Abstract
Agricultural heritage systems have great advantages in clean production, because they well maintain productivity while having low environmental impacts. However, as they are increasingly challenged by modernization, whether they can keep clean production in a modern society has become a general concern. In this study, we first put forward a theoretical framework for the environmental impact assessment of agricultural heritage systems. Then, we apply it to Qingtian Rice-Fish Culture System (QRFCS), the first Globally Important Agricultural Heritage Systems in China. We focus on its environmental impact in terms of greenhouse gas (GHG) emissions and analyze the changes in its capacity for reducing GHG emissions under dual impacts of modernization and conservation measures with the carbon footprint model. Results show that the rice-fish culture has obvious advantages in GHG emission reduction over the rice monoculture in the study area, but it is in face of environmental risks brought by the increased inputs of fertilizers and feed. The environmental impact of QRFCS in terms of GHG emissions has decreased these years, but the risk of the rice-fish industry shrinking has increased due to the negative feedback formed by the low input and low output status. However, the positive aspect is that the moderate land scale management has increased the capacity of QRFCS for reducing GHG emissions and promoted its conservation as an agricultural heritage system. We propose that this theoretical framework and its application results will not only provide suggestions for giving full play to the clean production capacity of agricultural heritage systems, but also provide countermeasures for their conservation in the context of modernization.
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References
Ahmed N, Garnett ST (2011) Integrated rice-fish farming in Bangladesh: meeting the challenges of food security. Food Secur 3:81–92
Altieri MA (2002) Agroecology: the science of natural resource management for poor farmers in marginal environments. Agric Ecosyst Environ 93:1–24
Bai Y, Sun X, Tian M et al (2014) Typical water-land utilization GIAHS in low-lying areas: the Xinghua Duotian Agrosystem example in China. J Resour Ecol 5(4):320–327
Bantayan NC, Calderon MM, DizonI JT et al (2012) Estimating the extent and damage of the UNESCO world heritage sites of the Ifugao. J Environ Sci Manag 15:1–5
Berg H, Tam NT (2018) Decreased use of pesticides for increased yields of rice and fish-options for sustainable food production in the Mekong Delta. Sci Total Environ 619:319–327
Cai S, Lv W, Zhu H, Zhang D, Xu S (2019) Effect of nitrogen application rate on soil fungi community structure in a rice-fish mutualistic system. Sci Rep 9:319–327
Chen X (ed) (2021) Rice-fish system in Qingtian: ecology, conservation and utilization. China Science Publishing & Media Ltd., Beijing
Chung K (2009) Methane and nitrous oxide emissions from an integrated rainfed rice-fish farming system of Eastern India. Agric Ecosyst Environ 129(1–3):228–237
Clavreul J, Butnar I, Rubio V, King H (2017) Intra-and inter-year variability of agricultural carbon footprints—a case study on field-grown tomatoes. J Clean Prod 158:156–164
Cui W, Jiao W, Min Q, Sun Y, Liu M, Wu M (2020) Environmental impact differences in Qingtian Rice-Fish Culture System at different management scales in the context of land transformation: an empirical study with the carbon footprint method. Chin J Appl Ecol 31(12):4125–4133 (in Chinese)
DEEZP (Department of Ecology and Environment of Zhejiang Province) (2022) Guidelines for the compilation of Zhejiang Province GHG Emission Inventory (revised edition in 2022)
dela Cruz MJ, Koohafkan P (2009) Globally Important Agricultural Heritage Systems: a shared vision of agricultural, ecological and traditional societal sustainability. Resour Sci 31(6):905–913
