Assessing Ecosystem Services of Rice–Fish Co-Culture and Rice Monoculture in Thailand

: Increasing production costs for rice monoculture and concerns about farming households’ food security have motivated farmers to adopt integrated rice–ﬁsh farming. To date, there has been little research that comparatively assesses the ecosystem services (ESVs) of both rice–ﬁsh co-culture and the rice monoculture system in Thailand. Therefore, this study aims to estimate the ESV values of these systems based on the Millennium Ecosystem Assessment. A total of 19 rice–ﬁsh co-culture farms were investigated, covering three regions of Thailand (northern, northeastern, and central regions) and consisting of 13 sub-districts, 13 districts, and 11 provinces. For a fair comparison, 19 conventional rice farms were selected as comparison sites. Rice–ﬁsh co-culture had a higher net ESV value of 48,450,968.4 THB ha − 1 year − 1 than rice monoculture with a net ESV value of 42,422,598.5 THB ha − 1 year − 1 . Rice–ﬁsh co-culture generated average economic values 25.40% higher than in rice monoculture farming. The most positive change in ESV was found in the regulation of temperature and humidity, with 3,160,862.9 THB ha − 1 year − 1 . Moreover, agrotourism can generate revenue and increase the ESV in rice–ﬁsh co-culture. Our ﬁndings showed that rice–ﬁsh co-culture gives more economic and ecological beneﬁts compared to the rice monoculture system. Further studies are recommended to explore and analyze the potential advantages of the rice–ﬁsh system in more detail.


Introduction
Rice is the primary source of nutrition for approximately two-thirds of the world's population [1], which accounts for up to 75% of the daily calorie intake of people in some Asian countries [2].It is projected that the world population will require 560 million tons of rice by 2035, which increased to around 120 million tons after 2010 [3].With 11.17 million harvesting hectares, 21.3 million tons of rice were produced in the crop year 2020/2021, making Thailand the world's 6th largest rice producer after China, India, Bangladesh, Indonesia, and Vietnam [4].However, future food security and the precarious livelihood of poor people are great challenges for rice farming.
The rice-fish co-culture system is a solution to improve the functioning of ecosystems and alleviate farmers' poverty in many locations [5].Rice yields from modern monoculture rice are not realistically sustainable due to falling yields from reduced soil fertility and pest problems [6], and the detrimental environmental effects of intense fertilization and pesticide use have now been properly addressed.According to previous studies, the ricefish co-culture system can efficiently reduce the use of pesticides and herbicides [7], as well as the amount of nitrogen consumed and absorbed by rice plants and fish [8][9][10].Despite the environmental benefits of the rice-fish co-culture system, their adoption is extremely low.In Asian countries, e.g., Bangladesh [11], China [8], Malaysia [12], and Vietnam [13], the adoption rate is only marginally greater than 1% [5].
Integrated rice and fish farming has been conducted in Thailand for more than 200 years [13].Capturing wild fish seed for stocking rice fields was necessary in the beginning.The Department of Fisheries (DOF) began to promote rice-fish production in the 1940s by providing fish seed and improving technology.The central plains saw a boom in rice-fish farming, with fish yields ranging from 137 to 304 kg ha −1 crop −1 [13].Rice yields increased by 25 to 30% in fields that included fish.In the 1970s, however, the introduction of high-yielding rice varieties, as well as increasing fertilizer and pesticide applications, led to the near collapse of rice-fish farming in Thailand's central plains.Farmers had two options: separate their rice and fish operations or stop raising fish [13].Currently, increasing production costs for rice cultivation (e.g., chemical fertilizers, insecticides, and herbicides) and concern for farming households' food security have motivated farmers to adopt integrated rice-fish farming due to its lower cost, higher economic returns, and additional food source.However, the number of rice-fish farms in Thailand remains low.Furthermore, integrated rice and fish farming is an organic agriculture system that the Thai government initially practiced in the 1980s.It has been promoted to persuade and subsidize farmers to adopt organic farming based on the philosophy of the late King Bhumibol Adulyadej as "sufficiency economy".There were only 2500 organic farmers in 2003, and this number increased to 44,418 organic farmers in 2019 [14,15], which accounted for only 0.003% of the total farmers in Thailand [16].To increase the number of organic farmers, proactive policies need to be focused specifically on rice-fish co-culture farming; thus, comprehensive research is required.
To comprehensively understand the ecological and economic benefits, ecosystem services (ESVs) are widely considered appropriate quantitative and qualitative assessment methods.Following the Millennium Ecosystem Assessment, ESVs are defined as "the benefits people obtain from ecosystems" [17].ESVs are classified into four types, namely cultural, provisioning, regulating, and supporting services [18], which connect ecological and sociological values for policy implications and decision making.ESVs are widely used and have achieved scientific results in rice-fish farming [8,[19][20][21][22].To date, there has been little research that comparatively assesses the rice-fish co-culture and rice monoculture systems in Thailand.Therefore, the objective of this study was to determine the ESV values of rice-fish co-culture and rice monoculture (conventional rice farming) in Thailand and to propose policy implications based on key findings to support government policy and decision making.

