侧深施氮对水稻产量及氮素吸收利用的影响

doi:10.3724/SP.J.1006.2021.02086

作物学报 ›› 2021, Vol. 47 ›› Issue (11): 2232-2249.doi: 10.3724/SP.J.1006.2021.02086

侧深施氮对水稻产量及氮素吸收利用的影响

黄恒¹(), 姜恒鑫¹, 刘光明¹, 袁嘉琦¹, 汪源¹, 赵灿¹, 王维领¹, 霍中洋¹^,^*(), 许轲¹, 戴其根¹, 张洪程¹, 李德剑², 刘国林²

¹扬州大学 / 江苏省作物遗传生理国家重点实验室培育点 / 粮食作物现代产业技术协同创新中心, 江苏扬州 225009
²江苏省兴化市农业局, 江苏兴化 225700

收稿日期:2020-12-03 接受日期:2021-04-26 出版日期:2021-11-12 网络出版日期:2021-05-17
通讯作者: 霍中洋
作者简介:E-mail: 632423039@qq.com
基金资助:
国家重点研发计划项目(2016YFD0200805);国家重点研发计划项目(2018YFD0300802);江苏省重点研发计划项目(BE2020319);江苏省重点研发计划项目(BE2019377);江苏省重点研发计划项目(BE2018362)

Effects of side deep placement of nitrogen on rice yield and nitrogen use efficiency

HUANG Heng¹(), JIANG Heng-Xin¹, LIU Guang-Ming¹, YUAN Jia-Qi¹, WANG Yuan¹, ZHAO Can¹, WANG Wei-Ling¹, HUO Zhong-Yang¹^,^*(), XU Ke¹, DAI Qi-Gen¹, ZHANG Hong-Cheng¹, LI De-Jian², LIU Guo-Lin²

¹Jiangsu Key Laboratory of Crop Genetics and Physiology / Co-Innovation Center for Modern Production Technology of Grain Crops / Yangzhou University, Yangzhou 225009, Jiangsu, China
²Bureau of Agriculture of Xinghua County of Jiangsu Province, Xinghua 225700, Jiangsu, China

Received:2020-12-03 Accepted:2021-04-26 Published:2021-11-12 Published online:2021-05-17
Contact: HUO Zhong-Yang
Supported by:
National Key Research and Development Program of China(2016YFD0200805);National Key Research and Development Program of China(2018YFD0300802);Key Research Program of Jiangsu Province(BE2020319);Key Research Program of Jiangsu Province(BE2019377);Key Research Program of Jiangsu Province(BE2018362)

摘要/Abstract

摘要：

水稻机插侧深施肥是一种高效、优质、安全的栽培技术。深入研究侧深施肥条件下不同施肥方式对水稻产量及氮素利用效率的影响, 有利于完善水稻侧深施肥技术体系。本研究以江苏优质食味水稻代表性品种南粳9108和南粳5718为材料, 设置4种不同的侧深施施肥方式, 分别为: 100%基肥侧深施FM1 (fertilization method 1)、70%基肥侧深施+30%分蘖肥FM2 (fertilization method 2)、70%基肥侧深施+30%穗肥FM3 (fertilization method 3)、35%基肥侧深施+35%分蘖肥+30%穗肥FM4 (fertilization method 4), 并设置常规施肥对照CFM (conventional fertilization method)和不施氮处理0N (no nitrogen)。研究了不同施肥方式 (处理)对水稻产量及构成因素、茎蘖动态、叶面积指数、光合势、干物质积累、群体生长率、氮素利用效率等方面的影响。结果表明, 与其他处理相比, FM3和FM4在稳定穗数的基础上, 显著提高了群体颖花量和千粒重, 经济产量最高。FM3生育中、后期的叶面积指数和干物质积累量尤其是抽穗至成熟期的干物质积累显著高于其他处理, 拔节后的氮素积累量和全生育期总吸氮量、氮素农学利用率、氮素生理利用率、氮素吸收利用率、和氮素偏生产力也均显著高于其他处理。同时, FM3比CFM及FM4减少施肥次数1~2次, 节省了用工及成本, 利于规模化生产, 是一种兼具高产、轻简与高效的水稻施肥方式。

