts of management on water, sediment, and agricultural chemical yields in large, ungauged watersheds on a daily basis [40,41]. The water balance is the basis of the SWAT model, on which pollutant simulation is based [42]. The water balance is calculated as follows:
S W t = S W 0 + i = 1 t ( R d a y Q s u r f E a W s e e p Q g w )
where SWt is the final soil moisture content, SW0 is the initial soil moisture content, Rday is the rainfall, Qsurf is the surface runoff, Ea is the evapotranspiration, Wseep is the water transferred from the soil profile into the gas zone, and Qgw is the return streamflow on day i.
APEX is a tool for managing whole farms or small watersheds to obtain sustainable production efficiency and maintain environmental quality [43]. APEX operates on a daily time step and is capable of performing long term simulations at the whole farm or small watershed level [44]. Effects of terrace systems, grass waterways, strip cropping, buffer strips/vegetated filter strips, crop rotations, plant competition, plant burning, grazing patterns of multiple herds, fertilizer, irrigation, liming, furrow diking, drainage systems, and manure management (feed yards and dairies with or without lagoons) can be simulated and assessed [45,46].
Several alternative BMPs were selected to assess their effectiveness for reducing nutrient and sediment losses within the SWAPP model (Table 2). The main function of bedding and pipes was to store water when there was too much rain, or transport excess underground water through pre–laid pipes. The bedding and piping systems (bedding and piping–no ditches improvement (BP–ND), bedding and piping–ditches expansion and reservoir system (BP–DER), bedding and piping–two stage ditches system (BP–TSD), and bedding and piping–tailwater irrigation (BP–TWI)) can reduce the accumulation of livestock and poultry manure and discharge the manure–polluted water [47]. The vegetation filter belt (FB) is actually a strip formed by densely planted plants or crops, which is mainly used to intercept the runoff from the source of pollution and filter out the pollutants [48]. The filter belt can also increase regional infiltration and reduce surface runoff and non–particle pollutants. Therefore, it can effectively reduce the levels of nutrients in manure to minimize water pollution [49]. Land leveling (LL) can change the distribution of nitrogen and phosphorus in the manure and other pollutants and reduce soil erosion along a slope. Meanwhile, dikes mitigate flood disasters and protect farmland during the flood season [50]. Pond construction is also an effective method of reducing non–point source pollution that can effectively prevent runoff, sediment, and nutrients from entering a river or field.
To compare the pollution abatement by different environmental pollution control measures, the flow rate and production of sediment, organic nitrogen (ORGN), organic phosphorus (ORGP), nitrate (NO3), phosphate (PO43−), TN, and TP in the entire basin were statistically analyzed.
The construction costs of BMPs were estimated using data summarized from studies conducted in China and other countries [7,51,52,53,54]. The BMPs database website (http://www.bmpdatabase.org, accessed on 31 March 2021) was combined with the Standard for Land Consolidation Engineering in Hubei Province to account costs.
Plastic pipes with an inner diameter of 0.15 m were selected for the pipeline system, and they were placed at a depth of 1–2 m with a spacing of 15 m. The two–stage ditches piping system combined pipelines and ditches with a depth of 1.5 m, width of 8 m, and spacing of 50 m. The ditches expansion and reservoir system included reservoirs with a depth of 3 m and width of 20 m to drain water based on a pipeline and ditch system. Ponds had a depth of 1–3 m, while dams required high construction costs, but had no specific data.