Study Sites and Description
The number of rice-fish co-culture farms in Thailand is very small, and there is no official record of the location and number of rice-fish co-culture farms.Thus, a purposive sampling method was used to select the farms.There were two criteria for rice-fish coculture farm selection in this study: (1) the rice-fish co-culture farm must practice organic rice farming and feed fish in the paddy fields without using any chemical substances, and (2) the rice-fish co-culture farm must have practiced rice-fish co-culture for at least 2 years.Based on our survey in the crop years 2020 and 2021, 19 rice-fish co-culture farms were selected, and the data investigated.These farms covered three regions of Thailand (northern, northeastern, and central regions), consisting of 13 sub-districts, 13 districts, and 11 provinces (Table 1).For a fair comparison, 19 conventional rice farms were selected as comparison sites.These conventional rice farms were located near the rice-fish co-culture farms in each sub-district to avoid variations in soil texture, microclimate, and irrigation conditions (Table 1).Based on the 19 rice-fish co-culture farms in this study, two field types of rice-fish co-culture were identified, namely the canal refuge (Figure 1a) and pond refuge (Figure 1b).'Khao Dawk Mali 105' (KDML 105), 'RD 6', and 'San Pah Tawng 1' varieties were found to be grown in paddy fields once a year.The transplanting method was used for planting, while harvesting was done by hand.The main species of farmed fish raised in the paddy fields were Nile tilapia (Oreochromis niloticus), Common snakehead (Channa striata), Common carp (Cyprinus carpio), Common silver barb (Barbonymus gonionotus), Mrigal carp (Cirrhinus cirrhosus), Seven-stripped carp (Probarbus jullieni), and Walking catfish (Clarias batrachus (Linnaeus)).Organic materials (rice husk, rice bran, pig manure, cattle manure, poultry manure, fruits and vegetables) were applied in the paddy fields to provide nutrients for rice and food for the fish.
found to be grown in paddy fields once a year.The transplanting method was used for planting, while harvesting was done by hand.The main species of farmed fish raised in the paddy fields were Nile tilapia (Oreochromis niloticus), Common snakehead (Channa striata), Common carp (Cyprinus carpio), Common silver barb (Barbonymus gonionotus), Mrigal carp (Cirrhinus cirrhosus), Seven-stripped carp (Probarbus jullieni), and Walking catfish (Clarias batrachus (Linnaeus)).Organic materials (rice husk, rice bran, pig manure, cattle manure, poultry manure, fruits and vegetables) were applied in the paddy fields to provide nutrients for rice and food for the fish.

Data Collection
Data on farm management practices in the two crop years (2019/2020 and 2020/2021) were collected from the owners of the rice-fish co-culture and conventional rice farms.The quantitative data were recorded from each farm, including rice field area, rice yield, fish yield, height of field ridge, volume of circular furrow, number of days of flooding in the field, annual irrigation volume, total number of tourists, and residence time.Moreover, the unit prices of rice, fish, and pesticides, reservoir engineering fee usage, water supply, and money received from tourism were recorded.