关键词: 侧深施肥, 粳稻, 施肥方式, 产量, 氮肥利用效率

Abstract:

Lateral deep fertilization is an efficient, high-quality, and safe cultivation technology of rice mechanical transplanting. In order to improve the technical system of lateral deep fertilization, we investigated the effects of different fertilization methods on rice yield and nitrogen use efficiency under the condition of lateral deep fertilization. In this study, Nanjing 9108 and Nanjing 5718, the representative varieties of quality and delicious rice of Jiangsu, were used as materials. Four different lateral deep fertilization methods were arranged, including 100% base fertilizer side deep application FM1 (fertilization method 1), 70% base fertilizer side deep application + 30% tillering fertilizer FM2 (fertilization method 2), 70% base fertilizer side deep application + 30% panicle fertilizer FM3 (fertilization method 3), and 35% base fertilizer side deep application + 35% tillering fertilizer + 30% panicle fertilizer FM4 (fertilization method 4). In addition, the conventional fertilization method and no nitrogen treatment were added. The effects of different treatments on rice yield, leaf area index, photosynthetic potential, dry matter accumulation, population growth rate, and nitrogen use efficiency were compared. The results revealed that the yield of FM3 and FM4 were higher than those of other treatments. The main reason was that the spikelet number of the population was significantly higher than that of other treatments on the basis of stable panicle number. The leaf area index and dry matter accumulation of FM3 treatment were higher in the middle and late growth stages, especially from heading to maturity stage. Nitrogen accumulation of FM3 was less before jointing stage, but nitrogen accumulation after jointing stage and the total nitrogen uptake during the whole growth period were significantly higher than those of other treatments. Moreover, the nitrogen agronomic utilization rate, nitrogen physiological utilization rate, nitrogen absorption utilization rate, and nitrogen partial productivity of FM3 were significantly higher than those of the other treatments. At the same time, compared with CFM and FM4, FM3 can reduce fertilization times by 1-2 times, save labor and cost, and is conducive to large-scale production. It is a high-yield, simple and efficient fertilization method for rice.

Key words: side deep placement of nitrogen, japonica rice, fertilization methods, yield, nitrogen use efficiency

黄恒, 姜恒鑫, 刘光明, 袁嘉琦, 汪源, 赵灿, 王维领, 霍中洋, 许轲, 戴其根, 张洪程, 李德剑, 刘国林. 侧深施氮对水稻产量及氮素吸收利用的影响[J]. 作物学报, 2021, 47(11): 2232-2249.

HUANG Heng, JIANG Heng-Xin, LIU Guang-Ming, YUAN Jia-Qi, WANG Yuan, ZHAO Can, WANG Wei-Ling, HUO Zhong-Yang, XU Ke, DAI Qi-Gen, ZHANG Hong-Cheng, LI De-Jian, LIU Guo-Lin. Effects of side deep placement of nitrogen on rice yield and nitrogen use efficiency[J]. Acta Agronomica Sinica, 2021, 47(11): 2232-2249.

图/表 10

表1

表2

表3

侧深施肥不同施肥方式对水稻茎蘖动态的影响"

