Effects of Organic Fertilizer Application on Soil Physicochemical Properties and Rice Growth and Development in Saline-Alkali Land

doi:10.3969/j.issn.1006-8082.2026.01.008

China Rice ›› 2026, Vol. 32 ›› Issue (1): 39-46.DOI: 10.3969/j.issn.1006-8082.2026.01.008

• Special Thesis & Basic Research • Previous Articles Next Articles

Effects of Organic Fertilizer Application on Soil Physicochemical Properties and Rice Growth and Development in Saline-Alkali Land

ZHANG Xiang¹, GENG Xiaoyu¹, WANG Lulu¹^,², MA Weiyi¹, ZUO Boyuan¹, ZHU Jizou¹, LIU Yang¹, SHENG Xiaozhou¹, GAO Pinglei¹, CHEN Yinglong¹, WEI Huanhe¹^,^*(), DAI Qigen¹^,^*()

¹Jiangsu Provincial Key Laboratory of Crop Genetics and Physiology/Jiangsu Provincial Key Laboratory of Crop Cultivation Physiology/Jiangsu Provincial Collaborative Innovation Center of Modern Grain Crop Industry Technology/Key Laboratory of Saline-Alkali Soil Improvement and Utilization (Coastal Saline-Alkali Land), Ministry of Agriculture and Rural Affairs/East China Branch of National Center of Technology Innovation for Saline-Alkali Tolerant Rice/Rice Industry Engineering and Technology Research Institute, Yangzhou University, Yangzhou, Jiangsu 225009, China
²Joint Laboratory for International Cooperation in Agriculture and Agricultural Products Safety, Ministry of Education, Yangzhou University/Institute of Agricultural Science and Technology Development, Yangzhou University, Yangzhou, Jiangsu 225009, China

Received:2025-09-14 Online:2026-01-20 Published:2026-01-13
Contact: WEI Huanhe, DAI Qigen

有机肥施用对盐碱地土壤理化特性和水稻生长发育的影响

张翔¹, 耿孝宇¹, 汪璐璐¹^,², 马唯一¹, 左博源¹, 朱济邹¹, 刘洋¹, 盛小洲¹, 高平磊¹, 陈英龙¹, 韦还和¹^,^*(), 戴其根¹^,^*()

¹江苏省作物遗传生理重点实验室/江苏省作物栽培生理重点实验室/江苏省粮食作物现代产业技术协同创新中心/农业农村部盐碱土改良与利用（滨海盐碱地）重点实验室/国家耐盐碱水稻技术创新中心华东中心/扬州大学水稻产业工程技术研究院，江苏扬州 225009
²扬州大学教育部农业与农产品安全国际合作联合实验室/扬州大学农业科技发展研究院，江苏扬州 225009

通讯作者: 韦还和,戴其根
基金资助:
江苏省碳达峰碳中和科技创新专项资金(BE2022304);江苏省高等学校基础科学（自然科学）研究重大项目(24KJA210002)

Abstract

Abstract:

Saline-alkali land is an important reserve arable resource and a “potential grain warehouse” in China. However, its high soil salinity, poor structural properties, and low nutrient content severely constrain crop productivity and quality improvement. Existing studies have demonstrated that the application of organic fertilizers can effectively improve the physicochemical properties of saline-alkali soils and alleviate the adverse effects of salinity on rice development, yield, and quality. This paper introduces the definition and classification of organic fertilizers, summarizes their effects on the physicochemical properties of saline-alkali soils, the composition of soil microbial communities, and soil enzyme activities. Furthermore, it analyzes the influence and physiological mechanisms of organic fertilizer application on rice growth, yield, and quality in saline-alkali environments. Finally, it offers recommendations for future innovations in organic fertilizer products and the optimization of application technologies, aiming to provide a scientific foundation for enhancing soil improvement efficiency and promoting rice yield and quality in saline-alkali lands.