2.4. Data Collection and Model Setup

The data used in the SWAPP model included land use, soil, meteorological, hydrologic, water quality, and local livestock data. The land–use data for 2010 were obtained from a Landsat5 TM satellite image and interpreted by the Environment for Visualizing Images (ENVI) at a resolution of 30 m. The soil maps (30 m resolution) were obtained from the Institute of Geography, Chinese Academy of Sciences. The soil properties were collected from the Chinese soil database and local surveys (National Soil Survey Office, 1998). The sub–watersheds were delineated using the second version of the Advanced Spaceborne Thermal Emission and Reflection Radiometer Global Digital Elevation Model (ASTER GDEM2), which was released in 2011. Daily meteorological data from 2000 to 2014 recorded at nine weather station were provided by the China Meteorological Administration, and included precipitation, temperature, solar radiation, wind speed, and relative humidity. Daily streamflow and water quality data from 2002 to 2011 were obtained from the Yangtze Water Resources committee. Livestock farming and agriculture data were obtained from statistical and field survey data. Finally, the livestock and poultry breeding numbers from 2000 to 2015 were obtained from The Statistical Yearbook of Xingshan, 2000–2015.
Based on the collected data, the pollution characteristics of livestock and poultry were estimated, and Huangliang, Shuiyuesi, and Xiakou produced the most livestock pollutants [39]. The SWAT model was then used to delineate watersheds and analyze ANPS with a new manure database. Among the 27 sub–watersheds delineated within the entire watershed, sub–basins 12, 16, 11, 19, 20, 21, 22, 23, 24, 25, 26, and 27, which fell within the administrative boundaries of Huangliang, Shuiyuesi, and Xiakou, were selected as the research areas (Figure 1). Only land–use types involving farming, such as cultivated land, woodland, grassland, and paddy fields, were simulated by APEX. Based on the application of manure in different sub–basins, different management measures were applied. The pollutant load at the outlet of each basin was an annual average calculated from 14 years of data.

3. Results and Discussion

3.1. Characteristics of Respondents

Ninety valid questionnaires were obtained. The demographic characteristics of the survey showed that, among all the respondents, the number of females was nearly four times higher than the number of males (Table 3). Most respondents had been reeducated to primary school level (37%), and far fewer had been to junior college (4%). The respondents were mostly farmers, or local self–employed, aged between 30 and 70, with considerable farming experience. Among the sampled farmers, almost 50% raised some type of livestock or poultry.
The most common livestock and poultry feces treatment method in Xingshan County was rinsing and dry collection, accounting for 91% of all treatment methods (Figure 2a). Only a small number of farmers chose to let livestock and poultry live in the mountains without centralized manure treatment measures. Furthermore, most of the sewage generated by manure rinsing underwent no emission–reduction measures and was directly discharged into nearby canals that flow into the main river channel, posing a great threat to the environment. Most farmers directly returned the collected feces to their fields as organic fertilizer after undergoing natural fermentation, and only 23% of the respondents had a biogas digester (Figure 2b). The majority (64%) of the farmers buried sick and dead livestock and poultry (Figure 2c), while 24% of the farmers did not have any treatment measures for dead livestock and poultry—they directly threw dead animals into the mountain or nearby drainage ditches, spreading disease and increasing environmental pollution. Very few farmers had implemented incineration treatment.
Over half (64%) of the surveyed households did not know about the prevention and control of livestock and poultry pollution (Figure 2d). Those who knew or had heard a little about it accounted for 36% of the surveyed population, while none of the respondents understood pollution prevention and control very well. The majority of the surveyed farmers said that the village that they lived in did not have clear regulations regarding pollution from livestock and poultry breeding, and almost all of the surveyed farmers reported that they had not seen the villages or communities publicize the control of pollution from livestock and poultry farming.
The results showed that 58% of the surveyed farmers were willing to pay for pollution control measures for livestock and poultry breeding (Figure 2e). Over half of the farmers were willing to accept a fee of 10–20 yuan/month for controlling livestock breeding pollution. Another 33% of the farmers surveyed said they were unwilling to pay for the prevention and control of pollution from livestock and poultry. A small number of farmers (9%) said that they could be willing to pay, but the specific amount would be determined by the actual situation and the measures to be taken.
The level of environmental awareness and the understanding of environmental conservation in local communities is generally low. With urbanization and economic development, a growing number of rural people are working in cities. However, in the rural areas of China, women still frequently remain at home [55]. These women are typically poorly educated but play a significant role in the daily life and agricultural activities. Furthermore, they are more concerned with maintaining their livelihoods than environmental problems [56]. Some farmers may also be unaware of the damage caused by livestock and poultry pollution to the environment and impacts on agricultural production [28]. Furthermore, environmental protection measures in rural areas are inadequate. The environmental impact of livestock breeding has not attracted sufficient attention from local policy–making and environmental protection departments, and the prevention and control of livestock and poultry pollution have not been suitably publicized [57]. All these factors have contributed to the severe environmental problems in rural areas.
The awareness of farmers towards environmental pollution is gradually increasing. Regardless of the cost, over half of the surveyed farmers were willing to pay a fee for pollution prevention and control, even if they did not know what measures would be taken or how they could benefit from the adoption of BMPs. Farmers tended to accept off–farm pollution reduction practices and were particularly opposed to practices that occupied cultivated lands or changed the conventional planting methods [23]. However, the farmers were unaware of how severely livestock pollution affects their benefits [58]. Once they understood that livestock pollution influences their livelihoods and interests, most farmers were willing to pay a fee for pollution prevention and control, including on–farm and off–farm measures [27].

