Impact of Reduced and Simplified Side Deep Fertilization on Rice Biomass Production and Quality

doi:10.11924/j.issn.1000-6850.casb2025-0330

Abstract

Abstract:

To investigate the effects of side-deep fertilization on rice biomass production, yield formation, and grain quality, in this experiment, no nitrogen fertilizer (0N) was set as the blank control, and the split application of 300 kg/hm² conventional fertilizer was set as the conventional control (CK). Two main plots were established: side-deep application of slow-release blended fertilizer and side-deep application of conventional compound fertilizer. Within these main plots, three nitrogen application gradients (240, 270 and 300 kg/hm²) were set as subplots. Additionally, two modes with a 10% nitrogen reduction were included: a one-time side-deep application of slow-release blended fertilizer (ODS18), and a one-base-one-topdressing side-deep application of conventional fertilizer (DSC18), resulting in a total of eight treatments. The results showed that compared with the control, side-deep fertilization did not reduce the number of tillers even when nitrogen application was reduced by 10%-20%; instead, it promoted tillering, with tiller numbers increased by 4.5% to 56.5% and effective panicles increased by 7.5% to 22.1%. Under side-deep fertilization, plant height increased across all nitrogen application levels, and the leaf area index significantly improved, favoring early-stage rice growth. It also significantly enhanced the photosynthetic potential, agronomic nitrogen use efficiency, and partial factor productivity of nitrogen fertilizer, with side-deep application of slow-release blended fertilizer outperforming side-deep application of conventional compound fertilizer. The highest photosynthetic potential and nitrogen use efficiency were achieved with slow-release blended fertilizer at a nitrogen application rate of 270 kg/hm². Under reduced nitrogen application and fewer fertilization events, side-deep fertilization effectively increased the number of effective panicles without reducing the seed-setting rate or 1000-grain weight, which were the main reasons for the yield increase. The yield of side-deep application of slow-release blended fertilizer with a 20% nitrogen reduction was close to that of the control, while a 10% nitrogen reduction increased yield by 14.5%, demonstrating significant potential for yield enhancement and efficiency improvement. The effects of side-deep fertilization on rice quality were complex, which could increase protein content but had minimal impact on processing and appearance quality. The head rice rate under side-deep application of compound fertilizer was higher than that of the control, and one-time deep side application of slow-release blended fertilizer significantly improved the head rice rate and reduced amylose content. In summary, side deep fertilization is an efficient fertilization method, which can stabilize or even increase the yield under the condition of reducing the amount of nitrogen fertilizer by 10% -20% and reducing the number of fertilization times by 2-3 times. In particular, the treatment of side deep application of slow-release blended fertilizer with 20% nitrogen reduction can stabilize the processing quality and appearance quality without reducing the yield, and has the value of large-scale promotion.

Key words: side-deep fertilization, reduced and simplified, biomass production, yield, quality

TANG Jianpeng, CHEN Jingdu, LIU Shaogui, HONG Ye, ZHANG Yan, XIN Haibin, LU Peiling, ZHANG Mingwei. Impact of Reduced and Simplified Side Deep Fertilization on Rice Biomass Production and Quality[J]. Chinese Agricultural Science Bulletin, 2026, 42(2): 16-24.

