The multiple roles of crop structural change in
productivity, nutrition and environment in China: A decomposition analysis

doi:10.1016/j.jia.2024.03.064

Journal of Integrative Agriculture

2024, Vol. 23

Issue (5): 1763-1773 DOI: 10.1016/j.jia.2024.03.064

Special Issue: 农业经济与管理Agricultural Economics and Management

Agricultural Economics and Management

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The multiple roles of crop structural change in productivity, nutrition and environment in China: A decomposition analysis

Xiangyang Zhang^{1, 2}, Yumei Zhang^1,
2#, Shenggen Fan^{1, 2}

¹College of Economics and Management, China Agricultural University, Beijing 100083, China

²Academy of Global Food Economics and Policy, China Agricultural University, Beijing 100083, China

Abstract
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摘要自2000年以来，中国的作物结构发生了重大变化，谷物、蔬菜和水果的比重提高，挤压了其他作物的种植。作物的土地生产力、营养供给和碳排放也因此发生了变化。如何将有限的土地在作物之间重新分配以实现农业食物系统的多重目标成为一个重要问题。本研究利用增长分解法探讨了2003年至2020年间土地生产力、营养供给增长和碳排放减少的源泉，并识别了作物结构变化在其中的作用。研究结果表明，作物本身的增长仍然是土地生产力和营养供给增长以及碳排放减少的主要驱动力。然而，结构调整在不同时期也发挥着不同的作用。2003年至2010年，作物结构调整增加了总热量供应，但降低了土地生产力，同时贡献了至少70%的碳排放总量的增长。2010-2015年，作物结构相对稳定，产生的影响较小。2015-2020年，作物结构调整发挥的作用更大，在提高土地生产力、微量营养素供给和减少碳排放等方面产生协同效应，促进了大约四分之一的土地生产力增长和减少了30%的碳排放量。为此，未来应综合考虑作物结构的多重影响来制定其调整战略，并努力实现协同效益，减少相互间的权衡效应。

Abstract

China’s crop structure has undergone significant changes in the last two decades since 2000, with an increase in the share of cereals, vegetables, and fruit, squeezing out other crops. As a result, land productivity, nutrient supply, and carbon emissions have changed. How to reallocate limited farmland among crops to achieve the multiple goals of agrifood systems becomes an important issue. This study explores the sources of land productivity and nutrition supply growth and carbon emissions reduction, and identifies the multiple roles of crop structural change from 2003 to 2020 based on a decomposition analysis. The results reveal that the growth within crops is still the primary driver in land productivity and nutrition supply and the reduction in carbon emissions. However, structural change also plays various roles at different periods. From 2003 to 2010, crop structural change increased the total calorie supply but lowered land productivity and contributed at least 70% of the total growth of carbon emissions. The crop structure was relatively stable, and their effects were modest from 2010 to 2015. From 2015 to 2020, the crop structural change began to play a greater role and generate synergistic effects in improving land productivity, micronutrient supply, and reducing carbon emissions, contributing to approximately a quarter of the growth of land productivity and 30% of total carbon emissions reduction. These results suggest that strategies for crop structural change should comprehensively consider its multiple impacts, aiming to achieve co-benefits while minimizing trade-offs.

Keywords: crop structural change land productivity nutrition carbon emissions

Received: 21 February 2023 Accepted: 08 February 2024

Fund: This work was supported by the National Natural Science Foundation of China (72061147002 and 72373143) and the National Social Science Fund of China (22&ZD085).

About author: Xiangyang Zhang, E-mail: zhangxiangyang@cau.edu.cn; #Correspondence Yumei Zhang, E-mail: zhangyumei@cau.edu.cn

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Cite this article:

Xiangyang Zhang, Yumei Zhang, Shenggen Fan. 2024.

The multiple roles of crop structural change in productivity, nutrition and environment in China: A decomposition analysis . Journal of Integrative Agriculture, 23(5): 1763-1773.

Bigsten A, Tengstam S. 2011. Smallholder diversification and income growth in Zambia. Journal of African Economies, 20, 781–822.

Birthal P S, Joshi P K, Negi D S, Agarwal S. 2014. Changing sources of growth in Indian agriculture: Implications for regional priorities for accelerating agricultural growth. IFPRI Discussion Paper, 01325.