3.2. Factors Influencing Farmers’ Awareness of ANPS Pollution

The respondents’ awareness of NPS pollution is an important factor affecting their willingness to participate in pollution prevention and control activities. The results of the binary logistic regression model showed that two variables significantly affected the farmers’ understanding of NPS pollution, i.e., respondents’ education level and their satisfaction with the environment. However, the gender and age of the respondents did not significantly influence their understanding of pollution (Table 4). Farmers with a high educational level and low environmental satisfaction had a greater awareness of environmental pollution.
According to the survey, 50% of the respondents were satisfied with their living environment, 17% said they were not satisfied, and some said they were extremely dissatisfied. Among the farmers satisfied with their living conditions, only 39% held the opinion that there were environmental problems. However, up to 71% of farmers with an education level of high school or above had noticed the environmental problems. Furthermore, 60% had realized environmental pollution and were willing to pay for and participate in pollution control. Farmers regarded livestock and poultry farming and the decrease of forest vegetation due to sheep herding as the main causes of environmental problems, according to the survey.
The lack of awareness of the environmental impacts caused by livestock breeding and the insufficiency of relevant environmental protection measures were the major problems in local rural areas. Promotion from the government may be a significant incentive affecting the use of BMPs [23]. However, determining methods of improving the agricultural environment is not only interesting to government agencies, but also to the individual stakeholders involved [28]. Improving the farmers overall understanding of environmental protection will improve their participation in conducting BMPs and is important for resolving NPS pollution [59]. The government or local organizations could provide farmers with more education, training, and other assistance, such as agricultural extension services, to help them adopt BMPs [27]. Consistent publicity to arouse public interest in the issue of environmental protection is another method of raising the environmental awareness of farmers [60].

3.3. Environmental Benefits and Economic Analysis of BMPs

Based on the SWAT model, several related parameters were calibrated, and the results were validated. The R2 and NSE values for flow were 0.76 and 0.71, and those for phosphorus were 0.77 and 0.65, respectively [39]. The environmental benefits of several BMPs were then analyzed with the calibrated and validated SWAT model.
The amount of pollutants produced throughout the basin by applying each measure was below the simulated baseline (no BMPs were taken), indicating that pollution reduction measures were necessary for controlling NPS pollution (Figure 3). Various BMPs had little impact on the river’s flow during the simulation period, as the river flow value almost did not change (fluctuations were less than 0.01) before and after applying the measures. Among all BMPs, the application of a combined piping system and ponds significantly reduced sediment and nitrogen, and NO3 exhibited the highest reduction rate (above 40%). However, the phosphorus removal effect was not notable. BP–TWI, a combined piping system, exhibited the highest reduction rates, reducing NO3 by 40.6%, sediment by 6.2%, and TN by 5.6%. However, the removal of all pollutants by FB, LL, BP–ND, and dikes was not remarkable, and the reduction rates were all below 3%. BP–ND had the lowest effect on pollutant reduction, as the reduction rates were all below 0.03%.
Spatially, although the reduction effects of the combined piping systems were better than those of most single measures in each watershed, the reduction rate achieved by each BMP in the upstream areas was generally higher than that achieved in the downstream areas (Figure 4). Among all sub–basins, the reduction rates of almost all pollutants by most measures were highest in upstream sub–basin 16. However, each measure did not have a good effect on reducing pollutants at the outlet of sub–basin 27. In the three combined systems (BP–TWI, BP–DER, and BP–TSD), the reduction rate of NO3 reached approximately 90% in the upstream sub–basins, and the NO3 and sediment reduction percentages were up to 30% higher than those in the downstream sub–basins. However, the reduction rates achieved by single measures in the upstream regions were not as high as those of the combined measures, and the differences in the reduction rates between the upstream and downstream regions were not notable (ranging from 0.02% to 20%).
Economically, ponds were the least expensive measure among the eight BMPs (Table 5). The bedding and pipeline systems were also economical practices, and the cost of BP–TSD was the lowest among the piping systems (minimum of 90 yuan acre). Furthermore, the combined piping systems were cheaper than pipe laying alone. However, the prices of other single measures, such as filter belts and LL, are relatively high—the cost of LL is almost 3000 yuan acre. The economic benefits of piping systems are also remarkable as they reduce land occupation, improve soil conditions, and increase crop yields [61].
Considering the construction costs and environmental benefits of the BMPs, the combined BMPs (BP–DER and BP–TWI) and ponds were cost–effective measures for reducing NPS pollution in the study area. Combining ditches, reservoirs, and tailwater irrigation with ponds in a piping system may be an effective method of achieving the desired benefits and achieving high environmental effectiveness at a low cost.