年份 Year	品种 Variety	处理 Treatment	分蘖盛期 Peak seeding stage (×10⁴ hm^-2)	拔节期 Jointing stage (×10⁴ hm^-2)	抽穗期 Heading stage (×10⁴ hm^-2)	成熟期 Maturity stage (×10⁴ hm^-2)	茎蘖成穗率 Percentage of productive tiller (%)
2019	南粳9108 Nanjing 9108	0N	342.20 e	327.37 e	257.53 c	257.43 d	74.54 a
		CFM	515.20 d	503.79 d	355.11 b	353.44 c	68.29 b
		FM1	611.79 a	585.48 a	355.46 b	355.47 c	57.50 c
		FM2	622.08 a	594.71 a	381.68 a	379.14 b	60.13 c
		FM3	589.87 b	580.07 ab	408.13 a	408.34 a	68.12 b
		FM4	569.61 c	555.34 c	396.63 a	394.82 a	65.41 b
	南粳5718 Nanjing 5718	0N	366.13 d	346.88 e	268.24 d	268.41 c	72.64 a
		CFM	534.42 c	512.33 d	368.71 c	366.47 b	67.89 b
		FM1	631.77 a	622.97 a	380.50 b	377.59 b	59.31 c
		FM2	629.59 a	620.22 a	381.83 b	379.71 b	59.67 c
		FM3	604.49 b	597.85 ab	415.67 a	415.21 a	68.05 b
		FM4	589.76 b	567.67 c	410.78 a	408.88 a	68.82 b
2020	南粳9108 Nanjing 9108	0N	340.22 e	323.89 e	257.35 d	257.21 d	71.92 a
		CFM	511.02 d	500.43 d	353.11 c	350.78 c	67.30 b
		FM1	610.85 a	582.14 a	353.26 c	351.25 c	60.75 c
		FM2	618.56 a	590.85 a	377.48 b	376.22 b	60.50 c
		FM3	586.39 b	576.39 ab	402.11 a	400.12 a	67.86 b
		FM4	567.11 c	551.56 c	393.15 a	392.22 a	71.08 a
	南粳5718 Nanjing 5718	0N	361.25 d	343.58 e	264.58 c	264.23 c	76.49 a
		CFM	530.68 c	510.15 d	362.15 b	361.75 b	67.09 b
		FM1	628.55 a	620.05 a	377.22 b	376.19 b	60.44 c
年份 Year	品种 Variety	处理 Treatment	分蘖盛期 Peak seeding stage (×10⁴ hm^-2)	拔节期 Jointing stage (×10⁴ hm^-2)	抽穗期 Heading stage (×10⁴ hm^-2)	成熟期 Maturity stage (×10⁴ hm^-2)	茎蘖成穗率 Percentage of productive tiller (%)
		FM2	627.15 a	615.64 a	379.29 b	378.05 b	61.57 c
		FM3	601.25 b	592.61 ab	411.39 a	410.05 a	68.06 b
		FM4	585.28 b	564.55 c	408.12 a	407.56 a	69.24 b
方差分析Variance analysis		Y	ns	ns	ns	ns	ns
		V	**	*	*	*	ns
		T	**	**	**	**	**
		Y×T	ns	ns	ns	ns	ns
		Y×V	ns	ns	ns	ns	ns
		V×T	**	**	**	**	**
		Y×V×T	ns	ns	ns	ns	ns

表3

表4

表5

表6

表7

表8

表9

表10

侧深施肥不同施肥方式对水稻氮效率的影响"