Key words: saline-alkali land, organic fertilizer, rice, physical and chemical properties of soil, growth and development

摘要：

盐碱地是我国重要的后备耕地资源和“潜在粮仓”。盐碱地因其土壤盐分高、结构差、养分含量低，严重制约了作物生产和产量品质的提升。已有研究表明，有机肥施用可有效改善盐碱地土壤理化特性，有效缓解盐分对水稻生长发育、产量和品质形成的抑制效应。本文介绍了有机肥的定义及其产品分类，概述了有机肥施用对盐碱地土壤理化性质、土壤微生物群落、土壤酶活性的影响，剖析了有机肥施用对盐碱地水稻生长发育、产量和品质形成的影响效应及其生理机制，对未来有机肥产品创新与施用技术优化提出了建议，以期为保障盐碱地土壤改良效率与水稻产量和品质提升提供科学依据。

关键词: 盐碱地, 有机肥, 水稻, 土壤理化特性, 生长发育

CLC Number:

S511.062

ZHANG Xiang, GENG Xiaoyu, WANG Lulu, MA Weiyi, ZUO Boyuan, ZHU Jizou, LIU Yang, SHENG Xiaozhou, GAO Pinglei, CHEN Yinglong, WEI Huanhe, DAI Qigen. Effects of Organic Fertilizer Application on Soil Physicochemical Properties and Rice Growth and Development in Saline-Alkali Land[J]. China Rice, 2026, 32(1): 39-46.

张翔, 耿孝宇, 汪璐璐, 马唯一, 左博源, 朱济邹, 刘洋, 盛小洲, 高平磊, 陈英龙, 韦还和, 戴其根. 有机肥施用对盐碱地土壤理化特性和水稻生长发育的影响[J]. 中国稻米, 2026, 32(1): 39-46.