Ecosystem Service Value Evaluation Method
The Common International Classification for Ecosystem Services (CICES) version 5.1 (2018) was used [23] in this study.Based on the definition of ecosystem services in CICES version 5.1 (2018), Liu et al. [21] and Liu et al. [24] designed 23 ESV indicators and 3 sections (provisioning, regulation and maintenance, and cultural) (Table 2).Due to the lack of relevant studies in Thailand and limited data availability, 13 of the 23 indicators were applied in this study (Table 2).
Following The Economics of Ecosystems and Biodiversity (TEEB) method [25,26], three categories were widely used to express the ESVs in monetary units: the direct market method, equivalent factor method, and replacement costs method [27].In this study, the direct market method was used to evaluate the "provisioning services", while the simulated market method was used to estimate the "development of tourism".Finally, the other ecosystem services were assessed based on the alternative market method.Based on Liu et al. [24], the formulas for calculating ESVs are presented below.

Provisioning Services
Rice and fish generate income for farmers depending on the yield and market prices.
where V 1 is the total income of primary products from paddy fields (THB ha −1 year −1 ); Y rice is rice yield (ton ha −1 ); P rice is the price of rice (THB ton −1 year −1 ); Y fish is the yield of fish (ton); and P fish is the price of fish (THB ton −1 year −1 ).

Gas Regulation
Rice farming regulates gases in the atmosphere by absorbing CO 2 and releasing O 2 through photosynthesis.
where V 2 is the value of gas regulation from paddy fields (THB ha −1 ), E CO 2 is the value of CO 2 fixed by rice (THB), Y Nrice is the net rice yield (ton ha −1 ), α is the amount of CO 2 fixed for 1 g of rice dry matter (1.63 g [24]), C CO 2 is the carbon content in CO 2 (27.27% [24]), C STR is the Swedish carbon tax rate (133.26USD ton −1 CO 2 on 1 November 2020 [28]), E O 2 is the value of rice-released O 2 (THB), ϕ is the amount of O 2 produced for 1 g of rice dry matter (1.19 g [24]), O cost is the cost of industrial oxygen production (2092 THB ton −1 O 2 , converted from Xu et al. [22]), Y rice is rice yield (ton ha −1 ), m is the moisture content of rice, and β is economic coefficient of rice (0.5 [24]).

Temperature and Humidity Regulation
Crop evapotranspiration and water evaporation in paddy fields can regulate heat and humidity in surrounding areas.
where V 3 is the value of temperature and humidity regulation from paddy fields (THB ha −1 ), W EV is the average daily water evaporation in the rice field (4.4 mm day −1 , generated using the CROPWAT 8.0 model), H DS is the number of hot days in summer in the study area (days; obtained from the Thai Meteorological Department), η is the heat consumption for evaporating 50 mm of water in 1 ha of rice field (equal to burning 30.57tons of coal) [24], and P Coal is the price of standard coal (THB ton −1 ).

Air Purification
Rice field ecosystems can purify the air by absorbing harmful gases (e.g., SO 2 , NO x , HF, and dust) in the atmosphere.
where V 4 is the value of air purification from paddy fields, A SO2 , A NOX , A HF , and A D are the average annual flux (kg) of SO 2 , NO x , HF, and dust absorbed by the paddy fields, respectively.Based on Ma et al. [29], the average annual flux of SO 2 , NO x , HF, and dust was 45.0, 33.3, 0.57, and 33,200 kg ha −1 year −1 , respectively.P SO 2 , P NO X , P HF , and P D are the costs of SO 2 , NO x , HF, and dust in the rice field, respectively (THB kg −1 ).In this study, the costs of SO 2 , NO x , HF, and dust in the rice field were 7.53, 3.97, 4.34, and 0.94 THB kg −1 , respectively, which were converted from Ma et al. [29].