年份 Year	品种 Variety	处理Treatment	氮素农学利用率 N agronomic efficiency (kg kg^-1)	氮素生理利用率 N physiological efficiency (kg kg^-1)	氮素吸收利用率 N recovery efficiency (%)	氮素谷物生产效率 N grain production efficiency (kg kg^-1)	氮素干物质生产效率 N dry matter production efficiency (kg kg^-1)	百千克籽粒需氮量 N requirement for 100-kg grain (kg)	氮素偏生产力 N partial factor productivity (kg kg^-1)
2019	南粳9108 Nanjing 9108	0N	—	—	—	61.31 a	107.51 a	1.63 b	—
		CFM	9.93 b	31.43 b	30.33 c	48.27 b	99.36 b	2.07 a	33.57 d
		FM1	7.47 c	25.69 c	29.07 c	46.14 c	93.07 c	2.17 a	31.50 e
		FM2	10.83 b	33.71 b	32.13 b	48.88 b	88.79 c	2.05 a	34.87 c
		FM3	13.77 a	38.35 a	35.90 a	50.33 b	99.68 b	1.99 a	37.80 a
		FM4	12.33 a	35.78 a	34.47 a	49.37 b	102.49 ab	2.03 a	36.37 b
	南粳5718 Nanjing 5718	0N	—	—	—	69.92 a	104.08 a	1.43 b	—
		CFM	8.07 b	22.91 b	35.50 c	46.19 b	98.74 b	2.16 a	34.57 b
		FM1	7.23 c	20.74 c	35.13 c	44.30 c	95.26 c	2.21 a	33.73 c
		FM2	8.33 b	24.95 b	36.77 b	45.77 b	101.99 a	2.18 a	34.83 b
		FM3	10.97 a	27.64 a	42.17 a	45.97 b	99.63 ab	2.18 a	37.47 a
		FM4	10.50 a	27.34 a	40.70 a	46.23 b	98.78 b	2.16 a	37.00 a
2020	南粳9108 Nanjing 9108	0N	—	—	—	57.47 a	105.45 a	1.74 b	—
		CFM	11.10 b	33.22 b	30.40 c	46.89 b	99.12 b	2.13 a	33.67 b
		FM1	10.43 c	25.81 c	29.13 c	48.25 c	92.63 c	2.07 a	31.00 c
		FM2	11.67 b	34.31 b	32.13 b	45.95 b	88.23 c	2.09 a	34.23 b
		FM3	13.20 a	36.77 a	35.90 a	47.58 b	99.62 b	2.10 a	35.77 a
		FM4	12.73a	36.94 a	34.47 a	47.88 b	100.45 ab	2.09 a	35.30 a
	南粳5718 Nanjing 5718	0N	—	—	—	65.63 a	101.26 a	1.52 b	—
		CFM	9.73 b	23.78 b	35.50 c	44.86 b	97.56 b	2.23 a	33.63 b
		FM1	9.03 c	21.87 c	35.13 c	42.49 c	90.54 c	2.20 a	31.93 c
		FM2	10.37 b	25.48 b	37.77 b	46.26 b	100.25 a	2.16 a	34.27 b
		FM3	11.50 a	28.94 a	42.10 a	44.63 b	98.53 ab	2.24 a	36.40 a
		FM4	10.80 a	28.08 a	40.70 a	44.53 b	96.52 b	2.25 a	35.70 a
方差分析 Variance analysis		Y	ns	ns	ns	ns	ns	ns	ns
		V	**	**	**	**	ns	ns	**
		T	**	**	**	**	**	ns	**
		Y×V	ns	ns	ns	ns	ns	ns	ns
		Y×T	ns	ns	ns	ns	ns	ns	ns
		V×T	**	**	**	**	**	ns	**
		Y×V×T	ns	ns	ns	ns	ns	ns	ns

