不同株型杂交籼稻对氮肥的耐受性差异比较

doi:10.3724/SP.J.1006.2021.02036

作物学报 ›› 2021, Vol. 47 ›› Issue (8): 1593-1602.doi: 10.3724/SP.J.1006.2021.02036

不同株型杂交籼稻对氮肥的耐受性差异比较

杨志远¹(), 舒川海¹, 张荣萍², 杨国涛², 王明田³, 秦俭⁴, 孙永健¹, 马均¹, 李娜¹^,^*()

¹四川农业大学水稻研究所/作物生理生态及栽培四川省重点实验室, 四川成都 611130
²西南科技大学生命科学与工程学院, 四川绵阳 621010
³四川省气象局, 四川成都 610072
⁴四川省农业科学院水稻高粱研究所, 四川德阳 618000

收稿日期:2020-05-23 接受日期:2021-01-11 出版日期:2021-08-12 网络出版日期:2021-02-23
通讯作者: 李娜
作者简介:E-mail: dreamislasting@163.com
基金资助:
国家重点研发计划项目(2017YFD0301706);国家重点研发计划项目(2017YFD0301701);四川省教育厅重点项目(18ZA0390)

Comparison of tolerances to nitrogen fertilizer between compact and loose hybrid indica rice varieties

YANG Zhi-Yuan¹(), SHU Chuan-Hai¹, ZHANG Rong-Ping², YANG Guo-Tao², WANG Ming-Tian³, QIN Jian⁴, SUN Yong-Jian¹, MA Jun¹, LI Na¹^,^*()

¹Rice Research Institute, Sichuan Agricultural University/Crop Ecophysiology and Cultivation Key Laboratory of Sichuan Province, Chengdu 611130, Sichuan, China
²School of Life Science and Engineering, Southwest University of Science and Technology, Mianyang 611000, Sichuan, China
³Sichuan Provincial Meteorological Service, Chengdu 610072, Sichuan, China
⁴Institute of Rice and Sorghum, Sichuan Academy of Agricultural Sciences, Deyang 618000, Sichuan, China

Received:2020-05-23 Accepted:2021-01-11 Published:2021-08-12 Published online:2021-02-23
Contact: LI Na
Supported by:
National Key Research and Development Program of China(2017YFD0301706);National Key Research and Development Program of China(2017YFD0301701);Scientific Research Fund of Sichuan Provincial Education Department(18ZA0390)

摘要/Abstract

摘要：

本研究通过3个大田裂区试验探究紧凑型杂交籼稻(compact hybrid rice, CHR)和松散型杂交籼稻(loose hybrid rice, LHR)品种对氮肥的耐受性差异。试验于2016—2018年在四川绵阳和成都实施, 主区为2个不同类型水稻品种各2个: 紧凑型杂交稻(CHR)隆两优1206和Y两优1号、松散型杂交稻(LHR)宜香优2115和F优498, 副区为4个施氮量: 0 (N0)、90 (N90)、150 (N150)和210 (N210)。结果表明, CHR对高氮耐受性优于LHR, 施氮量≤150 kg hm^-2时, LHR产量高于CHR, 施氮量达到210 kg hm^-2时, CHR单穗重优势升至14.46%, 而有效穗劣势降至12.46%, 产量较LHR高1.43%。偏最小二乘回归分析显示, 高峰苗、拔节至抽穗期生长速率、叶面积指数(leaf area index, LAI)及表征叶片伸展程度的消光系数(K值)对CHR和LHR产量贡献均为正向, 成穗率和抽穗期有效穗占比对产量贡献为负, 对氮肥农学利用率的影响则相反; 除K值外, 其余指标对产量贡献相近, 氮肥农学利用率亦如此。N0和N90条件下, CHR的LAI和K值均小于LHR, 光能截获率亦低于LHR; 施氮量由150 kg hm^-2增长至210 kg hm^-2, CHR的K值显著提高, 而LHR几乎无变化, 最终CHR抽穗期光能截获率超越LHR, 表明紧凑型杂交稻叶片伸展对高氮响应灵敏。

关键词: 水稻, 紧凑型杂交稻, 松散型杂交稻, 施氮量, 耐肥性

Abstract:

To explore the tolerances of compact hybrid rice (CHR) and loose hybrid rice (LHR) varieties to nitrogen fertilizer, three split-plot designed experiments were applied with main plot of four rice varieties (Longliangyou 1206, CHR; Y Liangyou 1, CHR; Yixiangyou 2115, LHR; and Fyou 498, LHR), and the sub-plot contained four N application rates (0 kg hm^-2, N0; 90 kg hm^-2, N90; 150 kg hm^-2, N150; and 210 kg hm^-2, N210). The results revealed that CHR was more tolerant to high nitrogen than LHR, and when the applied nitrogen was not higher than 150 kg hm^-2, the yields of LHR were higher than those of CHR. When the applied nitrogen reached 210 kg hm^-2, the single panicle weight advantage of CHR increased to 14.46%, while the effective panicle disadvantage decreased to 12.46%, then the yield of CHR was 1.43% higher than that of LHR. Partial least squares regression analysis showed that peak seedlings, growth rate from elongation to heading stage, leaf area index (LAI) and extinction coefficient (K-value) which characterized the degree of leaf stretching were positive contributions to CHR and LHR. The effective panicle rate at elongation and heading stages contributed negatively to the yield, but had the opposite effect on the agronomic efficiency of nitrogen fertilizer. Except K-value, the other indicators contributed similarly to yield, as did the agronomic efficiency of nitrogen fertilizer. Under N0 and N90, LAI and K-values of CHR were smaller than LHR, and the radiation interception rate was also lower than LHR. When nitrogen applied increased from 150 kg hm^-2 to 210 kg hm^-2, the K-value of CHR increased significantly, while LHR almost unchanged, resulting in the higher radiation interception rate at heading stage of CHR than LHR, indicating that the leaf stretching of CHR was sensitive to high nitrogen.

Key words: rice, compact hybrid rice, loose hybrid rice, nitrogen application rate, nitrogen tolerance

杨志远, 舒川海, 张荣萍, 杨国涛, 王明田, 秦俭, 孙永健, 马均, 李娜. 不同株型杂交籼稻对氮肥的耐受性差异比较[J]. 作物学报, 2021, 47(8): 1593-1602.

YANG Zhi-Yuan, SHU Chuan-Hai, ZHANG Rong-Ping, YANG Guo-Tao, WANG Ming-Tian, QIN Jian, SUN Yong-Jian, MA Jun, LI Na. Comparison of tolerances to nitrogen fertilizer between compact and loose hybrid indica rice varieties[J]. Acta Agronomica Sinica, 2021, 47(8): 1593-1602.

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地点 Location	年份 Year	全生育期降雨量	全生育期日照时数 Total sunshine hours of WGS (h)	全生育期日平均温度 Average diurnal temperature of WGS (℃)
地点 Location	年份 Year	Total rainfall of WGS (mm)	全生育期日照时数 Total sunshine hours of WGS (h)	全生育期日平均温度 Average diurnal temperature of WGS (℃)
绵阳 Mianyang	2016	426.0	757.3	23.88
成都 Chengdu	2017	538.8	630.3	22.32
成都 Chengdu	2018	571.4	648.2	22.51

地点 Location	年份 Year	有机质 Organic matter (g kg^-1)	全氮 Total N (g kg^-1)	速效氮 Available N (mg kg^-1)	速效磷 Available P (mg kg^-1)	速效钾 Available K (mg kg^-1)
绵阳 Mianyang	2016	22.38	1.89	98.45	21.89	101.22
成都 Chengdu	2017	24.55	2.11	118.04	28.91	109.23
成都 Chengdu	2018	21.72	2.01	102.45	24.04	98.67

类型 Type	品种 Variety	有效穗数Panicle m^-2	单穗重量Panicle weight (g)	产量 Grain yield (g m^-2)	农学利用率AEN (kg kg^-1)	叶张角 Leaf opening angel			叶基角 Leaf basal angel			叶片披垂度 Leaf drooping degree
类型 Type	品种 Variety	有效穗数Panicle m^-2	单穗重量Panicle weight (g)	产量 Grain yield (g m^-2)	农学利用率AEN (kg kg^-1)	剑叶Flag leaf	倒二叶2nd leaf from top	倒三叶3rd leaf from top	剑叶 Flag leaf	倒二叶2nd leaf from top	倒三叶3rd leaf from top	剑叶 Flag leaf	倒二叶2nd leaf from top	倒三叶3rd leaf from top
CHR	LLY	191.38 b	5.05 b	968 b	19.85 b	13.17 d	17.08 b	19.13 b	11.10 c	14.22 b	17.84 b	2.07 b	2.86 b	1.29 b
CHR	YLY	167.32 c	6.44 a	1078 a	24.98 a	14.09 c	17.95 b	19.73 b	11.80 bc	14.96 b	18.87 b	2.29 b	2.99 b	1.36 b
LHR	YXY	203.70 a	4.78 b	974 b	20.30 b	18.34 b	24.04 a	27.09 a	13.14 b	18.09 a	23.21 a	5.20 a	5.95 a	3.88 a
LHR	FY	186.02 b	6.16 a	1146 a	25.88 a	20.77 a	25.64 a	27.68 a	15.12 a	18.41 a	23.62 a	5.65 a	7.23 a	4.06 a

