中国农业气象 ›› 2023, Vol. 44 ›› Issue (10): 863-875.doi: 10.3969/j.issn.1000-6362.2023.10.001

• 农业生态环境栏目 •    下一篇

等氮替代施入生物炭对南方免耕早稻田温室气体排放的影响

李诗,张俊辉,胡钧铭,周凤珏,李婷婷,徐美花,马洁萍,陆展彩   

  1. 1.广西农业科学院农业资源与环境研究所/广西耕地保育重点实验室,南宁 530007;2.广西大学农学院,南宁 530004
  • 收稿日期:2022-11-19 出版日期:2023-10-20 发布日期:2023-10-11
  • 通讯作者: 胡钧铭,研究员,主要从事农业有机资源利用与生境调控及逆境生态研究。 E-mail:jmhu06@126.com
  • 作者简介:李诗,E-mail:2012038808@qq.com;张俊辉,E-mail:281113990@qq.com
  • 基金资助:
    国家自然科学基金项目(41661074);广西“新世纪十百千人才工程”专项资金(2018221);广西科技基地 和人才专项(2022AC18008);广西农业科学院创新团队项目(桂农科2021YT040)

Effect of Isonitrogen Substitution for Biochar Application on Greenhouse Gas Emissions from Southern No-till Early Rice Fields

LI Shi, ZHANG Jun-hui, HU Jun-ming, ZHOU Feng-jue, LI Ting-ting, XU Mei-hua, MA Jie-ping, LU Zhan-cai   

  1. 1.Agricultural Resource and Environment Research Institute, Guangxi Academy of Agricultural Sciencess/Guangxi Key Laboratory of Arable Land Conservation, Nanning 530007, China;2.Agricultural College, Guangxi University, Nanning 530004
  • Received:2022-11-19 Online:2023-10-20 Published:2023-10-11

摘要: 生物炭是新型外源有机底物,其稳定性好,吸附性强,富含碳营养物,常作为固碳减排的重要有机资源。中国南方早籼稻产量高,雨热同期且种植制度独特,2021−2022 年试验在典型籼稻区南宁开展,共设置3种处理分别为,对照处理(CK):不施肥;无机氮投入(T1,化肥)处理:化肥施用量为常规施肥水平,复合肥800kg·hm−2,尿素260.87kg·hm−2,钾肥193.55kg·hm−2;无机氮配施有机氮(T2,生物炭+化肥)处理:生物炭4000kg·hm−2,复合肥738.67kg·hm−2,尿素146.09kg·hm−2,钾肥34.19kg·hm−2。本研究在水稻插秧5d后,采用分离式静态箱−气相色谱法,定期监测水稻生育期内稻田土壤温室气体排放,解析其温室气体累计排放量、排放当量及水稻产量性状,探讨等氮替代施入生物炭对南方早稻田温室气体排放、水稻产量的影响,为优化集约化早籼稻低碳种植和减肥增效提供依据。结果表明:(1)生物炭能降低稻田土壤CH4 、CO2 排放,通过减缓CH4排放而减小综合排放当量。化肥配施生物炭可减缓单施化肥引起的温室气体碳源增排效应,其减缓CO2排放的延后效应较明显,生物炭处理(T2)中,与化肥处理(T1)相比,2021年CH4最大排放通量降低41.38%,累计排放量降低31.25%,2022年最大排放通量降低50.50%,累计排放量显著降低50%,2a的综合排放当量显著低于T1处理;2021年CO2最大排放通量、累计排放量分别比T1处理减小57.38%和 37.68%,2022年比T1处理分别相应减小16.06%和35.52%。(2)生物炭可抑制N2O排放,显著降低累计排放量,减小氮源排放当量。与T1处理对比,T2处理2021年N2O最大排放通量减小5.43%,而累计排放量显著降低33.53%;2022最大排放通量减小73.75%,累计排放量显著降低54.33%。(3)生物炭利于集约化早籼稻种植结构优化,提升早籼稻生产力。生物炭投入稻田2a后,增产效果明显,T2处理的理论产量为T1处理的1.02~1.33倍,实际产量则是T1处理的1.06~1.32倍。化肥配施生物炭减少了早籼稻田温室气体排放,增加了水稻产量,可作为南方集约化早籼稻低碳生产优化模式。

关键词: 温室气体, 生物炭, 低碳优化, 集约化稻田, 早籼

Abstract: Biochar has been recognized as a new exogenous organic substrate and is often used as an important organic resource for carbon reduction because of its stability, adsorption and carbon nutrient richness. The study was conducted in a typical indica rice area of Nanning from 2021 to 2022, against the background of having high early indica rice yields, simultaneous rain and heat, and unique cropping system. In this paper, authors set three treatments: Control treatment (CK): no fertilizer. Inorganic N input (T1, chemical fertilizer) treatment: chemical fertilizer application at conventional fertilizer level, compound fertilizer 800kg·ha−1, urea 260.87kg·ha−1, potassium 193.55kg·ha−1. Inorganic N with organic N (T2, biochar + chemical fertilizer) treatment: biochar 4000kg·ha−1, compound fertilizer 738.67kg·ha−1, urea 146.09kg·ha−1, potassium 34.19kg·ha−1. The cumulative greenhouse gas emissions, emission equivalents, rice yield traits and the effect of isonitrogen substitution of biochar application on greenhouse gas emissions and rice yield in early southern rice fields were analyzed by regular monitoring of soil greenhouse gas emissions in rice fields during the rice reproductive period using a split static box-meteorological chromatography method 5d after rice transplanting, this study provide a basis for optimizing intensive early rice low-carbon cultivation and reduce fertilizer and increase efficiency. The results showed that: (1) biochar can reduce CH4 and CO2 emissions from paddy soils, and reduce the combined emission equivalent by slowing down CH4 emissions. The application of fertilizer with biochar can mitigate the increase of greenhouse gas carbon emissions caused by fertilizer application alone, and its delayed effect of mitigating CO2 emissions is more obvious. In biochar treatment (T2), compared with the chemical fertilizer treatment (T1), the maximum CH4 emission flux in 2021 was reduced by 41.38% and the cumulative emission was reduced by 31.25%, and the maximum emission flux in 2022 was reduced by 50.50% and the cumulative emission was significantly reduced by 50%, and the combined emission equivalents of 2 years were significantly lower than those of the T1 treatment. The maximum CO2 emission flux and cumulative emission in 2021 were reduced by 57.38% and 37.68%, respectively, compared with the T1 treatment, and the corresponding reduction in 2022 was 16.06% and 35.52% compared to the T1 treatment. (2) Biochar can suppress N2O emissions, significantly reduce cumulative emissions, and reduce nitrogen source emission equivalents. Compared to the T1 treatment, the maximum N2O emission flux was reduced by 5.43% and the cumulative emission was significantly reduced by 33.53% in 2021 in T2 treatment; the maximum emission flux was reduced by 73.75% and the cumulative emission was significantly reduced by 54.33% in 2022, and there was no significant change with the CK treatment. (3) Biochar facilitates the optimization of intensive early indica rice cultivation structure and enhances the productivity of early indica rice. After biochar was put into the paddy field for 2 years, the effect of increasing yield became more and more obvious, and the theoretical yield of T2 treatment was 1.02−1.33 times that of T1 treatment, while the actual yield was 1.06−1.32 times that of T1 treatment. Fertilizer with biochar reduced greenhouse gas emissions and increased rice yield in early indica rice fields, which can be used as an optimization model for low-carbon production of intensive early indica rice in the south.

Key words: Greenhouse gas, Biochar, Low carbon optimization, Intensive rice field, Early indica rice