Figures/Tables 1

References 98

[1]	马凯, 饶良懿. 我国土壤盐碱化问题研究脉络和热点分析[J]. 中国农业大学学报, 2023, 28(11):90-102.
[2]	ZHANG W W, WANG C, XUE R, et al. Effects of salinity on the soil microbial community and soil fertility[J]. Journal of Integrative Agriculture, 2019, 18(6): 1 360-1 368.
[3]	MINHAS P S, RAMOS T B, BEN-GAL A, et al. Coping with salinity in irrigated agriculture: Crop evapotranspiration and water management issues[J]. Agricultural Water Management, 2020, 227: 105 832.
[4]	ZHU F M, KAMIYA T, FUJIWARA T, et al. A comparison of rice root microbial dynamics in organic and conventional paddy fields[J]. Microorganisms, 2024, 13(1): 41.
[5]	FU J H, LIU Y W, LIU X C, et al. Screening of saline-alkali tolerant microorganisms and their promoting effects on rice growth under saline-alkali stress[J]. Journal of Cleaner Production, 2024, 481: 144 176.
[6]	RAN C, GAO D P, LIU W Y, et al. Straw and nitrogen amendments improve soil, rice yield, and roots in a saline sodic soil[J]. Rhizosphere, 2022, 24: 100 606.
[7]	DING T Y, GUO Z C, QIAN Y Q, et al. Interaction between POM and pore structure during straw decomposition in two soils with contrasting texture[J]. Soil and Tillage Research, 2025, 245: 106 288.
[8]	李秀军, 李取生, 王志春, 等. 松嫩平原西部盐碱地特点及合理利用研究[J]. 农业现代化研究, 2002, 23(5):361-364.
[9]	KRAUSE H M, MUELLER R C, LORI M, et al. Organic cropping systems alter metabolic potential and carbon, nitrogen and phosphorus cycling capacity of soil microbial communities[J]. Soil Biology and Biochemistry, 2025, 203: 109 737.
[10]	KONG F X, JIU A M, KAN Z R, et al. Deep tillage combined with straw biochar return increases rice yield by improving nitrogen availability and root distribution in the subsoil[J]. Field Crops Research, 2024, 315: 109 481.
[11]	张瑞福, 陈玉, 孙新丽, 等. 中国生物肥料与有机肥料研究三十年:回顾与展望[J]. 植物营养与肥料学报, 2024, 30(7):1 262-1 273.
[12]	上官龙生, 王婷, 梁晨, 等. 碳源投入对西南地区土壤有机碳与作物产量的影响[J]. 核农学报, 2025, 39(3):605-617.
[13]	马桂秀, 林治安, 李志杰, 等. 有机物料与化肥配施改良盐碱耕地的效果研究[J]. 中国土壤与肥料, 2019(3):69-75.
[14]	HOU M M, SHAO X H, ZHAI Y M. Effects of different regulatory methods on improvement of greenhouse saline soils, tomato quality, and yield[J]. The Scientific World Journal, 2014, 2014(1): 953 675.
[15]	LIU J Y, XIE W P, YANG J S, et al. Effect of different fertilization measures on soil salinity and nutrients in salt-affected soils[J]. Water, 2023, 15(18): 3 274.
[16]	WANG S B, GAO P L, ZHANG Q W, et al. Application of biochar and organic fertilizer to saline-alkali soil in the Yellow River Delta: Effects on soil water, salinity, nutrients, and maize yield[J]. Soil Use and Management, 2022, 38(4): 1 679-1 692.