Pest Control
Fish can help reduce the weeds and pests in paddy fields by consuming them, resulting in a reduced demand for pesticides and herbicides.
V 5 = P p × R where V 5 is the value of pest control from paddy fields (THB ha −1 year −1 ); P p is the average pesticide cost for the rice monoculture system (THB ha −1 year −1 ); and R is the percentage of reduction in pesticide use for rice-fish co-culture.

Increase in Fauna Diversity and Microorganisms
Fish can control weeds and pests, which helps reduce the use of herbicides, pesticides, and chemical fertilizers, leading to increased species diversity.
where V 6 is the value of increase of fauna diversity and microorganisms from paddy fields (THB ha −1 year −1 ), τ is the value-equivalent factor of the rice field ecosystem (0.21, [30]), and V P is the equivalent product provisioning service (THB ha −1 year −1 ).

Maintaining Soil Nutrients
Paddy fields are sources of GHG emissions, especially CO 2 and CH 4 , whereas rice fields are sink pools of carbon through soil carbon sequestration.
where V 7 is the value of maintaining soil nutrient value from paddy fields (THB ha −1 year −1 ); P OM is the price of organic materials (7.69 THB kg −1 C, converted from Liu et al. [24]); IN OM is the organic matter input from soil (kg C ha −1 year −1 ); OU OM is the output amount of soil organic matter (kg C ha −1 year −1 ); R CO 2 is the amount of CO 2 emissions from rice fields (2123.63kg ha −1 year −1 , [24]); R CH 4 is the amount of CH 4 emissions from rice fields (29.64 kg ha −1 year −1 , [24]); the constant values of 0.27 and 0.75 are the conversion coefficients of CO 2 and CH 4 into carbon, respectively; N r and N s are the biomass of the rice root system and straw (kg ha −1 year −1 ), respectively; and C r and C s are the carbon content of the rice root system and straw (%), respectively.
In this study, a quadrat (1 m × 1 m) was used to randomly collect rice straw and rice roots with three replications from each field.Rice straw and rice roots were separated in the field and then put into plastic bags for laboratory analysis.The dry mass of rice straw and rice roots were determined after oven drying at 80 • C for 48 h.According to Ma et al. [31], the carbon content in rice straw and rice roots in this study was assumed to be 43.26% and 38.20%, respectively.

Water Conditions
Rice cultivation requires large amounts of water, mainly from rainfall, surface water, and groundwater.Moreover, paddy fields can provide water storage by storing rainwater on the surface and maintaining groundwater.
where V 8 is the value of water conditions from paddy fields (THB ha −1 year −1 ), E WS is the value of the water storage function of the rice system (THB ha −1 year −1 ), E GW is the value of groundwater conservation (THB), H R is the average height of the field ridge, V CF is the volume of a circular furrow, A is the area of the rice field, P RE is the unit price of the reservoir engineering fee usage (THB m −3 ), S WP is the soil water permeability in the rice field (6 mm, [24]), P WT is the market price of water (THB m −3 , obtained from Provincial Waterworks Authority), and D FL is the average days of flooding in the rice growing period (days).

Energy Losses for Irrigation
During the rice-growing period, maintaining the water level in the paddy field is very important, especially in rice-fish co-culture systems.However, water from rainfall may not be sufficient for rice cultivation throughout the growing period.Therefore, energy is required for pumping and lifting irrigation water from irrigation canals and groundwater.
where V 9 is the value of energy losses from paddy fields (THB ha −1 year −1 ), E IRR is the average annual irrigation per area (m 3 ha −1 year −1 ), and P WS is the cost of the water supply in lifting irrigation (THB m −3 ).