3.4. Effectivity and Efficiency of BMPs

The simulated BMPs exhibited good nitrogen removal. The reduction of nitrogen (N) loads by BMPs such as tillage management was higher than the reduction of phosphorus (P) loads [7,62]. Furthermore, the tillage system did not appear to influence the TP content [63]. This may be because the nutrients (N and P) in animal manures were stored and recycled into farmlands in improved ditches, tailwater irrigation, and pond systems. Nitrate easily absorbs and accumulates in crops and vegetables in reuse systems [64,65], while the availability of phosphorous in the acidic soils of the Xiangxi River watershed is poor. Reusing rural domestic sewage to irrigate farmlands can improve the crop yield while efficiently removing pollutants [66]. Using the nutrients in waste by combining water management with fertilization in agriculture is a useful, efficient, and sustainable method of reducing pollution.
When assessing the practical application of pollution–reduction measures, the maintenance costs, landowner opportunity costs (compensation for returning farmlands to forests or the construction of BMPs), agricultural production, and ecological effects must also be considered to quantify the long–term benefits of BMPs implemented in the watershed [7]. The cost–effectiveness and cost–benefit ratios of BMPs for reducing pollution were calculated to further ensure economic returns for five to ten years after their implementation [7,29].
The effectivity and efficiency of BMPs are closely related to the spatial allocation. The efficiency of a BMP is likely to vary between different locations within a watershed [67,68]. Pollutants tend to accumulate downstream due to the topography and erosion by rainfall runoff [69]. Therefore, it is beneficial to consider the upstream–downstream linkages during the construction of BMPs and other infrastructure to ensure that the pollution–reduction measures perform well [70]. Good catchment management practices for protecting the ecological environment in the upstream region can provide with downstream communities high–quality water resources, such as clean and sustainable water [71]. Spatially optimizing BMPs is an effective method of selecting and allocating BMPs for watershed management [39,72]. Optimizing the selection and placement of BMPs was found to triple their cost–effectiveness in comparison to targeting strategies for ensuring the same level of protection based on the maximum monthly sediment, phosphorus, and nitrogen loads [67].
The inclination of farmers towards accepting BMPs also needs to be considered. As they are important participants in agricultural activities, the involvement of farmers directly affects the implementation effectivity and efficiency of BMPs [73]. The more knowledge farmers have about NPS pollution and the better their awareness of environmental pollution, the easier it is for farmers to facilitate the implementation of BMPs [74]. Implementing BMPs can improve the environment and also increase the long–term local economic benefits [7,75,76]. The peer effect would also influence farmers’ choices, as BMPs are more likely to be adopted by farmers whose peer networks support and promote such practices [77]. Furthermore, BMPs that are more familiar, simple, and can be easily integrated into existing management practices are more likely to be adopted [59].
The selection and implementation of BMPs is critical to a regional environment [78]. Suitability for local conditions and general acceptability are issues need to be considered [27]. Decision makers need to coordinate multi–interest among the stakeholders and emphasize stakeholder consultation to meet local stakeholders’ needs [79]. It is advisable to provide more space for public participation in addressing environmental issues [80]. Cash incentives such as payments or subsidies will motivate farmers to adopt BMPs. In addition to education and publicity, attention should also be paid to technical support and extension services, such as guidance and assistance, to give farmers sufficient knowledge and technical skills to apply designed measures [81].

