Effects of Partial Substitution of Organic Nitrogen Fertilizer for Chemical Nitrogen Fertilizer on Rice Yield and Quality

doi:10.11924/j.issn.1000-6850.casb2023-0445

Abstract

Abstract:

To evaluate the application effect of organic fertilizer instead of chemical fertilizer and to provide scientific basis for formulating reasonable fertilizer cultivation measures, the effects of different proportions of organic fertilizer instead of nitrogen on soil fertility, rice yield and rice quality were studied by field location monitoring. The experiment site was located in the experimental base of Hunan Academy of Agricultural Sciences, Gaoqiao Town, Changsha County, Hunan Province, and four treatments were set up: NPK; 15% organic fertilizer replacement treatment (15M); 30% organic fertilizer replacement treatment (30M); 60% organic fertilizer replacement treatment (60M). After rice harvest, soil pH, total nitrogen, alkali-hydrolyzable nitrogen, total phosphorus, available phosphorus, total potassium, available potassium of 0-20 cm soil layer and rice yield and rice quality were measured. The results showed that the average annual yield followed the order of NPK<15M<30M<60M, the yield of 60M was significantly higher than that of NPK and 15M, increasing by 15.99% and 8.71%, respectively. Compared with NPK, 60M increased rice gum consistency, amylose and protein content by 4.72%, 7.15% and 10.67%, respectively. 30M and 60M increased soil total nitrogen, organic matter, alkali-hydrolyzed nitrogen, available phosphorus and available potassium contents. Partial substitution of organic nitrogen fertilizer for chemical nitrogen fertilizer could promote rice yield and improve rice quality by increasing soil organic matter and total nitrogen content. Under the experimental conditions, 60% organic fertilizer was the best substitute treatment.

Key words: organic fertilizer instead of chemical fertilizer, rice yield, rice quality, soil fertility

GAO Peng, LEI Xingyu, LU Yaoxiong, PENG Fuyuan, CUI Xinwei. Effects of Partial Substitution of Organic Nitrogen Fertilizer for Chemical Nitrogen Fertilizer on Rice Yield and Quality[J]. Chinese Agricultural Science Bulletin, 2024, 40(13): 1-6.

