Crops ›› 2025, Vol. 41 ›› Issue (2): 149-154.doi: 10.16035/j.issn.1001-7283.2025.02.021

Previous Articles     Next Articles

Effects of Different Controlled-Release Urea on Agronomic Traits, Yield and Nitrogen Use Efficiency of Cold Region Rice

Ji Jinghong(), Liu Shuangquan, Ma Xingzhu, Hao Xiaoyu, Zheng Yu, Zhao Yue, Wang Xiaojun, Kuang Enjun   

  1. Heilongjiang Academy of Black Soil Conservation and Utilization / Key Laboratory of Black Soil Protection and Utilization / Ministry of Agriculture and Rural Areas / The Key Lab of Soil Environment and Plant Nutrition / Research Center of Fertilizer Engineering and Technology of Heilongjian Province, Harbin 150086, Heilongjiang, China
  • Received:2023-12-25 Revised:2024-02-04 Online:2025-04-15 Published:2025-04-16

RichHTML

2

PDF (PC)

19

Abstract:

In a two-year field experiments, the effects of different controlled-release urea (CRU) and urea application methods on agronomic characteristics, yield, and nitrogen utilization efficiency of rice in the cold region of Heilongjiang were studied. The results showed that under the condition of a single basal application of nitrogen fertilizer, compared with urea (BU), CRU60 (controlled-release period of 60 days) and CRU90 (controlled-release period of 90 days), there was no significant difference in the number of effective tillers and panicles. The 1000-grain weight significantly increased. Especially, the number of grains per panicle was significantly increased, resulting in an average yield increase of 6.4%, and 7.5 percentage points increase in nitrogen fertilizer utilization efficiency in the CRU90 treatment. The rice grain number, yield and nitrogen utilization efficiency did not show significant differences under the CRU60 treatment. Compared with the treatment of applying urea once as basal fertilizer and twice as topdressing (CF), the 1000-grain weight was significantly increased under CRU60 and CRU90 treatments. The CRU60 treatment significantly reduced the number of filled-grains per panicle, with an average yield decrease of 10.6%, and the nitrogen fertilizer utilization efficiency decreased by 7.4 percentage points. There was no significant difference between CRU90 and CF treatments in the number of effective tillers, effective panicle number, grain number per panicle, yield and nitrogen utilization efficiency. In the rice production in the first and second accumulated temperature zones of Heilongjiang, controlled-release urea was more beneficial to rice yield and fertilizer utilization than common urea under the same treatment conditions. Under the condition of no lateral deep fertilization, the urea with longer controlled release period (90 days) should be selected preferentially.

Key words: Rice, Controlled-released urea, Agronomic traits, Yield, Nitrogen use efficiency

Table 1

Basic chemical property in the topsoil"

地点
Site		 pH 有机质
Organic matter (g/kg)		 全氮
Total N (g/kg)		 速效氮
Available N (mg/kg)		 速效磷
Available P (mg/kg)		 速效钾
Available K (mg/kg)
方正县Fangzheng 5.57 34.6 1.7 161.2 43.5 173.2
阿城区Acheng 5.82 29.3 1.5 115.6 19.6 145.8

Fig.1

The cumulative nitrogen release rate of controlled release urea with 60 days controlled period in 25 ℃"

Fig.2

The cumulative nitrogen release rate of controlled release urea with 90 days controlled period in 25 ℃"

Table 2

Effects of different treatments on rice agronomic traits"