[17]	LI G, SHAN Y Y, NIE W B, et al. Humic acid improves water retention, maize growth, water use efficiency and economic benefits in coastal saline-alkali soils[J]. Agricultural Water Management, 2025, 309: 109 323.
[18]	MA Y Q, CHENG X Y, ZHANG Y Y. The impact of humic acid fertilizers on crop yield and nitrogen use efficiency: A meta-analysis[J]. Agronomy, 2024, 14(12): 2 763.
[19]	肖雅寅, 蒲子天, 张瑞芳, 等. 不同有机物料对盐碱地改良效果的研究进展[J]. 中国土壤与肥料, 2024(3):229-239.
[20]	汪勇, 孟庆峰. 长期施用牛粪对松嫩平原盐渍化土壤脱盐碱化效果的影响[J]. 华北农学报, 2022, 37(2):142-151.
[21]	江瑜, 朱相成, 钱浩宇, 等. 水稻丰产与稻田甲烷减排协同的研究展望[J]. 南京农业大学学报, 2022, 45(5):839-847.
[22]	王逸筠, 赵文栋, 孙泽强, 等. 有机肥替代对鲁西北轻度盐碱地土壤性状和小麦、玉米产量的影响[J]. 山东农业科学, 2023, 55(1):93-99.
[23]	ZHOU Z X, LI Z Y, ZHANG Z Q, et al. Treatment of the saline-alkali soil with acidic corn stalk biochar and its effect on the sorghum yield in western Songnen Plain[J]. Science of the Total Environment, 2021, 797: 149 190.
[24]	MAHMOODABADI M, YAZDANPANAH N, SINOBAS L R, et al. Reclamation of calcareous saline sodic soil with different amendments (I): Redistribution of soluble cations within the soil profile[J]. Agricultural Water Management, 2013, 120: 30-38.
[25]	TIAN X G, ZHANG X, YANG G P, et al. Effects of microbial fertilizer application on soil ecology in saline-alkali fields[J]. Agronomy, 2025, 15(1): 14.
[26]	WANG R S, WANG C G, LIU T, et al. Effects of different organic materials and reduced nitrogen fertilizer application on sorghum yield and soil nutrients[J]. Scientific Reports, 2025, 15: 6 914.
[27]	ZHOU S S, CHANG T T, ZHANG Y J, et al. Organic fertilizer compost alters the microbial composition and network structure in strongly acidic soil[J]. Applied Soil Ecology, 2024, 195: 105 263.
[28]	谭文峰, 许运, 史志华, 等. 胶结物质驱动的土壤团聚体形成过程与稳定机制[J]. 土壤学报, 2023, 60(5):1 297-1 308.
[29]	王周, 李强, 彭畅, 等. 有机肥氮替代50%化肥氮有效改善吉林省中部地区黑土团聚体性状[J]. 植物营养与肥料学报, 2024, 30(12):2 247-2 257.
[30]	常香玲. 华北平原不同土地利用方式下土壤饱和导水率特征及其影响因素[J]. 节水灌溉, 2023(7):28-33.
[31]	李嘉楠, 周成乾, 胡广录, 等. 荒漠-绿洲过渡带典型固沙植物根区土壤大孔隙特征及影响因素[J]. 干旱区研究, 2024, 41(12):2 015-2 026.
[32]	杨红, 柳文杰, 刘合满, 等. 西藏玉米田养鹅模式下的土壤碳排放特征[J]. 干旱地区农业研究, 2022, 40(1):203-212.
[33]	REN S Y, LIU Y H, LIU Y H, et al. Combination of nitrogen-fixing bacteria and mycorrhizal fungi promotes Leymus chinensis growth and bioremediation of degraded grasslands in semi-arid regions[J]. Plant and Soil, 2025, 511(1): 1 575-1 595.
[34]	SONG H M, CHANG Z X, HU X, et al. Combined application of chemical and organic fertilizers promoted soil carbon sequestration and bacterial community diversity in dryland wheat fields[J]. Land, 2024, 13(8): 1 296.
[35]	周瑞春, 官会林, 刘奎, 等. 施用生物有机肥对旱地红壤保水性与细菌群落的影响[J]. 中国土壤与肥料, 2024(7):153-160.
[36]	荣慧, 房焕, 张中彬, 等. 团聚体大小分布对孔隙结构和土壤有机碳矿化的影响[J]. 土壤学报, 2022, 59(2):476-485.
[37]	温云杰, 张建诚, 杨娜, 等. 长期秸秆还田配施有机肥对土壤有机碳组分和孔隙结构的影响[J]. 农业工程学报, 2024, 40(21):74-81.
