Sam Higginbotom Institute of Agriculture Technology and Sciences, Allahabad, Uttar Pradesh, 211007, India.
International Maize and Wheat Improvement Center (CIMMYT)-India, NASC Complex, DPS Marg, New Delhi, 110012, India.
Environ Sci Pollut Res Int. 2021 Jan;28(1):246-261. doi: 10.1007/s11356-020-10395-x. Epub 2020 Aug 18.
Rice-based cropping systems are the most energy-intensive production systems in South Asia. Sustainability of the rice-based cropping systems is nowadays questioned with declining natural resource base, soil degradation, environmental pollution, and declining factor productivity. As a consequence, the search for energy and resource conservation agro-techniques is increasing for sustainable and cleaner production. Conservation agriculture (CA) practices have been recommended for resource conservation, soil health restoration and sustaining crop productivity. The present study aimed to assess the different CA modules in rice-based cropping systems for energy conservation, energy productivity, and to define energy-economic relations. A field experiment consisted of four different tillage-based crop establishment practices (puddled-transplanted rice followed by (fb) conventional-till maize/wheat (CTTPR-CT), non-puddled transplanted rice fb zero-till maize/wheat (NPTPR-ZT), zero-till transplanted rice fb zero-till maize/wheat (ZTTPR-ZT), zero-till direct-seeded rice fb zero-till maize/wheat (ZTDSR-ZT)), with two residue management treatments (residue removal, residue retention) in rice-wheat and rice-maize rotations were evaluated for energy budgeting and energy-economic relations. Conservation-tillage treatments (NPTPR-ZT, ZTTPR-ZT, and ZTDSR-ZT) reduced the energy requirements over conventional tillage treatments, with the greater reduction in ZTTPR-ZT and ZTDSR-ZT treatments. Savings of energy in conservation-tillage treatments were attributed to reduced energy use in land preparation (69-100%) and irrigation (23-27%), which consumed a large amount of fuel energy. Conservation-tillage treatments increased grain and straw/stover yields of crops, eventually increased the output energy (6-16%), net energy (14-26%), energy ratio (25-33%), and energy productivity (23-34%) as compared with CTTPR-CT. For these energy parameters, the treatment order was ZTDSR-ZT ≥ ZTTPR-ZT > NPTPR-ZT > CTTPR-CT (p < 0.05). Crop residue retention reduced net energy, energy ratio, and energy productivity when compared with residue removal. Our results of energy-economic relations favored the "conservative hypothesis," which envisages that energy and monetary investments are not essentially the determinants of crop productivity. Thus, zero tillage-based crop establishments (ZTTPR-ZT, ZTDSR-ZT) in rice-based production systems could be the sustainable alternative to conventional tillage-based agriculture (CTTPR-CT) as they conserved non-renewable energy sources, reduced water requirement, and increased crop productivity.
以水稻为基础的种植系统是南亚能源密集型生产系统中最耗能的。随着自然资源基础的减少、土壤退化、环境污染和要素生产力的下降,如今人们对以水稻为基础的种植系统的可持续性提出了质疑。因此,人们正在寻找节能和资源节约型农业技术,以实现可持续和清洁生产。保护性农业(CA)措施已被推荐用于资源保护、土壤健康恢复和维持作物生产力。本研究旨在评估水稻种植系统中不同的 CA 模块在节能、能源生产力方面的作用,并确定能源-经济关系。田间试验包括四种不同的耕作方式(水耕移栽稻后常规耕作玉米/小麦(CTTPR-CT)、免耕移栽稻后免耕玉米/小麦(NPTPR-ZT)、免耕移栽稻后免耕玉米/小麦(ZTTPR-ZT)、免耕直播稻后免耕玉米/小麦(ZTDSR-ZT)),以及水稻-小麦和水稻-玉米轮作中的两种残茬管理处理(残茬去除、残茬保留),用于能量预算和能量-经济关系的评估。与传统耕作处理相比,保护性耕作处理(NPTPR-ZT、ZTTPR-ZT 和 ZTDSR-ZT)减少了能源需求,其中 ZTTPR-ZT 和 ZTDSR-ZT 处理的减少幅度更大。保护性耕作处理中的能源节约归因于土地准备(69-100%)和灌溉(23-27%)方面的能源使用减少,而土地准备和灌溉消耗了大量燃料能源。保护性耕作处理增加了作物的粮食和秸秆/茎产量,最终增加了输出能量(6-16%)、净能量(14-26%)、能量比(25-33%)和能量生产力(23-34%),与 CTTPR-CT 相比。对于这些能量参数,处理顺序为 ZTDSR-ZT≥ZTTPR-ZT>NPTPR-ZT>CTTPR-CT(p<0.05)。与去除残茬相比,残茬保留降低了净能量、能量比和能量生产力。我们的能量-经济关系结果支持“保守假说”,该假说认为,能源和货币投资不一定是作物生产力的决定因素。因此,基于免耕的作物种植(ZTTPR-ZT、ZTDSR-ZT)在水稻生产系统中可能是传统基于耕作的农业(CTTPR-CT)的可持续替代方案,因为它们可以节约不可再生能源、减少用水需求并提高作物生产力。