地点
Site		 年份
Year		 处理
Treatment		 株高
Plant
height (cm)		 穗长
Panicle length
(cm)		 有效分蘖数(/穴)
Number of effective
tillers (/hole)		 有效穗数
Effective
panicles (m2)		 千粒重
1000-grain
weight (g)		 穗实粒数
Filled grain
per panicle		 穗粒数
Grain number
per panicle		 结实率
Seed-setting
rate (%)
方正Fangzheng 2019 N0 90.2b 16.8b 13.8c 289.6c 26.3a 83.1c 86.9c 95.6a
CF 102.2a 21.6a 16.0a 335.6a 24.5c 138.3a 144.1a 96.0a
BU 106.3a 21.2a 15.2ab 318.7ab 24.9c 131.2ab 138.4ab 94.8a
CRU60 100.5a 20.7a 15.0b 310.5b 25.5b 128.3b 132.5b 96.8a
CRU90 103.1a 20.8a 15.1ab 316.7ab 25.6b 134.4a 139.4a 96.4a
2020 N0 92.3b 15.8b 15.8c 331.8c 25.2a 72.1c 75.5c 95.5a
CF 106.3a 18.5a 18.6a 391.5a 23.5c 115.5a 120.7a 95.7a
BU 107.6a 18.6a 17.4b 366.4b 24.1c 107.3ab 113.9ab 94.2a
CRU60 104.2a 17.7a 17.2b 361.2b 24.7ab 106.3b 111.5b 95.3a
CRU90 104.7a 17.8a 17.7ab 371.9ab 24.5b 113.2a 117.4a 96.4a
阿城Acheng 2019 N0 88.8b 16.4b 13.5b 282.8b 26.5a 82.1c 84.7c 96.9a
CF 97.9a 20.9a 15.3a 322.3a 25.1bc 135.0a 139.8a 96.6a
BU 101.0a 20.7a 15.5a 325.1a 24.9c 121.8b 128.0b 95.2a
CRU60 100.3a 20.5a 15.2a 319.4a 25.5b 120.1b 124.4b 96.5a
CRU90 101.6a 20.4a 14.9a 318.4a 25.6b 132.1a 136.5a 96.8a
2020 N0 90.6b 15.6b 14.9b 313.4b 25.6a 68.5c 71.3c 96.1a
CF 104.2a 18.1a 17.3a 362.8a 24.1bc 115.5a 120.7a 95.7a
BU 104.9a 17.9a 16.6a 349.2a 23.8c 106.3b 113.8b 93.4b
CRU60 103.6a 17.6a 16.7a 350.4a 24.6b 104.3b 108.9b 95.8a
CRU90 104.5a 17.5a 16.4a 345.4a 24.8b 112.0a 116.8a 96.1a

Fig.3

Effects of different treatments on rice yield Different lowercase letters indicate significant difference at P < 0.05 level."

Table 3

Nitrogen uptake and nitrogen use efficiency of rice under different treatments"

地点
Site		 处理
Treatment		 植株吸氮量Nitrogen absorbing amount by plants (kg/hm2) 氮肥利用率Nitrogen use efficiency (%)
2019 2020 平均Mean 2019 2020 平均Mean
方正Fangzheng N0 110.3c 106.5c 108.4
CF 164.1a 168.6a 166.4 32.6a 37.6a 35.1
BU 154.2b 155.3b 154.8 26.6b 29.6c 28.1
CRU60 152.3b 157.8b 155.1 25.5b 31.1bc 28.3
CRU90 160.9a 164.3a 162.6 30.7a 35.0ab 32.9
阿城Acheng N0 98.7c 100.6c 99.7
CF 159.7a 168.1a 163.9 37.0a 40.9a 39.0
BU 146.1b 144.2b 145.2 28.7b 26.4b 27.6
CRU60 150.2b 151.3b 150.8 31.2bc 30.7b 31.0
CRU90 158.2a 165.9a 162.1 36.1ab 39.6a 37.9

Table 4

Economic benefit increment of rice of different fertilization treatments 元/hm2 yuan/hm2"