表10

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年份 Year	品种 Variety	处理 Treatment	产量 Grain yield (t hm^-2)	穗数 Panicles per (×10⁴ hm^-2)	每穗粒数Spikelets per panicle	结实率 Filled grains rate (%)	千粒重 1000-grain weight (g)
2019	南粳9108 Nanjing 9108	0N	7.21 d	255.07 d	115.44 e	96.94 a	28.91 a
		CFM	10.07 bc	351.85 c	126.95 d	94.58 b	26.50 bc
		FM1	9.45 c	351.80 c	114.95 e	89.72 f	26.28 cd
		FM2	10.46 b	374.07 b	130.98 c	90.93 e	25.87 d
		FM3	11.34 a	401.82 a	138.61 a	91.85 d	26.63 b
		FM4	10.91 a	372.60 b	134.01 b	92.54 c	26.75 b
	南粳5718 Nanjing 5718	0N	8.25 d	265.95 d	112.56 e	97.68 a	30.43 a
		CFM	10.37 bc	362.82 c	121.66 d	95.74 b	28.14 bc
		FM1	10.12 c	374.73 b	109.42 f	91.03 e	27.50 c
		FM2	10.45 b	375.67 b	126.71 c	91.41 e	27.71 c
		FM3	11.24 a	411.37 a	133.96 a	92.37 d	28.35 b
		FM4	11.10 a	405.87 a	128.53 b	93.42 c	28.53 b
2020	南粳9108 Nanjing 9108	0N	6.77 c	244.68 d	114.29 d	95.91 a	28.55 a
		CFM	9.80 b	343.93 c	127.38 c	94.30 ab	26.48 bc
		FM1	9.90 b	371.12 b	118.34 d	89.24 c	26.39 c
		FM2	10.27 ab	374.21 b	129.11 bc	92.12 b	26.11 d
		FM3	10.73 a	397.91 a	132.83 ab	92.90 b	26.68 b
		FM4	10.59 a	403.12 a	133.42 a	93.15 b	26.72 b
	南粳5718 Nanjing 5718	0N	7.77 c	276.31 d	111.24 d	96.08 a	30.80 a
		CFM	10.09 b	356.03 c	121.14 c	94.73 b	28.18 b
		FM1	10.18 b	379.91 b	113.24 d	91.45 d	27.87 c
		FM2	10.58 ab	386.11 b	122.45 bc	93.17 c	27.89 c
		FM3	10.92 a	409.22 a	126.38 a	93.83 c	28.00 bc
		FM4	10.71 a	405.25 a	124.25 ab	93.64 c	28.11 b
方差分析Variance analysis		Y	**	**	**	**	**
		V	**	**	**	**	**
		T	**	**	**	**	**
		Y×T	ns	ns	**	**	ns
		Y×V	**	ns	ns	ns	ns
		V×T	**	**	**	ns	ns
		Y×V×T	**	ns	ns	ns	ns

年份 Year	品种 Variety	处理 Treatment	播种期至拔节期 S-J (×10⁴ m² d hm^-2)	拔节期至抽穗期 J-H (×10⁴ m² d hm^-2)	抽穗期至成熟期 H-M (×10⁴ m² d hm^-2)
2019	南粳9108 Nanjing 9108	0N	55.83 c	88.23 d	172.98 d
		CFM	138.55 b	174.01 c	342.01 c
		FM1	160.13 a	190.15 a	357.59 a
		FM2	156.78 a	188.72 a	356.02 a
		FM3	142.99 b	179.95 b	359.85 b
		FM4	142.73 b	179.73 b	355.96 b
	南粳5718 Nanjing 5718	0N	84.55 c	108.45 d	203.11 d
		CFM	150.24 b	189.86 c	370.95 c
		FM1	176.95 a	205.62 a	380.09 a
年份 Year	品种 Variety	处理 Treatment	播种期至拔节期 S-J (×10⁴ m² d hm^-2)	拔节期至抽穗期 J-H (×10⁴ m² d hm^-2)	抽穗期至成熟期 H-M (×10⁴ m² d hm^-2)
		FM2	177.63 a	206.88 a	381.55 a
		FM3	156.87 b	197.01 b	385.70 b
		FM4	155.68 b	196.33 b	383.45 b
2020	南粳9108 Nanjing 9108	0N	56.73 c	88.87 d	173.62 d
		CFM	139.49 b	174.47 c	342.49 c
		FM1	162.13 a	190.99 a	357.97 a
		FM2	157.28 a	189.24 a	356.44 a
		FM3	143.77 b	180.63 b	360.13 b
		FM4	143.23 b	180.19 b	356.26 b
	南粳5718 Nanjing 5718	0N	84.95 c	108.91 d	207.15 d
		CFM	151.26 b	190.18 c	373.85 c
		FM1	177.25 a	206.00 a	380.13 a
		FM2	178.13 a	207.26 a	385.59 a
		FM3	157.19 b	197.55 b	385.90 b
		FM4	156.30 b	196.59 b	384.13 b
方差分析Variance analysis		Y	ns	ns	ns
		V	**	**	**
		T	**	**	**
		Y×V	ns	ns	ns
		Y×T	ns	ns	ns
		V×T	**	**	**
		Y×V×T	ns	ns	ns