[38]	戈应同, 王宇蕴, 徐翔, 等. 有机肥增强植物磷素吸收利用机制研究进展[J]. 中国土壤与肥料, 2024(7):228-235.
[39]	张文丽, 万雨欣, 徐伟慧, 等. 促生菌种组合提高玉米根际土壤有益微生物基因丰度及促生效应研究[J]. 植物营养与肥料学报, 2024, 30(2):394-405.
[40]	刘美灵, 汪益民, 金文豪, 等. 厨余垃圾有机肥对土壤微生物活性及功能的影响[J]. 环境科学, 2024, 45(1):530-542.
[41]	SHU X Y, LIU W J, HUANG H, et al. Meta-analysis of organic fertilization effects on soil bacterial diversity and community composition in agroecosystems[J]. Plants, 2023, 12(22): 3 801.
[42]	张湑泽, 王雪韧, 杜萌, 等. 青海干旱盐碱地区不同生境土壤微生物多样性分析[J]. 西北农业学报, 2025, 34(2):309-318.
[43]	张淼, 刘俊杰, 刘株秀, 等. 黑土区农田土壤氮循环关键过程微生物基因丰度的分布特征[J]. 土壤学报, 2022, 59(5):1 258-1 269.
[44]	马艳丽, 李海红, 宾齐. 耐盐染料降解菌群驯化及其微生物群落分析[J]. 工业水处理, 2023, 43(4):78-84.
[45]	SUN C, ZHENG H, HE S X, et al. Partial substitution of chemical fertilizer by organic fertilizer increases yield, quality and nitrogen utilization of Dioscorea polystachya[J]. PLoS One, 2024, 19(4): e0301108.
[46]	李丽, 檀文炳, 王国安, 等. 腐殖质电子传递机制及其环境效应研究进展[J]. 环境化学, 2016, 35(2):254-266.
[47]	杨彦明, 周祎, 张子健, 等. 腐殖酸与不同耕作措施对盐碱土碳库和微生物群落结构的影响[J]. 作物杂志, 2024(1):157-165.
[48]	王晓丽, 安梦洁, 张春媛, 等. 改良剂调控盐碱胁迫对棉田土壤微生物多样性的影响[J]. 石河子大学学报(自然科学版), 2022, 40(2):180-187.
[49]	XU S W, YUAN M, CHAPMAN S J, et al. Bio-converted organic wastes shape microbiota in maize rhizosphere: Localization and identification in enzyme hotspots[J]. Soil Biology and Biochemistry, 2023, 184: 109 105.
[50]	XIE X Y, LI H M, CHEN X P, et al. Rhizosphere phosphatase hotspots: Microbial-mediated P transformation mechanisms influenced by maize varieties and phosphorus addition[J]. Plant and Soil, 2025, 512(1): 1 577-1 593.
[51]	SHI S H, TIAN L, NASIR F, et al. Response of microbial communities and enzyme activities to amendments in saline-alkaline soils[J]. Applied Soil Ecology, 2019, 135: 16-24.
[52]	刘中良, 高俊杰, 谷端银, 等. 有机肥对设施番茄周年栽培土壤环境和产量的影响[J]. 应用生态学报, 2020, 31(3):929-934.
[53]	MOE K, HTWE A Z, THU T T P, et al. Effects on NPK status, growth, dry matter and yield of rice (Oryza sativa) by organic fertilizers applied in field condition[J]. Agriculture, 2019, 9(5): 109.
[54]	CHEN M M, ZHANG S R, LIU L, et al. Combined organic amendments and mineral fertilizer application increase rice yield by improving soil structure, P availability and root growth in saline-alkaline soil[J]. Soil and Tillage Research, 2021, 212: 105 060.
[55]	ZHANG J N, ZHOU S, SUN H F, et al. Three-year rice grain yield responses to coastal mudflat soil properties amended with straw biochar[J]. Journal of Environmental Management, 2019, 239: 23-29.
[56]	FAROOQ M, RAFIQUE S, ZANRA N, et al. Root system architecture and salt stress responses in cereal crops[J]. Journal of Agronomy and Crop Science, 2024, 210(6): e12776.
