Identifying a sustainable rice-based cropping system via on-farm evaluation of grain yield, carbon sequestration capacity and carbon footprints in Central China

IF 5.6 1区农林科学 Q1 AGRONOMY Field Crops Research Pub Date : 2024-08-01 DOI:10.1016/j.fcr.2024.109510

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Abstract

Context

Rice-based cropping system is a major anthropogenic source of direct greenhouse gases (GHG) emissions, agricultural inputs also produces numerous indirect GHG emissions and environmental problems. Identification of rice cropping systems with lower GHG emissions and higher grain yields is of great significance to ensure food security while minimizing agricultural carbon footprint (CF).

Objective

This study aimed to identify the optimal rice-based cropping system with lower greenhouse effects and comparable annual yield in central China.

Methods

Used life cycle assessment, a two-year field experiment was performed to evaluate the direct and indirect GHG emissions, CF, and carbon sequestration capacity in the six rice-based cropping systems widely used in central China, which consisted of fallow-early rice-late rice, rapeseed-early rice-late rice, fallow-ratoon rice, rapeseed-ratoon rice (RRaR), fallow-middle rice, and rapeseed-middle rice.

Results

The results showed that compared with the three systems with fallow season, the three systems with rapeseed had lower annual CH₄ emissions. The two systems with ratoon rice had lower annual indirect and direct GHG emissions than the two systems with double rice. The three systems with rapeseed had higher annual biomass, grain yields, and fixed carbon in biomass and significantly lower CF than the three systems with fallow season, and RRaR had the highest value of fixed carbon in biomass. The systems with ratoon rice had lower average CF than those systems with double rice. CH₄ emissions from paddy fields were the primary source of total annual GHG and the main component of CF. Compared with the three systems with fallow season, the three systems with rapeseed had significantly higher annual carbon sequestration capacity based on net ecosystem production (NEP). Ratoon rice systems had higher average NEP than double- and middle-rice systems. RRaR had the lowest CF per unit yield and highest NEP among all the six systems.

Conclusions

The results indicated that appropriate rice-based cropping systems may alleviate the greenhouse effect via reducing GHG emissions and enhancing paddy NEP, RRaR could achieve relatively higher annual grain yield and carbon sequestration capacity as well as lower CF.

Significance

This study highlight conversion of double rice and middle rice systems to RRaR may help improve grain yield and mitigate greenhouse effect. The findings may provide a theoretical basis for selection of sustainable development of rice based cropping systems in central China.

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通过对华中地区粮食产量、固碳能力和碳足迹的农场评估，确定以水稻为基础的可持续种植系统

以水稻为基础的种植系统是温室气体（GHG）直接排放的主要人为来源，农业投入也会产生大量的温室气体间接排放和环境问题。确定温室气体排放量较低、谷物产量较高的水稻种植系统，对于在确保粮食安全的同时最大限度地减少农业碳足迹（CF）具有重要意义。本研究旨在确定华中地区温室效应较低、年产量相当的最佳水稻种植系统。采用生命周期评估方法，通过为期两年的田间试验，对华中地区广泛使用的六种水稻种植制度（包括休耕-早稻-晚稻、油菜籽-早稻-晚稻、休耕-糙稻、油菜籽-糙稻（RRaR）、休耕-中稻和油菜籽-中稻）的直接和间接温室气体排放、碳足迹和固碳能力进行了评估。结果表明，与三个休耕期系统相比，三个油菜籽系统的 CH 年排放量较低。与两个双季稻系统相比，两个轮作水稻系统的年间接和直接温室气体排放量较低。采用油菜籽的三个系统的年生物量、谷物产量和生物量中的固定碳均高于采用休耕期的三个系统，而生物量中的固定碳则明显低于这三个系统，其中 RRaR 的生物量中的固定碳值最高。轮作水稻系统的平均 CF 值低于双季稻系统。水稻田的 CH 排放是全年温室气体总量的主要来源，也是 CF 的主要组成部分。根据生态系统净生产量（NEP），与三个休耕期系统相比，三个油菜籽系统的年固碳能力明显更高。轮作水稻系统的平均净生态生产率高于双季稻和中稻系统。在所有六种系统中，RRaR 的单位产量碳固存能力最低，净生态系统生产力（NEP）最高。研究结果表明，适宜的水稻种植系统可通过减少温室气体排放和提高水稻净效应水平来缓解温室效应，RRaR 可获得相对较高的年粮食产量和固碳能力以及较低的 CF。本研究强调，将双季稻和中稻系统转换为 RRaR 可能有助于提高粮食产量和缓解温室效应。研究结果可为华中地区选择可持续发展的水稻种植系统提供理论依据。

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来源期刊

Field Crops Research 农林科学-农艺学

CiteScore

9.60

自引率

12.10%

发文量

307

审稿时长

46 days

期刊介绍： Field Crops Research is an international journal publishing scientific articles on: √ experimental and modelling research at field, farm and landscape levels on temperate and tropical crops and cropping systems, with a focus on crop ecology and physiology, agronomy, and plant genetics and breeding.