年份 Year	品种 Variety	处理 Treatment	拔节期 Jointing stage (t hm^-2)	抽穗期 Heading stage (t hm^-2)	成熟期 Maturity stage (t hm^-2)	收获指数 Harvest index (%)
2019	南粳9108 Nanjing 9108	0N	2.73 d	7.02 c	13.20 c	54.62 a
		CFM	3.37 c	10.57 b	19.77 b	50.94 b
		FM1	4.72 a	10.62 ab	18.67 b	50.62 b
		FM2	4.70 a	11.63 a	20.13 ab	51.96 b
		FM3	3.75 b	11.70 a	21.77 a	52.09 b
		FM4	3.73 b	11.63 a	21.66 a	50.37 b
	南粳5718 Nanjing 5718	0N	3.07 d	8.40 b	14.69 d	56.16 a
		CFM	3.83 c	11.37 b	21.87 b	47.42 b
		FM1	4.98 a	11.75 ab	20.60 c	49.13 b
		FM2	4.93 a	12.19 a	21.61 b	48.36 b
		FM3	4.41 b	12.56 a	23.10 a	48.66 b
		FM4	4.41 b	12.52 a	23.04 a	48.18 b
2020	南粳9108 Nanjing 9108	0N	2.43 d	6.51 c	11.95 c	56.65 a
		CFM	3.56 c	10.25 b	19.47 b	50.34 b
		FM1	4.86 a	11.01 ab	19.26 b	51.40 b
		FM2	4.89 a	11.34 a	20.23 ab	50.77 b
		FM3	4.03 b	11.28 a	20.78 a	51.64 b
		FM4	4.05 b	11.31 a	20.84 a	50.82 b
	南粳5718 Nanjing 5718	0N	2.62 d	7.59 b	13.27 d	58.54 a
		CFM	3.73 c	10.77 b	21.42 b	47.10 b
		FM1	5.31 a	12.25 ab	20.70 c	49.18 b
		FM2	5.33 a	12.82 a	22.11 ab	47.85 b
		FM3	4.42 b	12.45 a	22.86 a	47.77 b
		FM4	4.43 b	12.48 a	22.97 a	46.63 b
方差分析Variance analysis		Y	ns	ns	ns	ns
		V	ns	**	**	ns
		T	**	**	**	**
		Y×V	ns	ns	ns	ns
		Y×T	ns	ns	ns	ns
		V×T	**	**	**	*
		Y×V×T	ns	ns	ns	ns

年份 Year	品种 Variety	处理 Treatment	播种期至拔节期 S-J (g m^-2 d^-1)	拔节期至抽穗期 J-H (g m ^-2d^-1)	抽穗期至成熟期 H-M (g m^-2 d^-1)
2019	南粳9108 Nanjing 9108	0N	4.71 d	20.92 d	6.12 c
		CFM	6.79 c	24.62 b	10.72 a
		FM1	8.73 a	22.00 c	8.18 b
		FM2	8.70 a	22.08 c	7.82 b
		FM3	7.47 b	26.07 a	11.00 a
		FM4	7.46 b	26.00 a	10.95 a
	南粳5718 Nanjing 5718	0N	5.04 d	21.05 d	6.23 c
		CFM	7.16 c	25.09 b	11.41 a
		FM1	8.92 a	23.21 c	8.75 b
		FM2	8.90 a	23.28 c	9.03 b
		FM3	7.62 b	27.22 a	11.43 a
		FM4	7.63 b	27.10 a	11.42 a
2020	南粳9108 Nanjing 9108	0N	4.85 d	21.00 d	6.18 c
		CFM	6.87 c	24.70 b	10.78 a
		FM1	8.77 a	22.02 c	8.24 b
		FM2	8.74 a	22.14 c	7.88 b
		FM3	7.51 b	26.15 a	11.02 a
		FM4	7.44 b	26.02 a	10.99 a
	南粳5718 Nanjing 5718	0N	5.08 d	21.17 d	6.27 c
		CFM	7.20 c	25.15 b	11.45 a
		FM1	8.98 a	23.27 c	8.85 b
		FM2	8.92 a	23.34 c	9.09 b
		FM3	7.64 b	27.28 a	11.47 a
		FM4	7.67 b	27.14 a	11.48 a
方差分析Variance analysis		Y	ns	ns	ns
		V	**	**	**
		T	**	**	*
		Y×V	ns	ns	ns
		Y×T	ns	ns	ns
		V×T	**	*	*
		Y×V×T	ns	ns	ns