Carlson K M, Curran L M, Ratnasari D, Pittman A M, Soares-Filho B S, Asner G P, Trigg S N, Gaveau D A, Lawrence D, Rodrigues H O. 2012. Committed carbon emissions, deforestation, and community land conversion from oil palm plantation expansion in West Kalimantan, Indonesia. Proceedings of the National Academy of Sciences of the United States of America, 109, 7559–7564.

Cheng K, Pan G X, Smith P, Luo T, Li L Q, Zheng J W, Zhang X H, Han X J, Yan M. 2011. Carbon footprint of China’s crop production - An estimation using agro-statistics data over 1993–2007. Agriculture, Ecosystems & Environment, 142, 231–237.

Cheng K, Yan M, Nayak D, Pan G X, Smith P, Zheng J F, Zheng J W. 2015. Carbon footprint of crop production in China: An analysis of national statistics data. Journal of Agricultural Science, 153, 422–431.

Cong W F, Zhang C C, Li C J, Wang G Z, Zhang F S. 2021. Designing diversified cropping systems in China: Theory, approaches and implementation. Frontiers of Agricultural Science and Engineering, 8, 362‒372.

Crippa M, Solazzo E, Guizzardi D, Monforti-Ferrario F, Tubiello F N, Leip A. 2021. Food systems are responsible for a third of global anthropogenic GHG emissions. Nature Food, 2, 198–209.

Davis K F, Chiarelli D D, Rulli M C, Chhatre A, Richter B, Singh D, DeFries R. 2018. Alternative cereals can improve water use and nutrient supply in India. Science Advances, 4, eaao1108.

Davis K F, Rulli M C, Seveso A, D’Odorico P. 2017. Increased food production and reduced water use through optimized crop distribution. Nature Geoscience, 10, 919–924.

DeFries R, Mondal P, Singh D, Agrawal I, Fanzo J, Remans R, Wood S. 2016. Synergies and trade-offs for sustainable agriculture: Nutritional yields and climate-resilience for cereal crops in Central India. Global Food Security, 11, 44–53.

Dong Z Q, Pan Z H, Wang S, An P L, Zhang J T, Zhang J, Pan Y Y, Huang L, Zhao H, Han G L, Wu D, Wang J L, Fan D L, Gao L, Pan X B. 2016. Effective crop structure adjustment under climate change. Ecological Indicators, 69, 571–577.

Dwivedi S L, van Bueren E T L, Ceccarelli S, Grando S, Upadhyaya H D, Ortiz R. 2017. Diversifying food systems in the pursuit of sustainable food production and healthy diets. Trends in Plant Science, 22, 842–856.

Ecker O. 2018. Agricultural transformation and food and nutrition security in Ghana: Does farm production diversity (still) matter for household dietary diversity? Food Policy, 79, 271–282.

Evenson R E, Gollin D. 2003. Assessing the impact of the green revolution, 1960 to 2000. Science, 300, 758–762.

Fan S G, Headey D, Rue C, Thomas T. 2021. Food systems for human and planetary health: Economic perspectives and challenges. Annual Review of Resource Economics, 13, 131–156.

Groot J C J, Yang X L. 2022. Trade-offs in the design of sustainable cropping systems at a regional level: A case study on the North China Plain. Frontiers of Agricultural Science and Engineering, 9, 295‒308.

Guo H P, Xie S D, Pan C L. 2021. The impact of planting industry structural changes on carbon emissions in the three northeast provinces of China. International Journal of Environmental Research and Public Health, 18, 705.

Jones A D. 2017. Critical review of the emerging research evidence on agricultural biodiversity, diet diversity, and nutritional status in low- and middle-income countries. Nutrition Reviews, 75, 769–782.

Liu Z H, Yang P, Wu W B, You L Z. 2018. Spatiotemporal changes of cropping structure in China during 1980–2011. Journal of Geographical Sciences, 28, 1659–1671.

Lukas M, Palzkill A, Rohn H, Liedtke C. 2013. The nutritional footprint: An innovative management approach for the food sector. In: Brebbia C A, Popov V, eds., Food and Environment II. WIT Press, Southampton UK. pp. 3–13.

McMillan M, Rodrik D, Verduzco-Gallo I. 2014. Globalization, structural change, and productivity growth, with an update on Africa. World Development, 63, 11–32.

Meng T, Fan S G. 2023. Transforming Chinese food and agriculture: A systems perspective. Frontiers of Agricultural Science and Engineering, 10, 4–15.