[57]	WU G Q, WANG S M. Calcium regulates K⁺/Na⁺ homeostasis in rice (Oryza sativa L.) under saline conditions[J]. Plant, Soil and Environment, 2012, 58(3): 121-127.
[58]	周明园. Cl^-对水稻幼苗生长、根系形态和K⁺吸收的影响[D]. 扬州: 扬州大学, 2015.
[59]	冯凯月, 赵鑫焱, 李子妍, 等. 植物响应盐碱胁迫的分子机制研究进展[J]. 生物技术通报, 2024, 40(10):122-138.
[60]	ZHAO S S, ZHANG Q K, LIU M Y, et al. Regulation of plant responses to salt stress[J]. International Journal of Molecular Sciences, 2021, 22(9): 4 609.
[61]	朱旺, 张徐彬, 耿孝宇, 等. 盐害和干旱影响水稻根系形态生理和产量形成及其机制研究进展[J]. 中国稻米, 2023, 29(3):34-40.
[62]	朱旺, 张翔, 耿孝宇, 等. 盐-旱复合胁迫下水稻根系的形态和生理特征及其与产量形成的关系[J]. 中国水稻科学, 2023, 37(6):617-627.
[63]	KHAN M T, ALEINIKOVIENE J, BUTKEVICIENE L M. Innovative organic fertilizers and cover crops: Perspectives for sustainable agriculture in the Era of climate change and organic agriculture[J]. Agronomy, 2024, 14(12): 2 871.
[64]	JIANG D, LU B, LIU L T, et al. Exogenous melatonin improves salt stress adaptation of cotton seedlings by regulating active oxygen metabolism[J]. PeerJ, 2020, 8: e10486.
[65]	WANG R J, DONG X, GAO Y, et al. Molecular mechanism of exogenous magnesium in regulating cation homeostasis in roots of peanut seedlings under salt stress[J]. Agronomy, 2024, 14(4): 724.
[66]	李开叶, 赵婷婷, 陈佳, 等. 不同有机物料对水稻根表铁膜及砷镉吸收转运的影响[J]. 环境科学, 2021, 42(4):2 047-2 055.
[67]	LIU C Y, JIANG X B, YUAN Z H. Plant responses and adaptations to salt stress: A review[J]. Horticulturae, 2024, 10(11): 1 221.
[68]	王亚新, 冯乃杰, 赵黎明, 等. 植物生长调节剂与氮肥对盐胁迫下水稻幼苗生理特性的影响[J]. 核农学报, 2024, 38(3):561-573.
[69]	WANG X M, CHEN Z T, SUI N. Sensitivity and responses of chloroplasts to salt stress in plants[J]. Frontiers in Plant Science, 2024, 15: 1 374 086.
[70]	LOBO A K M, ORR D J, CARMO-SILVA E. Regulation of rubisco activity by interaction with chloroplast metabolites[J]. Biochemical Journal, 2024, 481(15): 1 043-1 056.
[71]	SONG Y S, DONG M H, GU J R, et al. Synergistic effects of combined foliar fertilizers on growth, stress tolerance, and yield of high-quality japonica rice[J]. International Journal of Plant Production, 2025, 19(2): 255-268.
[72]	束晨晨, 周天阳, 顾逸彪, 等. 盐胁迫下喷施外源γ-氨基丁酸对不同耐盐性水稻生长及产量的影响[J]. 中国稻米, 2025, 31(2):35-42.
[73]	CUI H, HOU S N, WANG X Y, et al. Organic fertilizer-mediated cultivated land conservation and pollution source control in agricultural ecosystem, Northeast China[J]. Environmental Technology & Innovation, 2025, 37: 103 945.
[74]	MTHIYANE P, AYCAN M, MITSUI T. Integrating biofertilizers with organic fertilizers enhances photosynthetic efficiency and upregulates chlorophyll-related gene expression in rice[J]. Sustainability, 2024, 16(21): 9 297.
[75]	韦还和, 马唯一, 左博源, 等. 盐、干旱及其复合胁迫对水稻产量和品质形成影响的研究进展[J]. 中国水稻科学, 2024, 38(4):350-363.
[76]	潘晓飚, 谢留杰, 黄善军, 等. 杂交水稻不同生育阶段的耐盐性及育种策略[J]. 江苏农业科学, 2017, 45(6):56-60.