处理
Treatment		 方正Fangzheng 阿城Acheng
2019 2020 2019 2020
N0
CF 9726a 9108a 10 622a 8777a
BU 7572bc 6741bc 8012bc 6088bc
CRU60 6473c 6294c 7271c 5995c
CRU90 8151b 8352ab 9131ab 7154b
[1] 符建荣. 控释氮肥对水稻的增产效应及提高肥料利用率的研究. 植物营养与肥料学报, 2001, 7(2):145-152.
[2] 彭晓宗. 东北单季稻区氮肥施用特征与减施潜力研究. 北京: 中国农业科学院, 2021.
[3] 黄巧义, 唐拴虎, 张发宝, 等. 减氮配施控释尿素对水稻产量和氮肥利用的影响. 中国生态农业学报, 2017, 25(6):829-838
[4] 徐明岗, 李菊梅, 李冬初, 等. 控释氮肥对双季水稻生长及氮肥利用率的影响. 植物营养与肥料学报, 2009, 15(5):1010-1015.
[5] Ye Y S, Liang X Q, Chen Y X, et al. Alternate wetting and drying irrigation and congtrolled-release nitrogen fertilizer in late-season rice. Effects on dry matter accumulation, yield, water and nitrogen use. Field Crops Research, 2013,144:212-224.
[6] 朱宝国, 马晓明, 张春峰, 等. 控释氮肥对寒地水稻植株和土壤氮素含量及产量的影响. 农学学报, 2014, 4(1):25-28.
[7] 张迪, 吕思琪, 徐文越, 等. 侧深施控释肥下寒地粳稻产量形成及氮素利用特性. 中国土壤与肥料, 2021(2):213-220.
[8] 马昕, 杨艳明, 刘智蕾, 等. 机械侧深施控释掺混肥提高寒地水稻的产量和效益. 植物营养与肥料学报, 2017, 23(4):1095-1103.
[9] 马晓明, 朱宝国, 徐显国, 等. 控释氮肥对寒地水稻生长发育及产量的影响. 农学学报, 2013, 3(3):1-3.
[10] 鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2007.
[11] 凌启鸿. 水稻精确定量栽培理论与技术. 北京: 中国农业出版社, 2007.
[12] 蒋琪, 陈少杰, 王飞, 等. 不同缓(控)释肥料及运筹对双季稻生产特性及经济效益的影响. 中国稻米, 2021, 27(1):85-88.
doi: 10.3969/j.issn.1006-8082.2021.01.016
[13] 付月君, 王昌全, 李冰, 等. 控释氮肥与尿素配施对单季稻产量及氮肥利用率的影响. 土壤, 2016, 48(4):648-652.
[14] 彭显龙, 潘新杰, 秦迎春, 等. 基蘖肥氮量与寒地水稻产量和氮效率的关系. 中国土壤与肥料, 2016(2):72-77.
[15] 董明辉, 张洪程, 戴其根, 等. 不同粳稻品种氮素吸收利用特点的研究. 扬州大学学报, 2002, 23(4):43-46,65.
[16] 刘淑军, 秦道珠, 梁海军, 等. 不同水稻基因型品种养分吸收特性. 中国农学通报, 2015, 31(3):16-22.
doi: 10.11924/j.issn.1000-6850.2014-1952
[17] 孙磊. 控释氮肥在水稻上的应用效果研究. 作物杂志, 2009 (2):76-78.
[18] 魏海燕, 李宏亮, 程金秋, 等. 缓释肥类型与运筹对不同穗型水稻产量的影响. 作物学报, 2017, 43(5):730-740.
[19] 蒋伟勤, 胡群, 俞航, 等. 优质食味粳稻控混肥一次性基施效应. 中国农业科学, 2021, 54(7):1382-1396.
doi: 10.3864/j.issn.0578-1752.2021.07.006
[20] 王泽胤. 不同配比控释尿素对水稻的影响. 黑龙江农业科学, 2008(5):63-64.
[21] 姬景红, 李玉影, 刘双全, 等. 控释尿素对黑龙江地区水稻产量及氮肥利用率的影响. 土壤通报, 2018, 49(4):876-881.
[1] Ren Yongfu, Li Jiayi, Chen Guopeng, Pu Tian, Chen Hong, Wang Xiaochun. Effects of Different Planting Patterns on the Yield and Efficiency of Maize in Strip Intercropping System [J]. Crops, 2025, 41(2): 101-108.
[2] Tian Wenqiang, Wang Hongyi, Nie Lingfan, Sun Ganggang, Zhang Jun, Zhang Qiangbin, Yu Shan, Li Jiahao, Zhang Jinshan, Shi Shubing. The Effects of Sowing Date and Sowing Rate on the Growth, Dry Matter Accumulation and Yield of Extremely Late-Sown Wheat Population [J]. Crops, 2025, 41(2): 115-122.
[3] Zhang Shengchang, Wei Yuming, Ma Lina, Yang Zhao, Liu Wenyu, Huang Jie, Liu Huan, Yang Farong. Effects of Planting Density and Fertilization on Growth Characteristics of Forage Quinoa [J]. Crops, 2025, 41(2): 128-134.
[4] Zhao Lingling, Li Guifang, Cheng Chu, Zheng Mingjie, Hu Min, Zhu Jianfeng, Shen Ayi, Shen Aga, Wang Junzhen, Shao Meihong. Preliminary Report on Introduction Experiment of New Buckwheat Varieties in Zhejiang Province [J]. Crops, 2025, 41(2): 86-92.