项目 Item	产量 Grain yield	有效穗数Panicles	单穗重量Panicle weight	氮肥农学利用率 AEN	稻株叶面积指数 LAI at full heading stage	稻株叶片消光系数 K-value at full heading stage
品种(V)	8.86^*	318.66^***	305.36^***	4.11 ^ns	580.71^***	20.65^**
施氮量(N)	748.17^***	1363.77^***	108.12^***	12.86^***	219.77^***	19.10^***
年份(Y)	30.07^**	45.63^***	8.55^*	2.73 ^ns	95.67^***	1.33 ^ns
V × N	5.05^**	23.72^***	14.65^***	1.72 ^ns	3.29^*	8.22^***
V × Y	0.62 ^ns	0.06 ^ns	2.84 ^ns	0.05 ^ns	1.81 ^ns	0.12 ^ns
N × Y	0.82 ^ns	0.70 ^ns	0.27 ^ns	0.29 ^ns	0.40 ^ns	0.92 ^ns
V × N × Y	0.07 ^ns	0.29 ^ns	0.17 ^ns	0.03 ^ns	0.18 ^ns	0.84 ^ns

品种类型 Variety type	施氮处理 N treatment	2016				2017			2018
品种类型 Variety type	施氮处理 N treatment	有效穗 Panicle (×10⁴ hm^-2)	单穗重量 Panicle weight (g)		产量 Grain yield (kg hm^-2)	有效穗 Panicle (×10⁴ hm^-2)	单穗重量 Panicle weight (g)	产量 Grain yield (kg hm^-2)	有效穗 Panicle (×10⁴ hm^-2)	单穗重量 Panicle weight (g)	产量 Grain yield (kg hm^-2)
紧凑型杂交稻 Compact hybrid rice (CHR)	N0	127.6 d	5.23 c	6677 d		126.28 d	5.26 d	6651 d	122.14 d	5.11 c	6242 d
	N90	149.03 c	6.03 a	8988 c		142.73 c	6.23 a	8831 c	142.83 c	5.93 a	8471 c
	N150	174.27 b	5.85 ab	10,189 b		170.14 b	5.97 b	10,251 b	170.00 b	5.77 a	9801 b
	N210	203.83 a	5.65 b	11,520 a		204.02 a	5.68 c	11,340 a	199.03 a	5.40 b	10,757 a
平均值Average		163.68	5.69	9343		160.79	5.79	9268	158.50	5.55	8818
松散型杂交稻 Loose hybrid rice (LHR)	N0	144.44 d	5.11 b	7378 c		139.51 d	5.00 bc	7016 d	137.19 d	5.00 bc	6857 c
	N90	165.1 c	5.82 a	9593 b		159.1 c	5.80 a	9159 c	160.29 c	5.67 a	9084 b
	N150	212.31 b	5.19 b	11,017 a		208.38 b	5.21 b	10,570 b	203.31 b	5.12 b	10,401 a
	N210	227.55 a	4.94 b	11,239 a		231.06 a	4.89 c	11,176 a	223.89 a	4.79 c	10,721 a
平均值Average		187.35	5.26	9807		184.51	5.22	9480	181.17	5.14	9266
F值 F-value	V	728.70^**	42.03^**	22.64^*		3342.60^**	587.96^**	58.58^*	150.02^**	38.71^**	5.23 ^ns
	N	393.50^**	30.33^**	163.76^**		757.14^**	53.67^**	304.18^**	393.38^**	46.81^**	250.32^**
	V×N	7.99^**	6.22^**	2.87 ^ns		16.83^**	5.72^*	1.29 ^ns	5.04^*	6.66^**	1.90 ^ns