Gas Regulation
The mean value of the regulation service for CO 2 fixation from photosynthesis was 358,092.2THB ha −1 year −1 in the co-culture system, whereas the monoculture system earned 456,106.6 THB ha −1 year −1 .The annual decline in ESV can be seen in this regulation service.The O 2 released from photosynthesis in the two systems contributed to 14,697.9 and 18,720.9THB ha −1 year −1 .A decrease of 4023.0THB ha −1 year −1 per annum was observed when evaluating the ESV in this service.The paddy fields absorb SO 2 , NOx, HF, and dust, and this regulation service generates revenue of 31,681.5 THB ha −1 year −1 in the co-culture system and 31,681.5 THB ha −1 year −1 in the monoculture system (Table 3).

Nutrient Cycling and Organic Accumulation, and Reduction of GHG Emissions
The calculation of ESV from the ecosystem service related to nutrient cycling, organic accumulation, and reduction of GHG emissions was 23,798,852.3THB ha −1 year −1 in coculture and 21,678,588.0THB ha −1 year −1 in monoculture.Remarkably, approximately half of the total ESV comes from this service in both systems.A significant annual increase in ESV was also found in this service (Table 3).This is because the biomass and carbon content in rice straw and roots of the rice-fish co-culture farms were higher than in rice monoculture.

Pesticide and Herbicide Reduction
Reducing the use of pesticides and herbicides enhances ecosystem services in several ways.The rice-fish co-culture system obtained an ESV of 937,500.0THB ha −1 year −1 , while an annual ESV of approximately 187,500.0THB ha −1 year −1 was received in the rice monoculture system.Moreover, the increase in ESV in this category was estimated to be 750,000.0THB ha −1 year −1 (Table 3).Organic rice farming practiced in rice-fish co-culture does not require the application of chemical substances, leading to lower production costs and a reduction in environmental pollution.

Regulation of Temperature and Humidity
The valuation of the ecosystem service related to the regulation of temperature and humidity of rice-fish co-culture and rice monoculture systems resulted in 23,179,661.4THB ha −1 year −1 and 20,018,798.5 THB ha −1 year −1 , respectively.This service generates nearly half of the total ESV in both systems.Furthermore, a significant increase in the annual ESV was notable, as rice-fish culture developed in an area (Table 3).

Increase in Fauna Diversity and Microorganisms
Increasing fauna diversity and microorganisms can improve the performance of ecosystem services.An ESV of 10,584.0THB ha −1 year −1 was received from the co-culture and 7896.0THB ha −1 year −1 from the monoculture.The ESV has risen annually by 2688.0THB ha −1 year −1 (Table 3).Due to the higher provisioning services in rice-fish co-culture than rice monoculture, the ESV of fauna diversity and microorganisms increased.This demonstrates that avoiding the use of pesticides and herbicides can increase biodiversity in paddy fields.

Increase in Water Storage
The rice-fish co-culture system gained 16,682.3 THB ha −1 year −1 from this service, while the monoculture system earned 6341.9 THB ha −1 year −1 .The yearly increase in ESV was noteworthy (Table 3).Under the rice-fish co-culture system, the value of the water storage function increased due to the high volume of water stored on the surface, as well as the long period of flooding during the rice-fish growing period.

Groundwater Conservation
Groundwater conservation in co-culture and monoculture contributes 13,992.0 and 1017.6 THB ha −1 year −1 , respectively, with an annual increase of ESV 4452.0THB ha −1 year −1 (Table 3).A longer period of flooding in rice-fish co-culture fields means that more groundwater can be stored through percolation and infiltration.

Energy Losses in Lift Irrigation
As a negative ESV, the valuation of energy losses in lifting irrigation was 14,175.2THB ha −1 year −1 in the co-culture and 2115.0THB ha −1 year −1 in monoculture.In this category, an ESV decrease of 9952.8THB ha −1 year −1 occurred due to the development of rice-fish culture.Based on the field survey, most farmers used fossil fuel (diesel) for pumping water into paddy fields, while a few farms installed solar panels and used solar energy for water management in their fields.Using solar energy can reduce 19.5% of the energy cost compared with diesel fuel.