[77]	张稳, 彭锐, 袁定阳, 等. 多穗型杂交稻在不同肥力下生长与产量表现研究[J]. 杂交水稻, 2024, 39(1):102-111.
[78]	李旭, 付立东, 王宇, 等. 不同时期水分胁迫对水稻生长发育和产量的影响[J]. 江苏农业科学, 2017, 45(7):70-73.
[79]	陈光, 李佳, 杜瑞英, 等. 水稻盐敏感突变体ss2的鉴定与基因功能分析[J]. 生物技术通报, 2022, 38(9):158-166.
[80]	HOU M M, ZHANG Y B, XU X Y, et al. Advances in auxin synthesis, transport, and signaling in rice: implications for stress resilience and crop improvement[J]. Frontiers in Plant Science, 2025, 15: 1516 884 .
[81]	潘晶, 黄翠华, 彭飞, 等. 植物根际促生菌诱导植物耐盐促生作用机制[J]. 生物技术通报, 2020, 36(9):75-87.
[82]	ZHANG Z H, LIU Q, SONG H X, et al. Responses of different rice (Oryza sativa L.) genotypes to salt stress and relation to carbohydrate metabolism and chlorophyll content[J]. African Journal of Agricultural Reseearch, 2012, 7(1): 19-27.
[83]	WANG X, MA G H, FENG N J, et al. Abscisic acid can improve the salt tolerance and yield of rice by improving its physiological characteristics[J]. Agronomy, 2025, 15(2): 309.
[84]	LIU C T, MAO B G, YUAN D Y, et al. Salt tolerance in rice: Physiological responses and molecular mechanisms[J]. The Crop Journal, 2022, 10(1): 13-25.
[85]	谭颖, 袁定阳, 官志祥, 等. 籼稻耐盐不育系的筛选及其生理分析[J]. 杂交水稻, 2023, 38(2):25-31.
[86]	韦还和, 张翔, 朱旺, 等. 盐胁迫对水稻籽粒灌浆特性及产量形成的影响[J]. 作物学报, 2024, 50(3):734-746.
[87]	KUMAR A, SHEORAN P, KUMAR N, et al. Elucidating morphogenic and physiological traits of rice with nitrogen substitution through nano-nitrogen under salt stress conditions[J]. BMC Plant Biology, 2024, 24(1): 908.
[88]	李明, 张俊华. 不同施肥模式对盐碱化稻作土壤细菌群落的影响[J]. 干旱地区农业研究, 2018, 36(5):142-148.
[89]	ZHENG E N, QIN M T, ZHANG Z X, et al. Humic acid fertilizer incorporation increases rice radiation use, growth, and yield: A case study on the Songnen Plain, China[J]. Agriculture, 2022, 12(5): 653.
[90]	唐奇志, 汪帆, 时金泽, 等. 有机肥部分替代氮肥的盐碱土壤改良与水稻增产效应研究[J]. 土壤, 2024, 56(1):97-102.
[91]	魏文良, 刘路, 仇恒浩. 有机无机肥配施对我国主要粮食作物产量和氮肥利用效率的影响[J]. 植物营养与肥料学报, 2020, 26(8):1 384-1 394.
[92]	翟彩娇, 邓先亮, 张蛟, 等. 盐分胁迫对稻米品质性状的影响[J]. 中国稻米, 2020, 26(2):44-48.
[93]	CHOMPA S S, ZUAN A T K, AMIN A M, et al. Growth and protein response of rice plant with plant growth-promoting rhizobacteria inoculations under salt stress conditions[J]. International Microbiology, 2024, 27(4): 1 151-1 168.
[94]	肖丹丹, 李军, 邓先亮, 等. 不同品种稻米品质形成对盐胁迫的响应[J]. 核农学报, 2020, 34(8):1 840-1 847.
[95]	杨胜玲, 黄兴成, 刘彦伶, 等. 长期有机肥无机肥配施对水稻氮素吸收、转运及产量的影响[J]. 中国稻米, 2021, 27(6):63-68.
[96]	刘红江, 郭智, 张岳芳, 等. 不同类型有机肥对水稻产量和稻米品质的影响[J]. 江苏农业学报, 2024, 40(4):645-651.
[97]	付旭坤, 刘宝龙, 高大鹏, 等. 地膜覆盖与肥料种类对寒地水稻产量和品质的影响[J]. 中国农业大学学报, 2022, 27(10):87-99.
[98]	TAO W L, ZHANG Y J, GU J F, et al. The synergistic optimization of rice yield, quality, and profit by the combined application of organic and inorganic nitrogen fertilizers[J]. Agronomy, 2024, 14(11): 2 665.