Figures/Tables 4

References 29

[1]	韩天富, 马常宝, 黄晶, 等. 基于Meta分析中国水稻产量对施肥的响应特征[J]. 中国农业科学, 2019, 52(11):1918-1929. doi: 10.3864/j.issn.0578-1752.2019.11.007
[2]	韩雪梅, 杨林章, 俞映倞, 等. 配方施肥对水稻生产和经济,环境效益的影响[J]. 农业环境科学学报, 2021, 40(12): 2614-2622.
[3]	闫湘, 金继运, 梁鸣早, 等. 我国主要粮食作物化肥增产效应与肥料利用效率[J]. 土壤, 2017, 49(6):1067-1077.
[4]	DU S, GE A H, LIANG Z H, et al. Fumigation practice combined with organic fertilizer increase antibiotic resistance in watermelon rhizosphere soil[J]. Science of the total environment, 2022,805:150426.
[5]	LI Q, ZHANG D, SONG Z, et al. Organic fertilizer activates soil beneficial microorganisms to promote strawberry growth and soil health after fumigation[J]. Environmental pollution, 2022,295.
[6]	夏思瑶, 王冲, 王新宇. 施用有机肥对生菜产量和品质影响的Meta分析[J]. 中国土壤与肥料, 2021(6):7-9.
[7]	沈仕洲, 王风, 薛长亮, 等. 施用有机肥对农田温室气体排放影响研究进展[J]. 中国土壤与肥料, 2015(6):1-7.
[8]	林治安, 赵秉强, 袁亮, 等. 长期定位施肥对土壤养分与作物产量的影响[J]. 中国农业科学, 2009, 42(8):2809-2819.
[9]	宁建凤, 邹献中, 杨少海, 等. 有机无机氮肥配施对土壤氮淋失及油麦菜生长的影响[J]. 农业工程学报, 2007, 23(11):95-100.
[10]	徐明岗, 李冬初, 李菊梅, 等. 化肥有机肥配施对水稻养分吸收和产量的影响[J]. 中国农业科学, 2008, 41(10):3133-3139.
[11]	梁元振, 赵京考, 吴德亮, 等. 秋施有机肥对土壤生物学、理化性状及玉米产量的影响[J]. 水土保持研究, 2017, 24(3):113-118.
[12]	崔新卫, 张杨珠, 高菊生, 等. 长期不同施肥处理对红壤稻田土壤性质及晚稻产量与品质的影响[J]. 华北农学报, 2019, 34(6):190-197. doi: 10.7668/hbnxb.20190052
[13]	任凤玲. 施用有机肥我国典型农田土壤温室气体排放特征[D]. 北京: 中国农业科学院, 2018.
[14]	鲍士旦. 土壤农化分析[M]. 北京: 中国农业出版社, 2000.
[15]	姜玲玲, 刘静, 赵同科, 等. 有机无机配施对番茄产量和品质影响的Meta分析[J]. 植物营养与肥料学报, 2019, 25(4):601-610.
[16]	王静, 王磊, 刘耀斌, 等. 长期施用不同有机肥对甘薯产量和土壤生物性状的影响[J]. 水土保持学报, 2021, 35(2):184-192.
[17]	QASWAR M, JING H, AHMED W, et al. Yield sustainability, soil organic carbon sequestration and nutrients balance under long-term combined application of manure and inorganic fertilizers in acidic paddy soil[J]. Soil and tillage research, 2020,198:104569.
[18]	XIA Y, CHEN X, ZHENG S, et al. Manure application accumulates more nitrogen in paddy soils than rice straw but less from fungal necromass[J]. Agriculture ecosystems & environment, 2021,319:107575.
[19]	郭振, 王小利, 徐虎, 等. 长期施用有机肥增加黄壤稻田土壤微生物量碳氮[J]. 植物营养与肥料学报, 2017, 23(5):1168-1174.
[20]	杨修一, 耿计彪, 于起庆, 等. 有机肥替代化肥氮素对麦田土壤碳氮迁移特征的影响[J]. 水土保持学报, 2019, 33(5):230-236.
[21]	WANG Q, WEN J, WEN Y, et al. Alteration of soil-surface electrochemical properties by organic fertilization to reduce dissolved inorganic nitrogen leaching in paddy fields[J]. Soil and tillage research, 2021,209:104956.
[22]	丁维婷, 武雪萍, 张继宗, 等. 长期有机无机配施对暗棕壤土壤酶活性及春麦产量品质的影响[J]. 中国土壤与肥料, 2020(6):1-8.
[23]	ZHANG M, YAO Y L, TIAN Y H, et al. Increasing yield and N use efficiency with organic fertilizer in chinese intensive rice cropping systems[J]. Field crops research, 2018,227:102-109.
[24]	EAGLE A J, BIRD J A, HORWATH W R, et al. Rice yield and nitrogen utilization efficiency under alternative straw management practices[J]. Agronomy journal, 2000, 92(6):1096-1103. doi: 10.2134/agronj2000.9261096x URL
[25]	QASWAR M, JING H, AHMED W, et al. Long-term green manure rotations improve soil biochemical properties, yield sustainability and nutrient balances in acidic paddy soil under a rice-based cropping system[J]. Agronomy journal, 2019, 9(12):780.
[26]	鲁艳红, 廖育林, 周兴, 等. 长期不同施肥对红壤性水稻土产量及基础地力的影响[J]. 土壤学报, 2015, 52(3):597-606.
[27]	徐一兰, 唐海明, 程爱武, 等. 长期不同施肥模式对双季稻田土壤养分及水稻产量的影响[J]. 华北农学报, 2017, 32(6):192-197. doi: 10.7668/hbnxb.2017.06.028
[28]	WANG H X, XING J, XUE J L, et al. Effects of long-term application of organic fertilizer on improving organic matter content and retarding acidity in red soil from china[J]. Soil and tillage research, 2019,195:104382.
[29]	LIU J, SHU A, SONG W, et al. Long-term organic fertilizer substitution increases rice yield by improving soil properties and regulating soil bacteria[J]. Geoderma, 2021,404:115287.