4. Conclusions

In Xingshan County, farmers’ environmental awareness and understanding of environmental conservation are generally low. Most of the surveyed rural households had little understanding of the prevention of livestock pollution, and the propaganda about public knowledge regarding the control of livestock breeding pollution was inadequate. However, farmers are gradually becoming aware of environmental pollution. Most villagers were willing to bear the corresponding costs for minimizing livestock pollution within an affordable range. The farmers’ education level and satisfaction with the environment significantly affected their awareness of ANPS pollution, according to the results of the Binary Logistic model. Farmers with a high educational level and low environmental satisfaction were better aware of environmental pollution. Therefore, financial incentives or economic subsidies, intensive education efforts, and consistent publicity also need to be established to improve the farmers’ overall environmental protection consciousness to further encourage their involvement in implementing BMPs.
The environmental benefits of BMPs were analyzed with a calibrated and validated SWAT model. Among all selected BMPs, the application of combined piping systems and ponds significantly reduced the levels of pollutants, with NO3 reduction rate exceeding 40% throughout the basin. In contrast, the effect on phosphorus removal was not notable. The construction costs of combined piping systems and ponds were also relatively low. Upon considering the construction costs and environmental benefits of the BMPs, the combined BMPs (BP–DER and BP–TWI) and ponds were the most cost–effective measures for reducing non–point source pollution in the study area. Spatially, the reduction effect was more notable in the upstream area than the downstream area. The reduction rate of NO3 by three combined systems (BP–TWI, BP–DER, and BP–TSD) reached approximately 90% in upstream sub–basins, which is 30% higher than that in downstream areas. However, the reductions achieved by single measures in the upstream area were not as significant as those achieved by the combined measures, and the differences in the reduction rates between the upstream and downstream were not notable.
Ensuring and improving the effectivity and efficiency of BMPs is vital for reducing ANPS pollution. Combining cost–effective BMPs with the local situation can improve the environmental situation. As farmers are the main stakeholders of BMPs and should be involved, the factors influencing their choices and determining approaches to encourage their participation must be explored. Under governmental impetus, improving farmers’ awareness of environmental protection and further encouraging them to adopt cost–effective BMPs can achieve desirable benefits.

Author Contributions

Conceptualization, R.L. and Y.M.; methodology, R.L.; Q.W. and Y.M.; software, Q.W.; validation, R.L.; Q.W. and Y.M.; investigation, Y.M.; L.J.; Y.W.; Q.W.; L.L. and L.C.; writing—original draft preparation, Y.M.; writing—review and editing, R.L.; visualization, Y.M.; supervision, R.L.; project administration, R.L.; funding acquisition, R.L. All authors have read and agreed to the published version of the manuscript.

Funding

This study was funded by the National Natural Science Foundation of China (41571486), the National Key Research and Development Program of China (2017YFA0605001) and the Interdisciplinary Research Funds of Beijing Normal University.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

No additional data are available. All data generated or analysed during this study are included in this published article.