[5] Zhao Fuyang, Ma Bo, Hu Jifang, Tan Kefei, Liu Chuanzeng, Yan Feng, Dong Yang, Hou Xiaomin, Li Qingquan, Han Yehui. Evaluation of Photoperiod Sensitivity of Japonica Rice in Cold Regions under Different Photoperiod Conditions [J]. Crops, 2025, 41(2): 135-140.
[6] Ma Yingchen, Wang Jiatong, Feng Yanfei, Ma Haoxiong, Ren Xuejun, Guo Zhenqing, Li Yun, Han Yucui, Lin Xiaohu. Impacts of the Residual Effects of the Combined Application of Compound Fertilizers and Microbial Inoculant on Soil Physicochemical Properties and Quality of Foxtail Millet [J]. Crops, 2025, 41(2): 141-148.
[7] Zhang Jili, He Jinghao, Wei Jianyu, Huang Chongjun, Wang Wei, Cai Yixia. Effects of Application Period of Microbial Inoculants on Rhizosphere Soil Bacterial Diversity, Enzyme Activity and Yield and Quality of Flue-Cured Tobacco [J]. Crops, 2025, 41(2): 162-171.
[8] Jin Dandan, Sui Shijiang, Chen Yue, Li Bo, Qu Hang, Gong Liang. Effects of Straw Returning with Nitrogen Application Reduction on Yield and Nitrogen Utilization of Rice in Liaohe Plain [J]. Crops, 2025, 41(2): 172-179.
[9] Lu Jing, Yu Bo, Jiang Mi, Peng Lianxin, Ren Yuanhang, Wu Qi. Assessment of Genetic Diversity in 58 Germplasm Resources of Highland Barley [J]. Crops, 2025, 41(2): 20-28.
[10] Wu Lu, Zhang Hao, Yang Feiyun, Guo Erjing, Si Linlin, Cao Kai, Cheng Chen. Adaptability Assessment of WOFOST Model for Simulating Rice Growth and Development in the Jianghuai Region [J]. Crops, 2025, 41(2): 215-221.
[11] Li Yunxia, Yang Jiashuo, Li Yangyang, Xiang Shipeng, Yu Jinlong, Li Bin, Zheng Weiwei, Liu Lu. Effects of Different Transplanting Periods on the Growth, Development and Yield Quality of Flue-Cured Tobacco in Tobacco-Rice Rotation Area [J]. Crops, 2025, 41(2): 222-227.
[12] Li Junzhi, Dou Shuang, Wang Xiaodong, Zhang Meng, Xiao Jibing. Effects of Different Intercropping Patterns on Sorghum Growth and Development [J]. Crops, 2025, 41(2): 234-240.
[13] Jiang Suzhen, Xu Chao, Wang Zhongyuan, Zheng Shen, Chen Jianguo, Zhu Hanhua, Huang Daoyou, Zhang Quan, Zhu Qihong. Effects of Sepiolite and Biochar on the Uptake and Accumulation of Cadmium and Arsenic in Rice [J]. Crops, 2025, 41(2): 241-248.
[14] Luo Jianke, Zhang Kehou, Wang Zeyu, Zhang Pingzhen, Nan Ming. Research on the Production Performance of 18 Oat Varieties (Lines) in the Irrigation Area along the Yellow River in Baiyin City [J]. Crops, 2025, 41(2): 93-100.
[15] Zhang Jiazhi, Zhao Yuhan, Ding Junjie, Yao Liangliang, Qiu Lei, Zhang Maoming, Wang Zijie, Gao Xuedong, Huang Chengliang, Cui Shize, Yang Xiaohe. Effects of “Double-Exemption Dense Seedling” Technique on Seedling Quality and Enzyme Activity of Rice in Cold Region [J]. Crops, 2025, 41(2): 109-114.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!