Cultural Services Development of Tourism
Agrotourism is becoming increasingly popular in rice-fish regions.According to the farmers who participated in the survey, approximately 53 tourists were attracted by rice-fish activities in 2020-2021.Each tourist spends one day, and their average expenditure is 1000 THB.Therefore, the tourism contribution value of the rice-fish system was 53,000.0THB ha −1 year −1 (Table 3).Most of the visitors came to see the rice-fish co-culture and gain knowledge and experiences, and the rest visited to buy organic rice and fish products.Integrated rice and fish have been recommended as a sustainable strategy for improving soil nutrient status and water resources, which provide carbohydrates and proteins to humans and reduce environmental pollution [8,32].Moreover, the rice-fish co-culture system can alleviate local farmers' poverty and enhance social welfare [11,33].When comparing the two systems in the current study, the rice-fish co-culture system has a higher net ESV value of 48,450,968.4THB ha −1 year −1 (Table 3).In addition, rice-fish co-culture generated average economic values 25.40% higher than rice monoculture farming (Table 3).The regulation services that occupied the largest portion of total ESV were nutrient cycling and organic accumulation, reduction of GHG emissions, and regulation of temperature and humidity (Figure 2).In contrast, the contributions of the remaining ESVs were not significant, and only a small portion of the net value was received from these services (Figure 2).Developing rice-fish co-culture has positive effects on provisioning services, as co-culture contributes to the increase of ESV in the area.Regarding gas regulation services, the benefits of the co-culture system cannot be seen in CO 2 fixation and O 2 release from photosynthesis.This is because rice yields from rice-fish co-culture farms were mostly lower than in the rice monoculture system.Furthermore, there was no significant change in the ESV of the two systems regarding SO 2 , NOx, HF, and dust absorbed by the paddy field.
The most significant positive change in ESV can be seen in the regulation of temperature and humidity with 3,160,862.9THB ha −1 year −1 (Table 3).The service related to nutrient cycling and organic accumulation, and reduction of GHG emissions, takes second place in contributing to the improvement of ecosystem services (Figure 2).Paddy fields have the potential to improve soil physical and chemical properties, increase soil organic carbon, and mitigate CO 2 emissions in the atmosphere [21,34,35].Increasing fauna diversity, microorganisms (bacteria, protozoa, algae, and fungi), and water storage, as well as groundwater conservation, make minor contributions to the increase in net ESV.These are in line with the studies of Nayak et al. [36] and Ren et al. [37], who reported that rice-fish co-cultures maintain the genetic diversity of aquatic organisms in paddy fields due to the reduction in the use of pesticides, insecticides, and chemical fertilizers.Wan et al. [38] found that finless eel and loach rice-fish co-cultural practices in China can help reduce the abundance of pests, leading to lower use of pesticides and a reduction in labor costs.This is consistent with our study, which found that even though the rice-fish co-cultural farms in our study areas practiced organic rice farming, the yields of organic rice were high, and there were fewer pests and diseases as well as weeds.This is because fish excrement can improve soil nutrients, and fish consume insects in paddy fields, while the water level can control the abundance of weeds.This is similar to the study of Xie et al. [8], which found that the level of water in paddy fields can reduce the abundance of rice planthoppers.Wan et al. [38] also found that the abundance of herbivore insects decreased by 24.07%, weed abundance was reduced by 67.62%, and invertebrate predator abundance increased by 19.48%.
Although agrotourism can generate revenue and increase the ESV, its proportion in the total value is not significant.However, tourists are interested in visiting rice-fish farming areas but not traditional monocultures.This means that the co-culture system has the potential to receive a higher ESV from this cultural service.Tourism can have direct benefits for farmers by creating marketing opportunities to sell their products to tourists [39] and may provide additional income to farmers from other agricultural activities, such as developing creative tourism, which provides a true experience of connection for tourists.
Although agrotourism can generate revenue and increase the ESV, its proportion in the total value is not significant.However, tourists are interested in visiting rice-fish farming areas but not traditional monocultures.This means that the co-culture system has the potential to receive a higher ESV from this cultural service.Tourism can have direct benefits for farmers by creating marketing opportunities to sell their products to tourists [39] and may provide additional income to farmers from other agricultural activities, such as developing creative tourism, which provides a true experience of connection for tourists.