年份 Year	品种 Variety	处理 Treatment	拔节期 Jointing stage (×10^-2 t hm^-2)	抽穗期 Heading stage (×10^-2 t hm^-2)	成熟期 Maturity stage (×10^-2 t hm^-2)
2019	南粳9108 Nanjing 9108	0N	3.97 e	9.80 d	11.76 d
		CFM	6.48 d	16.91 c	20.86 bc
		FM1	10.54 ab	16.93 c	20.48 c
		FM2	10.76 a	17.66 ab	21.40 b
		FM3	7.67 c	18.17 a	22.53 a
		FM4	7.55 c	17.90 ab	22.10 a
	南粳5718 Nanjing 5718	0N	3.85 d	9.80 d	11.80 d
		CFM	6.07 c	18.16 c	22.45 bc
		FM1	10.46 a	18.58 c	22.34 c
		FM2	10.55 a	18.93 ab	22.83 b
		FM3	7.38 b	19.67 a	24.45 a
		FM4	7.30 b	19.45 ab	24.01 a
2020	南粳9108 Nanjing 9108	0N	3.99 e	9.84 d	11.78 d
		CFM	6.52 d	16.93 c	20.90 bc
		FM1	10.58 ab	16.97 c	20.52 c
		FM2	10.80 a	17.70 ab	21.42 b
		FM3	7.69 c	18.21 a	22.55 a
		FM4	7.59 c	17.94 ab	22.12 a
	南粳5718 Nanjing 5718	0N	3.87 d	9.86 d	11.84 d
		CFM	6.11 c	18.20 c	22.49 bc
		FM1	10.50 a	18.64 c	22.38 c
年份 Year	品种 Variety	处理 Treatment	拔节期 Jointing stage (×10^-2 t hm^-2)	抽穗期 Heading stage (×10^-2 t hm^-2)	成熟期 Maturity stage (×10^-2 t hm^-2)
		FM2	10.61 a	18.97 ab	22.87 b
		FM3	7.42 b	19.71 a	24.47 a
		FM4	7.34 b	19.47 ab	24.05 a
方差分析Variance analysis		Y	ns	ns	ns
		V	**	**	**
		T	**	**	**
		Y×V	ns	ns	ns
		Y×T	ns	ns	ns
		V×T	**	**	**
		Y×V×T	ns	ns	ns

侧深施氮对水稻产量及氮素吸收利用的影响

Effects of side deep placement of nitrogen on rice yield and nitrogen use efficiency

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处理 Treatment	基肥N Basic fertilizer N (kg hm^-2)	分蘖肥N Tiller fertilizer N (kg hm^-2)	穗肥N Earing fertilizer N (kg hm^-2)	总N Total N (kg hm^-2)	施肥次数Fertilization times
不施氮肥0N	0	0	0	0	0
常规施肥对照CFM	105	105	90	300	4
100%基肥一次性侧深施FM1	300	0	0	300	1
70%基肥侧深施+30%分蘖肥FM2	210	90	0	300	2
70%基肥侧深施+30%穗肥FM3	210	0	90	300	2
35%基肥侧深施+35%分蘖肥+30%穗肥FM4	105	105	90	300	4