Figures/Tables 8

References 25

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	处理（总氮量）	基肥	分蘖肥	穗肥
0N	空白对照0	0	0	0
CK	常规施肥4次，300	90	108	102
CK	常规施肥4次，300	复合肥600	尿素2次，150+82.5	复合肥225+尿素150
DS16	缓混肥侧深施2次，240	180	0	60
DS16	缓混肥侧深施2次，240	缓混肥600		复合肥150+尿素90
DS18	缓混肥侧深施2次，270	180	0	90
DS18	缓混肥侧深施2次，270	缓混肥600		复合肥150+尿素150
DS20	缓混肥侧深施3次，300	180	30	90
DS20	缓混肥侧深施3次，300	缓混肥600	尿素64.5	复合肥150+尿素150
DSC18	复合肥侧深施2次，270	180	0	90
DSC18	复合肥侧深施2次，270	复合肥525+尿素225		复合肥225+尿素120
ODS18	缓混肥一次性侧深施，270	缓混肥900	0	0
DC16	复合肥侧深施3次，240	90	90	60
DC16	复合肥侧深施3次，240	复合肥600	尿素195	复合肥150+尿素90
DC18	复合肥侧深施3次，270	90	90	90
DC18	复合肥侧深施3次，270	复合肥600	尿素195	复合肥150+尿素150
DC20	复合肥侧深施4次，300	90	120	90
DC20	复合肥侧深施4次，300	复合肥600	尿素2次，150+111	复合肥150+尿素150

	处理（总氮量）	基肥	分蘖肥	穗肥
0N	空白对照0	0	0	0
CK	常规施肥4次，300	90	108	102
CK	常规施肥4次，300	复合肥600	尿素2次，150+82.5	复合肥225+尿素150
DS16	缓混肥侧深施2次，240	180	0	60
DS16	缓混肥侧深施2次，240	缓混肥600		复合肥150+尿素90
DS18	缓混肥侧深施2次，270	180	0	90
DS18	缓混肥侧深施2次，270	缓混肥600		复合肥150+尿素150
DS20	缓混肥侧深施3次，300	180	30	90
DS20	缓混肥侧深施3次，300	缓混肥600	尿素64.5	复合肥150+尿素150
DSC18	复合肥侧深施2次，270	180	0	90
DSC18	复合肥侧深施2次，270	复合肥525+尿素225		复合肥225+尿素120
ODS18	缓混肥一次性侧深施，270	缓混肥900	0	0
DC16	复合肥侧深施3次，240	90	90	60
DC16	复合肥侧深施3次，240	复合肥600	尿素195	复合肥150+尿素90
DC18	复合肥侧深施3次，270	90	90	90
DC18	复合肥侧深施3次，270	复合肥600	尿素195	复合肥150+尿素150
DC20	复合肥侧深施4次，300	90	120	90
DC20	复合肥侧深施4次，300	复合肥600	尿素2次，150+111	复合肥150+尿素150

处理	6月29日	7月6日	7月13日	7月20日	7月26日	8月3日	8月11日	8月17日	8月24日	有效穗数	成穗率/%
0N	227.6 b	402.4 c	516.2 d	469.0 d	446.8 d	421.8 d	341.3 c	316.4 d	291.4 d	263.6 c	51.08 ab
CK	212.3 b	512.0 bc	616.1bc	525.9 bc	537.0 cd	470.4 c	367.7 c	353.8 c	328.8 c	298.8 b	48.50 c
DS16	210.9 b	556.4 b	582.7 cd	568.8 ab	552.1 bc	470.3 c	450.9 b	419.0 b	388.5 b	321.2 ab	47.05 c
DS18	280.3 ab	648.0 a	671.6 b	686.2 ab	668.8 a	627.2 a	535.6 a	412.1 b	384.3 b	358.9 a	52.30 ab
DS20	292.8 a	560.6 b	641.0 b	729.0 a	677.4 a	595.2 ab	550.8 a	485.6 a	459.3 a	364.9 a	50.05 b
DSC18	274.7 ab	449.6 bc	564.7 cd	538.4 bc	488.4 de	459.3 c	416.3 bc	389.9 bc	377.4 b	328.8 ab	58.23 a
ODS18	265.0 ab	541.1 b	740.9 a	722.9 a	686.8 a	525.9 b	485.6 ab	464.8 a	423.2 ab	350.6 a	47.32 c
DC16	247.0 ab	585.5 b	577.1bc	575.8 bc	505.0 bc	471.8 c	463.4 b	477.3 a	364.9 bc	339.5 a	50.14 b
DC18	258.1 ab	530.0 b	639.4 b	549.5 bc	541.9 cd	457.9 c	414.9 bc	444.0 ab	380.2 b	347.8 a	58.02 a
DC20	226.2 ab	509.2 bc	663.2 b	734.0 a	636.9 ab	513.4 b	420.4 bc	474.5 a	413.5 ab	356.1 a	48.52 c