Policy Implications
Although integrated rice and fish farming has been practiced in Thailand for a long time, in recent years, the number of farms has been small, and the trend is declining.This is due to the intensification and modernization of rice cultivation focusing on maximizing yield, and urbanization involving converting paddy fields to commercial building and industrial factories.In addition, the impact of climate change is causing changes to the

Policy Implications
Although integrated rice and fish farming has been practiced in Thailand for a long time, in recent years, the number of farms has been small, and the trend is declining.This is due to the intensification and modernization of rice cultivation focusing on maximizing yield, and urbanization involving converting paddy fields to commercial building and industrial factories.In addition, the impact of climate change is causing changes to the seasons and increasing the frequency and intensity of flood and drought events.Based on in-depth interviews, drought was the main cause of loss of rice and fish yields on farms in the northeastern region, while flooding caused damage in the northern and central regions.This indicates that rice-fish co-culture farming answers these challenges in Thailand.
The results demonstrated that rice-fish co-culture provides nutrient cycling and organic accumulation, reduction of GHG emissions, and regulation of temperature and humidity for the ecosystem (Table 3 and Figure 2).At the same time, rice-fish co-culture provides safe foods (rice and fish) and extra income for the farmers' households, implying that Thailand has great potential to be a rice-fish co-culture society because rice and fish are part of the ancestral food culture for Thai people.It is obvious that rice-fish co-culture could address more than one sustainable development goal (SDG), such as SDG 2 (zero hunger), SDG 12 (responsible consumption and production), SDG 13 (climate action), and SDG 14 (life below water).Therefore, policy implications should implement the following strategies to promote and support rice-fish co-culture: (1) develop innovation for better irrigation systems to reduce the impact from flood and drought events, (2) support the quantity of fish seed to increase the number of fish seed survival after release into paddy fields, (3) promote community learning centers for rice-fish co-culture to establish the farmer school, (4) strengthen the new innovative technology for pests and diseases control, (5) work as multi-stakeholders (farmer-officer-businessman-scholar), and (6) develop and promote the unique selling points of rice-fish co-culture, which are organic rice, organic fish, and destinations for travel.These strategies can help ensure the sustainability of the agricultural, environmental, and economic aspects of rice-fish co-culture in Thailand.

Conclusions
The rice-fish co-culture system has benefits for sustainability and ecology.At the same time, it must compete with commercial and advanced agricultural systems.Our findings showed that the rice-fish system provides more economic and ecological benefits than the rice monoculture system.The rice-fish co-culture system has a higher net ESV value of 48,450,968.4THB ha −1 year −1 than rice monoculture (net ESV 42,422,598.5 THB ha −1 year −1 ), which generated average economic values 25.40% higher than rice monoculture.The most positive change in ESV can be seen in the regulation of temperature and humidity, with 3,160,862.9THB ha −1 year −1 .Services related to nutrient cycling and organic accumulation, and reduction of GHG emissions take second place in contributing to the improvement of ecosystem services.Further studies are recommended to explore and analyze the potential advantages of the rice-fish system in more detail.

Figure 1 .
Figure 1.Rice-fish co-culture field type: (a) canal refuge and (b) pond refuge.Note: The refuges in our study sites were heterogeneous in size (depth and width).

Figure 1 .
Figure 1.Rice-fish co-culture field type: (a) canal refuge and (b) pond refuge.Note: The refuges in our study sites were heterogeneous in size (depth and width).

1 .
Ecosystem Service Value of the Rice-Fish Co-Culture System

Table 1 .
Description of study areas.
Note: X represents ecological services that were not considered in this study due to no data available for calculation.

Table 3 .
Ecosystem service values of rice-fish co-culture and rice monoculture systems during 2020-2021.