年份 Year	品种 Variety	处理 Treatment	拔节期 Jointing stage	抽穗期 Heading stage	成熟期 Maturity stage
2019	南粳9108 Nanjing 9108	0N	1.68 c	3.69 c	1.49 c
		CFM	4.15 b	6.41 b	3.81 ab
		FM1	4.81 a	6.74 a	3.94 a
		FM2	4.69 a	6.77 a	3.96 a
		FM3	4.28 b	6.65 a	4.05 a
		FM4	4.26 b	6.65 a	3.98 a
	南粳5718 Nanjing 5718	0N	2.53 c	4.06 c	2.07 c
		CFM	4.50 b	7.02 b	4.10 ab
		FM1	5.31 a	7.19 a	4.16 a
		FM2	5.29 a	7.27 a	4.21 a
		FM3	4.69 b	7.24 a	4.25 a
		FM4	4.66 b	7.25 a	4.21 a
2020	南粳9108 Nanjing 9108	0N	1.81 c	3.81 c	1.58 c
2020	南粳9108 Nanjing 9108	CFM	4.41 b	6.62 b	4.01 b
年份 Year	品种 Variety	处理 Treatment	拔节期 Jointing stage	抽穗期 Heading stage	成熟期 Maturity stage
		FM1	4.98 a	6.62 b	4.09 b
		FM2	4.96 a	6.79 b	4.11 b
		FM3	4.52 b	6.97 a	4.35 a
		FM4	4.50 b	6.96 a	4.33 a
	南粳5718 Nanjing 5718	0N	2.88 c	4.14 c	2.21 c
		CFM	4.87 b	7.12 b	4.26 b
		FM1	5.28 a	7.12 b	4.27 b
		FM2	5.26 a	7.25 b	4.28 b
		FM3	4.98 b	7.47 a	4.46 a
		FM4	5.00 b	7.46 a	4.45 a
方差分析Variance analysis		Y	ns	ns	ns
		V	**	**	**
		T	**	**	**
		Y×V	ns	ns	ns
		Y×T	ns	ns	ns
		V×T	**	**	**
		Y×V×T	ns	ns	ns

年份 Year	品种 Variety	处理 Treatment	播种期至拔节期 S-J	拔节期至抽穗期 J-H	抽穗期至成熟期 H-M
2019	南粳9108 Nanjing 9108	0N	0.43 d	1.29 c	0.21 d
		CFM	0.71 c	2.31 a	0.43 b
		FM1	1.17 a	1.47 b	0.38 c
		FM2	1.19 a	1.52 b	0.40 c
		FM3	0.84 b	2.33 a	0.47 a
		FM4	0.83 b	2.29 a	0.46 a
	南粳5718 Nanjing 5718	0N	0.42 d	1.32 c	0.21 d
		CFM	0.67 c	2.68 a	0.47 b
		FM1	1.16 a	1.57 b	0.41 c
		FM2	1.16 a	1.63 b	0.42 c
		FM3	0.80 b	2.68 a	0.51 a
		FM4	0.81 b	2.72 a	0.52 a
2020	南粳9108 Nanjing 9108	0N	0.45 d	1.31 c	0.23 d
		CFM	0.73 c	2.33 a	0.45 b
		FM1	1.17 a	1.51 b	0.42 c
		FM2	1.21 a	1.54 b	0.42 c
年份 Year	品种 Variety	处理 Treatment	播种期至拔节期 S-J	拔节期至抽穗期 J-H	抽穗期至成熟期 H-M
	南粳5718 Nanjing 5718	0N	0.44 d	1.34 c	0.23 d
		FM3	0.86 b	2.35 a	0.49 a
		FM4	0.85 b	2.31 a	0.48 a
		CFM	0.69 c	2.70 a	0.49 b
		FM1	1.18 a	1.59 b	0.43 c
		FM2	1.20 a	1.65 b	0.44 c
		FM3	0.82 b	2.72 a	0.53 a
		FM4	0.83 b	2.74 a	0.54 a
方差分析Variance analysis		Y	ns	ns	ns
		V	**	**	**
		T	**	**	**
		Y×V	ns	ns	ns
		Y×T	ns	ns	ns
		V×T	**	**	**
		Y×V×T	ns	ns	ns

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