Denevan WM (1995) Prehistoric agricultural methods as modes for sustainability. Adv Plant Pathol 11:21–43
Dey MM, Prein M, Haque ABMM, Sultana P, Dan NC, Van Hao N (2005) Economic feasibility of community-based fish culture in seasonally flooded rice fields in Bangladesh and Vietnam. Aquacult Econ Manag 9:65–88
Dey MM, Spielman DJ, Haque ABMM, Rahman MS, Valmonte-Santos R (2013) Change and diversity in smallholder rice-fish systems: recent evidence and policy lessons from Bangladesh. Food Policy 43:108–117
Diksha S, Devakumar AS (2018) The carbon footprint of agricultural crop cultivation in India. Carbon Manag 9(3):213–225
Ding WH, Li NN, Ren WZ, Hu L, Chen X, Tang J (2013) Effects of improved traditional rice-fish system productivity on field water environment. Chin J Eco-Agric 21:308–314
Dubey A, Lal R (2009) Carbon footprint and sustainability of agricultural production systems in Punjab, India and Ohio, USA. J Crop Improv 23:332–350
Ecoinvent Database (2011) http://www.ecoinvent.ch. Accessed 30 June 2016
Feng J, Li F, Zhou X, Xu C, Fang F (2016) Nutrient removal ability and economical benefit of a rice-fish co-culture system in aquaculture pond. Ecol Eng 94:315–319
Finkbeiner M (2009) Carbon footprinting-opportunities and threats. Int J Life Cycle Assess 14(2):91–94
Frei M, Khan MAM, Razzak MA, Hossain MM, Dewan S, Becker K (2007) Effects of a mixed culture of common carp, Cyprinus carpio L., and Nile tilapia, Oreochromis niloticus (L.), on terrestrial arthropod population, benthic fauna, and weed biomass in rice fields in Bangladesh. Biol Control 41:207–213
Fuller T, Min Q (2013) Understanding agricultural heritage sites and complex adaptive systems: the challenge of complexity. J Resour Ecol 4(3):195–201
Fuller AM, Min Q, Jiao W, Bai Y (2015) Globally Important Agricultural Heritage Systems (GIAHS) of China: the challenge of complexity in research. Ecosyst Health Sustain 1(2):1–10
Guo H, Luo H, Li F, Qi M, Hu Z, Liu Q (2020) Investigation of soil fertility of Qingtian rice-fish coculture system under different rice cultivation densities. J Fish China 44(5):805–815 (in Chinese)
Halwart M (2008) Biodiversity, nutrition and livelihoods in aquatic rice-based ecosystems. Biodiversity 9:36–40
He X, Sun Y, Gao D et al (2011) Comparison of agronomic traits between rice landraces and modern varieties at different altitudes in the paddy fields of Yuanyang terrace, Yunnan Province. J Resour Ecol 2(1):46–50
Hedlund J, Longo SB, York R (2020) Agriculture, pesticide use, and economic development: a global examination (1990–2014). Rural Sociol 85(2):519–544
Hu L, Ren W, Tang J, Li N, Chen X (2013) The productivity of traditional rice-fish co-culture can be increased without increasing nitrogen loss to the environment. Agric Ecosyst Environ 177(2):28–34
Hu L, Zhang J, Ren W, Guo L, Cheng Y, Li J, Li K, Zhu Z, Zhang J, Luo S, Cheng L, Tang J, Chen X (2016) Can the co-cultivation of rice and fish help sustain rice production? Sci Rep 6:28728
Huang X, Chen C, Qian H, Chen M, Deng A, Zhang J, Zhang W (2016) Quantification for carbon footprint of agricultural inputs of grains cultivation in China since 1978. J Clean Prod 142:1629–1637
IPCC (2021) Climate change 2021: the physical science basis. Working Group I Contribution to the IPCC Sixth Assessment Report. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA (in press)
Jiao W, Min Q, Cheng S, Li W (2013) The Waste Absorption Footprint (WAF): a methodological note on footprint calculations. Ecol Indic 34:356–360
Jiao W, Min Q, Fuller AM, Yuan Z, Li J, Cheng S, Li W (2015) Evaluating environmental sustainability with the Waste Absorption Footprint (WAF): an application in the Taihu Lake Basin, China. Ecol Indic 49:39–45
Jiao W, Fuller AM, Xu S, Min Q, Wu M (2016) Socio-ecological adaptation of agricultural heritage systems in modern China: three cases in Qingtian county, Zhejiang province. Sustainability 8:1260. https://doi.org/10.3390/su8121260