处理	糙米率	精米率	整精米率	垩白粒率	垩白度	胶稠度	直链淀粉	蛋白质
NPK	80.01±1.25a	65.89±0.90a	57.03±0.11a	28.90±1.03a	2.90±0.19a	79.06±0.24b	12.16±0.10b	8.15±0.09b
15M	79.87±0.11a	65.85±1.11a	58.51±0.30a	28.99±0.75a	2.93±0.15a	79.13±0.10b	12.44±0.11b	8.55±0.17ab
30M	80.03±1.01a	66.11±0.42a	60.05±1.36a	28.92±0.69a	2.96±0.19a	81.65±0.29a	12.91±0.11ab	8.93±0.09a
60M	80.15±1.90a	66.07±0.81a	59.72±0.64a	28.87±0.48a	2.91±0.12a	82.79±0.39a	13.03±0.08a	9.02±0.21a

处理	糙米率	精米率	整精米率	垩白粒率	垩白度	胶稠度	直链淀粉	蛋白质
NPK	80.01±1.25a	65.89±0.90a	57.03±0.11a	28.90±1.03a	2.90±0.19a	79.06±0.24b	12.16±0.10b	8.15±0.09b
15M	79.87±0.11a	65.85±1.11a	58.51±0.30a	28.99±0.75a	2.93±0.15a	79.13±0.10b	12.44±0.11b	8.55±0.17ab
30M	80.03±1.01a	66.11±0.42a	60.05±1.36a	28.92±0.69a	2.96±0.19a	81.65±0.29a	12.91±0.11ab	8.93±0.09a
60M	80.15±1.90a	66.07±0.81a	59.72±0.64a	28.87±0.48a	2.91±0.12a	82.79±0.39a	13.03±0.08a	9.02±0.21a

处理	pH	有机质/(g/kg)	全氮/(g/kg)	碱解氮/(mg/kg)	全磷/(g/kg)	有效磷/(mg/kg)	全钾/(g/kg)	速效钾/(mg/kg)
NPK	6.05±0.31a	27.14±0.90b	1.83±0.004c	244.64±6.65b	0.63±0.03a	5.06±0.85b	17.38±0.25a	91.31±24.01b
15M	6.16±0.13a	27.14±2.09b	1.88±0.11bc	250.95±6.43ab	0.61±0.07a	4.99±0.45b	17.57±0.49a	87.33±16.09b
30M	6.10±0.29a	30.55±2.41ab	2.01±0.08b	262.04±7.45a	0.63±0.06a	5.48±1.35a	17.96±0.42a	100.76±41.73ab
60M	6.02±0.08a	33.12±1.03a	2.11±0.08a	260.53±9.08a	0.69±0.03a	5.78±0.33a	18.20±0.49a	119.16±20.69a

处理	pH	有机质/(g/kg)	全氮/(g/kg)	碱解氮/(mg/kg)	全磷/(g/kg)	有效磷/(mg/kg)	全钾/(g/kg)	速效钾/(mg/kg)
NPK	6.05±0.31a	27.14±0.90b	1.83±0.004c	244.64±6.65b	0.63±0.03a	5.06±0.85b	17.38±0.25a	91.31±24.01b
15M	6.16±0.13a	27.14±2.09b	1.88±0.11bc	250.95±6.43ab	0.61±0.07a	4.99±0.45b	17.57±0.49a	87.33±16.09b
30M	6.10±0.29a	30.55±2.41ab	2.01±0.08b	262.04±7.45a	0.63±0.06a	5.48±1.35a	17.96±0.42a	100.76±41.73ab
60M	6.02±0.08a	33.12±1.03a	2.11±0.08a	260.53±9.08a	0.69±0.03a	5.78±0.33a	18.20±0.49a	119.16±20.69a

	胶稠度	直链淀粉	蛋白质	有机质	全氮	碱解氮	全磷	有效磷	全钾	速效钾	pH
产量	0.675^*	0.720^**	0.737^**	0.699^*	0.688^*	0.505	-0.153	0.123	0.456	0.57	-0.133
胶稠度	1	0.938^**	0.834^**	0.871^**	0.890^**	0.703^*	0.118	0.425	0.675^*	0.491	-0.34
直链淀粉		1	0.939^**	0.835^**	0.862^**	0.751^**	-0.037	0.381	0.53	0.503	-0.226
蛋白质			1	0.712^**	0.787^**	0.684^*	-0.143	0.312	0.495	0.511	-0.145
有机质				1	0.961^**	0.764^**	0.414	0.546	0.463	0.583^*	-0.383
全氮					1	0.820^**	0.403	0.57	0.56	0.596^*	-0.347
碱解氮						1	0.358	0.637^*	0.481	0.422	-0.018
全磷							1	0.606^*	0.142	0.213	-0.205
有效磷								1	0.218	0.251	-0.287
全钾									1	0.058	-0.229
速效钾										1	0.3