Acknowledgments

The authors thank the editors and anonymous reviewers for their valuable comments and suggestions.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. The map of study area.
Figure 1. The map of study area.
Water 13 00985 g001
Figure 2. Questionnaire statistical results;(a) The main processing method for excrements. (b) Fecal reduction technique. (c) Processing for the dead livestock. (d) How familiar the farmers with livestock control. (e) The fees willing to pay for livestock.
Figure 2. Questionnaire statistical results;(a) The main processing method for excrements. (b) Fecal reduction technique. (c) Processing for the dead livestock. (d) How familiar the farmers with livestock control. (e) The fees willing to pay for livestock.
Water 13 00985 g002aWater 13 00985 g002b
Figure 3. The comparison between the baseline and the scenarios. (Flow unit: kg/m3; Sediment unit: t; Pollutants unit: kg).
Figure 3. The comparison between the baseline and the scenarios. (Flow unit: kg/m3; Sediment unit: t; Pollutants unit: kg).
Water 13 00985 g003
Figure 4. Pollutants percentage changes between the baseline and the scenarios in different subbasins; (a) Filter belt. (b) Land levelling. (c) Bedding and piping system-ditch expansion and reservoir. (d) Bedding and piping system-no ditch improved. (e) Bedding and piping system-tail water irrigation. (f) Bedding and piping system-two stage ditches. (g) Permanent dams. (h) Ponds.
Figure 4. Pollutants percentage changes between the baseline and the scenarios in different subbasins; (a) Filter belt. (b) Land levelling. (c) Bedding and piping system-ditch expansion and reservoir. (d) Bedding and piping system-no ditch improved. (e) Bedding and piping system-tail water irrigation. (f) Bedding and piping system-two stage ditches. (g) Permanent dams. (h) Ponds.
Water 13 00985 g004aWater 13 00985 g004b
Table 1. Variable descriptive statistics in Binary Logistic regression model.
Table 1. Variable descriptive statistics in Binary Logistic regression model.
VariablesDescriptionMean ValueStandard Deviation
dependent variable
farmers cognitionhave recognized (=1);
have not recognized (=0)
0.580.497
independent variables
Sexmale (=1); female (=2)1.770.425
Age24~8352.1812.463
educationUneducated (=1); primary school (=2);
middle school (=3); high school (=4);
College degree or above (=5)
2.581.112
workFarmer (=1); worker (=2);
self–employed (=3); others (=4)
1.981.18
environmental satisfactionrather dissatisfied (=1); dissatisfied (=2);
normal (=3); satisfied (=4); Rather satisfied (=5)
3.310.843
Table 2. Scenarios management setting in SWAPP.
Table 2. Scenarios management setting in SWAPP.
ScenariosSpecific Measures
FBSelect vegetation type, planting width and removal rate
LLSet the slope reduction percentage
BP–NDILay straws and pipelineSet bedding and pipe width
BP–DERSet bedding, pipe width and reservoir area
BP–TWISet bedding, pipe width and reservoir area; add automatic irrigation
BP–TSDSet bedding and pipe width
Permanent dikesNo special setting
Ponds Set the ratio affected by the pond
Table 3. Demographic characteristic of surveyed respondents.
Table 3. Demographic characteristic of surveyed respondents.
VariableOptions of VariablePercentage (%)
Sexmale23
female77
Agebelow 306
31–5038
51–7052
over 704
Professionworker6
farmer56
Self–employed24
others14
Educationno education17
primary school37
middle school23
high school19
college degree or more4
Table 4. Estimation results of factors influencing farmers’ cognition to environmental pollution.
Table 4. Estimation results of factors influencing farmers’ cognition to environmental pollution.
BS.E.WalsdfSig.Exp(B)
Education0.4370.2184.00910.0451.549
Satisfaction–1.2450.35312.45410.0000.288
Constant3.4351.3436.54710.01131.038
Table 5. Construction costs of BMPs.
Table 5. Construction costs of BMPs.
MeasuresConstruction Cost
(Yuan Acre)
FT607–1214
LL1278–2904
BP–DER140–370
BP–NDI121–387
BP–TWI145–465
BP–TSD90–290
Permanent dikes
Ponds80–140
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Liu, R.; Miao, Y.; Wang, Q.; Jiao, L.; Wang, Y.; Li, L.; Cao, L. Effectivity and Efficiency of Best Management Practices Based on a Survey and SWAPP Model of the Xiangxi River Basin. Water 2021, 13, 985. https://doi.org/10.3390/w13070985

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Liu R, Miao Y, Wang Q, Jiao L, Wang Y, Li L, Cao L. Effectivity and Efficiency of Best Management Practices Based on a Survey and SWAPP Model of the Xiangxi River Basin. Water. 2021; 13(7):985. https://doi.org/10.3390/w13070985

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Liu, Ruimin, Yuexi Miao, Qingrui Wang, Lijun Jiao, Yifan Wang, Lin Li, and Leiping Cao. 2021. "Effectivity and Efficiency of Best Management Practices Based on a Survey and SWAPP Model of the Xiangxi River Basin" Water 13, no. 7: 985. https://doi.org/10.3390/w13070985

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