Jiao W, Cui W, Min Q, Zhang Y (2021) A review of research on agricultural heritage systems and their conservation. Resour Sci 43(4):823–837 (in Chinese)
Koohafkan P, dela Cruz M (2011) Conservation and adaptive management of Globally Important Agricultural Heritage Systems (GIAHS). J Resour Ecol 2:22–28
Lal R (2004) Carbon emission from farm operations. Environ Int 30(7):981–990
Li N (2013) Ecological analysis of representative rice-based ecosystems in China. Zhejiang University, Hangzhou
Li W (2015) Agri-cultural heritage research and conservation practices: progress and perspectives. J Agro-Environ Sci 34(1):1–6 (in Chinese)
Lin K, Wu J, Lin A (2020) Effect of introducing frogs and fish on soil phosphorus availability dynamics and their relationship with rice yield in paddy fields. Sci Rep 10(1):2395–2407
Liu X, Wang H, Chen J, He Q, Zhang H, Jiang R, Chen X, Hou P (2010) Method and basic mode for development of Chinese reference life cycle database. J Environ Sci 30(10):2136–2144 (in Chinese)
Liu M, Xiong Y, Yuan Z et al (2014) Standards of ecological compensation for traditional eco-agriculture: taking rice-fish system in Hani terrace as an Example. J Mt Sci 11:1049–1059
Liu S, Hu Z, Wu S, Li S, Li Z, Zou J (2016) Methane and nitrous oxide emissions reduced following conversion of rice paddies to inland crab-fish aquaculture in southeast China. Environ Sci Technol 50:633–642
Min Q, Sun Y, van Schoubroeck F, Liang L, dela Cruz M (2009) The GIAHS-rice-fish culture: China project framework. Resour Sci 31:10–20
Min Q, Zhang Y, Jiao W, Sun X (2016) Responding to common questions on the conservation of agricultural heritage systems in China. J Geogr Sci 26(7):969–982
Nahuelhual L, Carmona A, Laterra P et al (2014) A mapping approach to assess intangible cultural ecosystem services: the case of agriculture heritage in Southern Chile. Ecol Ind 40:90–101
Oehme M, Frei M, Razzak MA, Dewan S, Becker K (2007) Studies on nitrogen cycling under different nitrogen inputs in integrated rice-fish culture in Bangladesh. Nutr Cycl Agroecosyst 79(2):181–191
Park H, Oh C (2017) Flora, life form characteristics, and plan for the promotion of biodiversity in South Korea’s Globally Important Agricultural Heritage System, the traditional Gudeuljang irrigated rice terraces in Cheongsando. J Mt Sci 14(6):1212–1228
Pimental D, Acquay H, Biltonen M, Rice P, Silva M, Nelson J, Lipner V, Giordane S, Horowitz A, Amore MD (1992) Environmental and economic costs of pesticides use. Bioscience 42:750–760
Plahe J, Wright S, Marembo M (2017) Livelihoods crises in Vidarbha, India: Food Sovereignty through Traditional Farming Systems as a possible solution. South Asia J South Asian Stud 40(3):1–19
Pretty JN (1995) Regenerating agriculture: policies and practice for sustainability and self-reliance. Joseph Henry Press, Washington, D.C.
Qiu Z, Chen B, Nakamura K (2016) Customary management system of irrigation ponds in Japan—a case study in a Globally Important Agricultural Heritage Systems (GIAHS) site of Noto Island, Ishikawa Prefecture. J Resour Ecol 7(3):205–210
Ren W, Cao C, Wang J (2008) Economic valuation of gas regulation as a service by rice-duck-fish complex ecosystem. Ecol Econ 4:266–272
Ren W, Hu L, Guo L et al (2018) Preservation of the genetic diversity of a local common carp in the agricultural heritage rice-fish system. Proc Natl Acad Sci 115:546–554
Scheele EA, Kruger D (2006) Global anthropogenic methane and nitrous oxide emissions. Energy J 27:33–44
Smith P, Bustamante M, Ahammad H et al (2014) Agriculture, forestry and other land use (AFOLU). In: Climate change 2014: mitigation of climate change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge
Su M, Sun Y, Wall G et al (2019) Agricultural heritage conservation, tourism and community livelihood in the process of urbanization-Xuanhua Grape Garden, Hebei Province, China. Asia Pacific J Tour Res 25(3):205–222