Effects of Organic Fertilizer Application on Soil Physicochemical Properties and Rice Growth and Development in Saline-Alkali Land

有机肥施用对盐碱地土壤理化特性和水稻生长发育的影响

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 1

References 98

Related Articles 15

Recommended Articles

Metrics

[1]	WANG Hua, CHU Guang. Practices and Reflections on Increasing Large-Area Per-Unit Yield of Rice in a Mountainous County of Southeast Guizhou——A Case Study of Taijiang County [J]. China Rice, 2026, 32(1): 1-5.
[2]	LIN Zhijian, LIN Chengbao, TANG Jiangxia, DENG Zeqin, HUANG Xianbo, SU Rongli. Resistance Mechanism of Rice Carrying Pyramided Bph14 and Bph15 Genes to Brown Planthopper [J]. China Rice, 2026, 32(1): 102-106.
[3]	ZHANG He, SHI Jiawei, GAO Jianmiao, XUE Zhankui, FU Liqing, Liu Kaili. Effects of Different Planting Densities and Nitrogen Application Rates on Yield and Nitrogen Use Efficiency of the Rice Noodle Variety Zhongzu 237 [J]. China Rice, 2026, 32(1): 107-112.
[4]	ZHOU Yujie, LUO Qin, LI Runjing, CAO Zijian, JIANG Nan. [J]. China Rice, 2026, 32(1): 113-117.
[5]	CHEN Jie, WANG Gaofeng. Research on the Bottlenecks and Countermeasures of “Jiaxing Rice” Brand Construction [J]. China Rice, 2026, 32(1): 118-122.
[6]	SHANG Quanyu, LIU Youhong, LIN Jingyan, LIU Anjin, WANG Song, ZHANG Wenzhong. Research on Adaptability and Development Strategies of the Rice Industry in High-Latitude and High-Altitude Regions under Climate Change [J]. China Rice, 2026, 32(1): 12-15.
[7]	SUN Yuyan, LI Xin, CUI Xiaohong. Analysis of New Rice Variety Breeding and High-Quality Rice Industry Development in Xing'an League [J]. China Rice, 2026, 32(1): 123-126.
[8]	ZHANG Manli, ZHENG Wenjing. Development and Prospects of Hybrid Japonica Rice in Northern China Over the Past 50 Years [J]. China Rice, 2026, 32(1): 16-20.
[9]	LI Zhouwei, YIN Qianyu, YE Changrong, CHENG Jihua, WANG Sizhe, CHEN Hailong, LI Changhong, ZHANG Yan, LONG Yu, CAI Shanshan, WU Yuntian, JIA Gaofeng, TIAN Bingchuan. Identification of Low Cadmium Accumulation and Drought Tolerance in Rice Germplasm and Gene Mining [J]. China Rice, 2026, 32(1): 20-25.
[10]	NIU Fuan, ZHANG Anpeng, CHENG Can, SUN Bin, CHU Huangwei, ZHOU Jihua, DAI Yuting, ZHANG Jianming, FANG Jun, XIE Kaizhen, CAO Liming. Research Progress and Prospect in Genetic Improvement of Salt Alkali Tolerant Rice [J]. China Rice, 2026, 32(1): 26-29.
[11]	ZHUANG Haifeng, LIN Zhouyang, RAO Cong, CHI Yongqing. Effects of Co-Pyrolyzed Biochar from Straw and Pig Manure on Soil Fertility and Rice Yield [J]. China Rice, 2026, 32(1): 30-38.
[12]	XIN Yuwei, CAO Tiehua, LI Shanlong, ZHAO Xin, LI Tao, LI Yutong, YANG Yutong, LIANG Xuanhe. Long-Term Positioning Research of Combined Application of Organic and Inorganic Fertilizers on Rice Production and Soil Nutrient Changes in Cold and Cool Regions [J]. China Rice, 2026, 32(1): 47-54.
[13]	GONG Yanlong, LEI Yue, WANG Zhongni, ZHU Susong. Effects of Combined Application of Biological Organic Fertilizer and Nitrogen Fertilizer on the Quality Traits of Dalixiang and Its Relationship with Panicle Type Index [J]. China Rice, 2026, 32(1): 55-63.
[14]	CHEN Liang, CHEN Yong, YUAN Chi, CAO Houming, LUO Tao. Integration and Innovation of High-Quality and High-Yield Rice Cultivation Technology in the Hilly Regions of Southwest China——Zizhong, Sichuan for Example [J]. China Rice, 2026, 32(1): 6-11.
[15]	GUO Jinquan, ZHOU Youjun. Effects of Combined Application of Jinggangmycin and Nano-Silicon Fertilzer on Photosynthetic Characteristics, Defense Enzyme Activities, and Control Efficacy Against Rice Sheath Blight [J]. China Rice, 2026, 32(1): 64-69.