不同株型杂交籼稻对氮肥的耐受性差异比较

Comparison of tolerances to nitrogen fertilizer between compact and loose hybrid indica rice varieties

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品种类型Variety type	施氮处理 N treatment	2016			2017			2018
品种类型Variety type	施氮处理 N treatment	叶面积指数LAI	光能截获率RIR	消光系数 K	叶面积指数LAI	光能截获率RIR	消光系数 K	叶面积指数LAI	光能截获率RIR	消光系数 K
紧凑型杂交稻 Compact hybrid rice (CHR)	N0	6.04 c	78.34 d	0.25 c	5.60 d	77.26 c	0.27 b	5.61 c	77.00 c	0.26 a
	N90	6.90 b	84.05 c	0.27 c	6.36 c	82.14 c	0.27 b	6.40 b	82.98 b	0.28 a
	N150	7.57 a	92.04 b	0.34 b	6.83 b	88.95 b	0.33 b	7.15 a	91.39 a	0.35 a
	N210	8.05 a	95.97 a	0.40 a	7.48 a	96.23 a	0.45 a	7.58 a	93.10 a	0.35 a
平均Average		7.14	87.60	0.32	6.57	86.15	0.33	6.68	86.12	0.31
松散型杂交稻 Loose hybrid rice (LHR)	N0	6.87 d	83.87 c	0.27 a	6.04 d	80.95 b	0.28 a	6.34 d	81.98 c	0.27 b
	N90	7.72 c	87.55 b	0.27 a	7.21 c	87.30 a	0.29 a	7.28 c	87.18 b	0.29 b
	N150	8.71 b	90.76 b	0.27 a	7.78 b	89.04 a	0.30 a	8.12 b	89.35 ab	0.28 a
	N210	9.34 a	94.55 a	0.32 a	8.61 a	92.26 a	0.30 a	8.81 a	92.17 a	0.29 a
平均Average		8.16	89.18	0.28	7.41	87.38	0.29	7.64	87.67	0.28
F值 F value	V	160.52^**	25.69^**	4.26 ^ns	747.58^**	1.87 ^ns	14.27 ^ns	146.40^**	1.88 ^ns	6.17 ^ns
	N	71.83^**	57.50^**	12.69^**	80.81^**	19.71^**	4.62^*	69.36^**	75.30^**	8.67^**
	V×N	1.02 ^ns	4.52^*	2.93 ^ns	1.96 ^ns	1.98 ^ns	2.98 ^ns	0.82 ^ns	6.92^**	6.16^**

品种类型 Variety type	指标 Trait	标准回归系数 Standard regression coefficient	决定系数 R²
紧凑型杂交稻	叶面积指数 LAI	0.553^**	0.960^**
Compact hybrid rice	消光系数 K	0.503^**	0.960^**
松散型杂交稻	叶面积指数 LAI	0.736^**	0.960^**
Loose hybrid rice	消光系数 K	0.521^**	0.960^**

品种类型 Variety type	指标 Trait	产量 Grain yield		氮肥农学利用率 AEN
品种类型 Variety type	指标 Trait	标准偏回归系数 Standard partial regression coefficient	决定系数 R²	标准偏回归系数 Standard partial regression coefficient	决定系数 R²
紧凑型杂交稻 Compact hybrid rice	高峰苗 Peak tiller number	0.1796	0.8325^**	0.1188	0.3639^**
	成穗率 Ear-bearing tiller percentage	-0.1776		0.1174
	拔节至抽穗生长速率 Growth rate from jointing to heading	0.1661		-0.1098
	抽穗期有效穗占比 Ear-bearing tiller percentage at heading	-0.1724		0.114
	叶面积指数 LAI	0.1498		-0.099
	消光系数 K	0.1501		-0.0992
松散型杂交稻 Loose hybrid rice	高峰苗 Peak tiller number	0.1806	0.6351^**	-0.1454	0.4117^**
	成穗率 Ear-bearing tiller percentage	-0.1622		0.1306
	拔节至抽穗生长速率 Growth rate from jointing to heading	0.1605		-0.1292
	抽穗期有效穗占比 Ear-bearing tiller percentage at heading	-0.1758		0.1416
	叶面积指数 LAI	0.1631		-0.1313
	消光系数 K	0.0574		-0.0462

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