Effects of combined application of conventional urea and slow-release urea on rice yield and phosphorus fertilizer use efficiency

doi:10.16178/j.issn.0528-9017.20240441

Abstract

Abstract:

To investigate the effects of combined application of conventional urea and slow-release urea on rice yield and phosphorus fertilizer use efficiency, a field experiment was conducted with six treatments: CK (no fertilizer), NK, N2K, NPK, N2PK, and N3PK. The results showed that under straw return conditions, the rice grain yield of the no fertilizer treatment (CK) was the lowest, at 5 577 kg·hm^-2, accounting for 60.10% of the yield in the NPK treatment, indicating a fertilizer-induced yield increase contribution rate of 39.90%. The average grain yield of the no-phosphorus treatments (NK and N2K) was 86.46% of that of the phosphorus-applied treatments (NPK, N2PK, and N3PK), demonstrating a phosphorus fertilizer contribution rate of 13.54%. Compared with CK, the phosphorus-applied treatments (NPK, N2PK, and N3PK) significantly (p<0.05) increased rice grain yield, with the combined slow-release urea treatments (N2PK and N3PK) showing particularly notable effects. Compared with the no-phosphorus treatments (NK and N2K), the combined slow-release urea treatments (N2PK and N3PK) significantly enhanced grain yield, straw yield, straw phosphorus content, grain phosphorus uptake, and straw phosphorus uptake. Compared with the NPK treatment, the combined slow-release urea treatments (N2PK and N3PK) increased the apparent phosphorus recovery efficiency by 11.2 percentage points. In conclusion, under the experimental conditions, the combined application of slow-release urea (N2PK and N3PK) is recommended to effectively improve rice yield and phosphorus fertilizer use efficiency.

Key words: rice, slow-release urea, phosphorus fertilizer, fertilizer use efficiency, yield

CLC Number:

S146

CHEN Weilong, SHEN Wenying, XIAO Jiali, TU Changpeng, CAO Xuexian. Effects of combined application of conventional urea and slow-release urea on rice yield and phosphorus fertilizer use efficiency[J]. Journal of Zhejiang Agricultural Sciences, 2025, 66(11): 2566-2570.

Figures/Tables 4

References 15

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处理	基肥				分蘖肥	穗肥	折纯
处理	缓释尿素	普通尿素	过磷酸钙	氯化钾	普通尿素	普通尿素	N	P₂O₅	K₂O
CK	0	0	0	0	0	0	0	0	0
NK	0	170	0	275	170	85	195.5	0	165
N2K	354.5	85	0	275	0	0	195.1	0	165
NPK	0	170	625	275	170	85	195.5	75	165
N2PK	354.5	85	625	275	0	0	195.1	75	165
N3PK	354.5	0	625	275	85	0	195.1	75	165

处理	基肥				分蘖肥	穗肥	折纯
处理	缓释尿素	普通尿素	过磷酸钙	氯化钾	普通尿素	普通尿素	N	P₂O₅	K₂O
CK	0	0	0	0	0	0	0	0	0
NK	0	170	0	275	170	85	195.5	0	165
N2K	354.5	85	0	275	0	0	195.1	0	165
NPK	0	170	625	275	170	85	195.5	75	165
N2PK	354.5	85	625	275	0	0	195.1	75	165
N3PK	354.5	0	625	275	85	0	195.1	75	165

处理	籽粒产量	秸秆产量
CK	5 577 c	5 982 c
NK	8 235 b	7 641 b
N2K	8 541 b	7 953 b
NPK	9 279 ab	8 278 b
N2PK	9 986 a	9 824 a
N3PK	9 841 a	9 803 a

处理	籽粒产量	秸秆产量
CK	5 577 c	5 982 c
NK	8 235 b	7 641 b
N2K	8 541 b	7 953 b
NPK	9 279 ab	8 278 b
N2PK	9 986 a	9 824 a
N3PK	9 841 a	9 803 a

处理	磷含量/(g·kg^-1)		吸磷量/(kg·hm^-2)
处理	籽粒	秸秆	籽粒	秸秆
CK	10.6 b	2.40 c	58.9 c	14.1 e
NK	12.6 a	2.66 b	101.9 b	20.5 d
N2K	12.2 a	2.74 b	104.1 b	22.6 c
NPK	12.7 a	3.10 a	117.7 a	25.7 b
N2PK	12.2 a	3.06 a	121.6 a	30.1 a
N3PK	12.3 a	3.09 a	121.4 a	30.3 a