Su Sin T (2006) Evaluation of different species of fish for biological control of golden apple snail Pomacea canaliculata (Lamarck) in rice. Crop Protect 25:1004–1012
Tilman D, Cassman KG, Matson PA, Naylor R, Polasky S (2002) Agricultural sustainability and intensive production practices. Nature 418:671–677
Tong YD (2017) Rice intensive cropping and balanced cropping in the mekong delta, Vietnam d economic and ecological considerations. Ecol Econ 132:205–212
Tsuruta T, Yamaguchi M, Abe SI, Iguchi K (2011) Effect of fish in rice-fish culture on the rice yield. Fish Sci 77:95–106
Wan N, Li S, Li T, Cavalieri A, Weiner J, Zheng X, Ji X, Zhang J, Zhang H, Zhang H, Bai N, Chen Y, Zhang H, Tao X, Zhang H, Lv W, Jiang J, Li B (2019) Ecological intensification of rice production through rice-fish co-culture. J Clean Prod 234:1002–1012
Wang W, Min Q, Sardans J et al (2016) Organic cultivation of jasmine and tea increases carbon sequestration by changing plant and soil stoichiometry. Agron J 108(4):1636–1648
Wang X, Zhao X, Wang Y, Xue J, Zhang H (2017) Assessment of the carbon footprint of rice production in China. Resour Sci 39(4):713–722 (in Chinese)
Wang Y, Pu C, Zhao X, Wang X, Liu S, Zhang H (2018) Historical dynamics and future trends of carbon footprint of wheat and maize in China. Resour Sci 40(9):1800–1811 (in Chinese)
Wiedmann T, Minx J (2008) A definition of ‘carbon footprint.’ In: Pertsova CC, Cochrane P (eds) Ecological Economics Research Trends. Nova, Hauppauge
Wilson DJ (1999) Indigenous South Americans of the past and present: an ecological perspective. Westview Press, Boulder
Xie J, Liu L, Chen X, Chen J, Yang X, Tang J (2009) Control of diseases, pests and weeds in traditional rice-fish ecosystem in Zhejiang, China. Bull Sci Technol 25(6):802–810
Xie J, Wu X, Tang J et al (2011a) Conservation of traditional rice varieties in a Globally Important Agricultural Heritage Systems (GIAHS): rice-fish co-culture. J Agric Sci China 10(5):101–105
Xie J, Hu LL, Tang JJ, Wu X, Li N, Yuan Y, Yang H, Zhang J, Luo S, Chen X (2011b) Ecological mechanisms underlying the sustainability of the agriculture heritage rice-fish coculture system. Proc Natl Acad Sci USA 108(50):1381–1387
Xu H, Wang Q, Bai J et al (2010) Changes of phosphate and ammonium nitrogen in irrigated waters of Hani terrace wetlands along the elevation gradients. Procedia Environ Sci 2:1368–1373
Yuan W, Cao C, Li C, Zhang M, Cai M (2009) Methane and nitrous oxide emissions from rice-duck and rice-fish complex ecosystems and the evaluation of their economic significance. Agric Sci China 10:1246–1255
Zhang Y, Min Q (2016) A review of conservation of rice terraces as agricultural heritage systems. Chin J Eco-Agric 24(4):460–469 (in Chinese)
Zhang L, Li F, Cui H (2014) Role of traditional agricultural ecosystem on prevention-and-cure agricultural non-point source pollution: a case study of rice-fish-duck symbiotic mode in Congjiang County, Guizhou Province. Ecol Econ 30(5):131–134
Zhang Y, Min Q, Wang W et al (2016) Impact of household social-economic characteristics on the willingness to grow crops: a case study of jasmine growers in Fuzhou based on conservation of the agricultural heritage system. Chin J Eco-Agric 24(12):1714–1721 (in Chinese)
Acknowledgements
This study was financially supported by the National Natural Science Foundation of China (Grant no. 41801204). We would like to thank the two anonymous reviewers for their valuable and constructive comments.
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Jiao, W., Cui, W. & He, S. Can agricultural heritage systems keep clean production in the context of modernization? A case study of Qingtian Rice-Fish Culture System of China based on carbon footprint. Sustain Sci 18, 1397–1414 (2023). https://doi.org/10.1007/s11625-022-01274-0
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DOI: https://doi.org/10.1007/s11625-022-01274-0