处理	6月29日	7月6日	7月13日	7月20日	7月26日	8月3日	8月11日	8月17日	8月24日	有效穗数	成穗率/%
0N	227.6 b	402.4 c	516.2 d	469.0 d	446.8 d	421.8 d	341.3 c	316.4 d	291.4 d	263.6 c	51.08 ab
CK	212.3 b	512.0 bc	616.1bc	525.9 bc	537.0 cd	470.4 c	367.7 c	353.8 c	328.8 c	298.8 b	48.50 c
DS16	210.9 b	556.4 b	582.7 cd	568.8 ab	552.1 bc	470.3 c	450.9 b	419.0 b	388.5 b	321.2 ab	47.05 c
DS18	280.3 ab	648.0 a	671.6 b	686.2 ab	668.8 a	627.2 a	535.6 a	412.1 b	384.3 b	358.9 a	52.30 ab
DS20	292.8 a	560.6 b	641.0 b	729.0 a	677.4 a	595.2 ab	550.8 a	485.6 a	459.3 a	364.9 a	50.05 b
DSC18	274.7 ab	449.6 bc	564.7 cd	538.4 bc	488.4 de	459.3 c	416.3 bc	389.9 bc	377.4 b	328.8 ab	58.23 a
ODS18	265.0 ab	541.1 b	740.9 a	722.9 a	686.8 a	525.9 b	485.6 ab	464.8 a	423.2 ab	350.6 a	47.32 c
DC16	247.0 ab	585.5 b	577.1bc	575.8 bc	505.0 bc	471.8 c	463.4 b	477.3 a	364.9 bc	339.5 a	50.14 b
DC18	258.1 ab	530.0 b	639.4 b	549.5 bc	541.9 cd	457.9 c	414.9 bc	444.0 ab	380.2 b	347.8 a	58.02 a
DC20	226.2 ab	509.2 bc	663.2 b	734.0 a	636.9 ab	513.4 b	420.4 bc	474.5 a	413.5 ab	356.1 a	48.52 c

处理	基部第一节间长	基部第二节间长	基部第三节间长	基部节间长之和	基部节间占株高比例	穗下节间长	穗下节占株高比例	株高
0N	2.74 b	6.58 ab	12.04 ab	21.36 b	25.84 ab	41.52 b	50.23 a	82.66 c
CK	3.59 ab	8.32 a	13.07 ab	24.97 ab	27.37 ab	45.54 ab	49.92 ab	91.23 b
DS16	4.38 a	8.88 a	13.90 ab	27.16 ab	28.92 a	45.70 ab	48.67ab	93.90 b
DS18	2.38 b	5.76 ab	10.58 ab	18.71 c	19.30 bc	45.63 ab	47.06 ab	96.95 ab
DS20	3.94 ab	4.60 b	9.22 c	17.76 c	17.58 c	44.32 ab	43.86 bc	101.04 a
DSC18	3.84 ab	7.40 ab	13.22 ab	24.46 ab	26.52 ab	43.86 ab	47.55 ab	92.24 b
ODS18	3.58 ab	3.36 b	9.00 c	15.94 c	16.26 c	41.95 b	42.81 bc	98.00 ab
DC16	3.82 ab	7.00 ab	15.08 a	25.90 ab	28.23 a	47.18 a	51.43 a	91.74 b
DC18	4.96 a	9.22 a	14.40 a	28.58 a	29.71 a	45.72 ab	47.53 ab	96.20 ab
DC20	2.98 b	5.54 ab	12.48 ab	21.00 b	20.74 bc	41.78 b	41.27 c	101.24 a