Messéan A, Viguier L, Paresys L, Aubertot J N, Canali S, Iannetta P, Justes E, Karley A, Keillor B, Kemper L, Muel F, Pancino B, Stilmant D, Watson C, Willer H, Zornoza R. 2021. Enabling crop diversification to support transitions toward more sustainable European agrifood systems. Frontiers of Agricultural Science and Engineering, 8, 474‒480.

Olesen J E, Trnka M, Kersebaum K C, Skjelvag A O, Seguin B, Peltonen-Sainio P, Rossi F, Kozyra J, Micale F. 2011. Impacts and adaptation of European crop production systems to climate change. European Journal of Agronomy, 34, 96–112.

Ray D K, Ramankutty N, Mueller N D, West P C, Foley J A. 2012. Recent patterns of crop yield growth and stagnation. Nature Communications, 3, 1293.

Rodrik D, McMillan M, Sepúlveda C. 2017. Structural change, fundamentals, and growth. In: McMillan M, Rodrik D, Sepúlveda C, eds., Structural Change, Fundamentals, and Growth: A Framework and Case Studies. IFPRI, Washington, USA. pp. 1–38.

Song W, Han Z, Deng X Z. 2016. Changes in productivity, efficiency and technology of China’s crop production under rural restructuring. Journal of Rural Studies, 47, 563–576.

Stevenson J R, Villoria N, Byerlee D, Kelley T, Maredia M. 2013. Green Revolution research saved an estimated 18 to 27 million hectares from being brought into agricultural production. Proceedings of the National Academy of Sciences of the United States of America, 110, 8363–8368.

Sun J, Mooney H, Wu W B, Tang H J, Tong Y X, Xu Z C, Huang B R, Cheng Y Q, Yang X J, Wei D, Zhang F S, Liu J G. 2018. Importing food damages domestic environment: Evidence from global soybean trade. Proceedings of the National Academy of Sciences of the United States of America, 115, 5415–5419.

Wan Y, Hu H, Hu W Y. 2022. Agricultural production structure, market conditions and farmers’ nutritional intake in rural China. Journal of Integrative Agriculture, 21, 1812–1824.

Wu Z P, Liu M Q, Davis J. 2005. Land consolidation and productivity in Chinese household crop production. China Economic Review, 16, 28–49.

Xie W, Zhu A F, Ali T, Zhang Z T, Chen X G, Wu F, Huang J K, Davis K F. 2023. Crop switching can enhance environmental sustainability and farmer incomes in China. Nature, 616, 300–305.

Xue Q G, Zhou H, Wang Q Z. 2013. Contribution and influencing factors of structural changes in the growth of China’s planting industry-based on the analysis of provincial panel data from 1985 to 2011. Chinese Rural Economy, 12, 28–38+92. (in Chinese)

Yang J, Liu X Y. 2021. The impact of agricultural planting structural change on production efficiency in China-based on the perspective of specialized division of labor. Journal of Huazhong University of Science and Technology (Social Science Edition), 35, 64–73. (in Chinese)

Zhang H, Xu F, Wu Y, Hu H H, Dai X F. 2017. Progress of potato staple food research and industry development in China. Journal of Integrative Agriculture, 16, 2924–2932.

Zhang Y M, Diao X S. 2020. The changing role of agriculture with economic structural change - The case of China. China Economic Review, 62, 101504.

Zhang Y M, Meng T, Lan X M, Fan S G, Chen K Z, Si W. 2022. Evolution of agricultural support policies. In: 2022 China and Global Food Policy Report: Reforming Agricultural Support Policy for Transforming Agrifood Systems. Beijing, China. pp. 2–12.

Zhao Q R, Zhang Y M, Fan S G, Chen K Z, Cui Y, Zhang Y. 2022. Reforming support policies to improve Chinese nutrition and diet. In: 2022 China and Global Food Policy Report: Reforming Agricultural Support Policy for Transforming Agrifood Systems. Beijing, China. pp. 2–12.

Zhong F N, Ye C H. 2004. Principles and simulation results of strategic structural adjustment of China’s planting industry. Chinese Rural Economy, (4), 4–9+23. (in Chinese)

Zhong F N, Zhu J. 2000. The role of structural adjustment in China’s agricultural growth. Chinese Rural Economy, 7, 4–7. (in Chinese)

Zhu J, Li T X, Lin D Y, Zhong F N. 2013. Analysis on China’s nine-year consecutive grain production growth: Contribution and future potential of inter-crop structural adjustment. Issues in Agricultural Economy, 34, 36–43+110–111. (in Chinese)

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