过量施氮对西藏河谷农区青稞生长发育的影响

doi:10.11924/j.issn.1000-6850.casb2023-0111

中国农学通报 ›› 2024, Vol. 40 ›› Issue (4): 6-13.doi: 10.11924/j.issn.1000-6850.casb2023-0111

过量施氮对西藏河谷农区青稞生长发育的影响

谈建鑫¹^,²(), 同坚¹^,², 贠民政¹^,², 降志兵¹^,², 梁莎¹^,²

¹ 西藏自治区农牧科学院农业研究所，拉萨 850032
² 省部共建青稞和牦牛种质资源与遗传改良国家重点实验室，拉萨 850032

收稿日期:2023-02-06 修回日期:2023-06-07 出版日期:2024-02-05 发布日期:2024-01-29
作者简介:
谈建鑫，男，1991年出生，甘肃定西人，助理研究员，硕士，研究方向：农作物栽培机理与成果转化。通信地址：850032 西藏拉萨市金珠西路157号区农科院农业研究所，E-mail：990020503@qq.com。
基金资助:
西藏青稞品种区域布局与配套栽培技术集成示范(XZ2021ZD004N-04); 西藏自治区农牧科学院农业研究所统筹项目“春青稞新品系13-5171、13-6927氮磷钾配施试验”(2021-XZNYS-TCXM-0005); 中华全国总工会职工创新补助资金项目“春青稞新品系氮磷钾配施研究”

Effects of Excessive Nitrogen Application on the Growth and Development of Highland Barley in Tibet Valley Agricultural Area

TAN Jianxin¹^,²(), TONG Jian¹^,², YUN Minzheng¹^,², JIANG Zhibing¹^,², LIANG Sha¹^,²

¹ Tibet Academy of Agricultural and Animal Husbandry Sciences, Lhasa 850032
² State Key Laboratory of Barley and Yak Germplasm Resources and Genetic Improvement, Lhasa 850032

Received:2023-02-06 Revised:2023-06-07 Published-:2024-02-05 Online:2024-01-29

摘要/Abstract

摘要：

摸清过量施氮下不同青稞品种（系）生长发育指标的变化和调控机制，为西藏河谷农区青稞高产高效栽培提供科学依据。本研究设置N₁（施氮量70 kg/hm²，常规施氮处理）、N₂（施氮量172.5 kg/hm²）、N₃（施氮量275 kg/hm²）、N₄（施氮量345 kg/hm²）4个施氮处理，CK（施氮量0 kg/hm²）为不施氮处理，比较分析不同施氮量水平下，青稞品种‘藏青3000’和青稞品系‘6927’的株高、分蘖和成穗、叶绿素、粒重和籽粒灌浆特性、氮素利用和产量等因子的变化。结果表明，施氮对青稞的基本苗没有影响，青稞分蘖率呈现出先增加后降低的趋势，相同处理下‘6927’的最高茎蘖数高于‘藏青3000’；随着施氮量的增加，青稞成穗数呈现减少的趋势；随着施氮量的增加，所有生育期的株高均表现为先升高后降低或增加不明显的趋势；随着施氮量的增加，叶绿素SPAD值呈先增加后不再显著增加或降低的趋势，‘藏青3000’各施氮处理的旗叶叶绿素SPAD值高于‘6927’；施氮可明显提高青稞各生育期粒重，粒重在开花后7~28 d时增高趋势十分明显，于花后35 d达到最大值，常规施氮的实际粒重和理论最大千粒重均高于其他处理，本研究2个青稞品种（系）最大灌浆速率(V_max)和平均灌浆速率(V_mean)均出现在N₂处理；青稞的产量随着施氮量的增加呈现出减少的趋势，相同处理下‘藏青3000’产量均高于‘6927’；氮肥农学利用率和氮肥偏生产力均随着施氮量的增加而降低。

关键词: 青稞, 西藏, 氮, 生长发育, 产量

Abstract:

To find out the change and regulation mechanism of growth and development indexes of different highland barley varieties under excessive nitrogen application, providing scientific foundations for high-yield and high efficiency cultivation of highland barley in the Tibet river valley, five fertilization treatments were set in this study, including N₁ (70 kg/hm² of nitrogen, conventional nitrogen application treatment), N₂ (172.5 kg/hm² of nitrogen), N₃ (275 kg/hm² of nitrogen), N₄ (275 kg/hm² of nitrogen) and CK (0 kg/hm²of nitrogen), to compare and analyze the variations of plant height, tiller and spike rate, chlorophyll, grain filling, nitrogen utilization and yield of the highland barley varieties ‘Zangqing 3000’ and ‘6927’ under different nitrogen application levels. The results showed that there was no significant difference on the basic seedlings in different treatments, the variation of tillering rate increased first and then decreased. The tiller number of ‘6927’ was higher than that of ‘Zangqing 3000’ under the same treatment; the number of spike decreased with the increase of nitrogen application; the plant height increased first and then decreased or no significant difference in growth stage with the increasing of nitrogen application rate; the chlorophyll SPAD increased first and then kept stable or decreased significantly with the increase of nitrogen application rate; the chlorophyll SPAD of ‘Zangqing 3000’ was higher than that of ‘6927’ under the same treatment; nitrogen application could increase the grain weight significantly in each growth period, the grain weight increased significantly from 7 to 28 days after flowering date, reached the maximum value on 35^th days after flowering. The actual grain weight and theoretical maximum of thousand-grain weight of conventional nitrogen application were higher than that of other treatments. In this study, the maximum grouting rate (V_max) and average grouting rate (V_mean) of two highland barley varieties (lines) were in N₂ treatment; the yield of highland barley decreased with the increase of nitrogen application, and the yield of ‘Zangqing 3000’ was higher than that of ‘6927’under the same treatment; the nitrogen agronomic efficiency and nitrogen partial factor productivity decreased with the increasing of nitrogen application rate.

Key words: highland barley, Tibet, nitrogen, growth and development, yield

谈建鑫, 同坚, 贠民政, 降志兵, 梁莎. 过量施氮对西藏河谷农区青稞生长发育的影响[J]. 中国农学通报, 2024, 40(4): 6-13.

TAN Jianxin, TONG Jian, YUN Minzheng, JIANG Zhibing, LIANG Sha. Effects of Excessive Nitrogen Application on the Growth and Development of Highland Barley in Tibet Valley Agricultural Area[J]. Chinese Agricultural Science Bulletin, 2024, 40(4): 6-13.

图/表 10

参考文献 19

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品种	处理	基本苗/(万株/hm²)	最高茎蘖数/(万/hm²)	成穗数/(万/hm²)	分蘖率	分蘖成穗率
藏青3000	N₁	333.35±17.41a	740.04±38.65bcd	532.83±27.83b	2.22	0.72
	N₂	325.05±5.79a	796.38±14.17abc	541.54±9.64b	2.45	0.68
	N₃	327.57±23.40a	815.65±58.28ab	432.30±30.89cd	2.49	0.53
	N₄	336.46±10.44a	817.60±25.37abc	408.80±12.68d	2.43	0.50
	CK	323.13±5.59a	665.64±11.51d	432.67±7.48cd	2.06	0.65
6927	N₁	332.91±12.33a	792.32±29.35abc	647.43±30.93a	2.38	0.82
	N₂	331.08±5.48a	867.41±14.35a	631.12±12.41a	2.62	0.73
	N₃	332.02±14.73a	883.16±39.18a	518.76±37.06b	2.66	0.59
	N₄	325.35±11.93a	845.91±31.00ab	490.56±15.22bc	2.60	0.58
	CK	323.13±22.91a	710.88±50.40cd	519.20±8.98b	2.20	0.73

品种	处理	基本苗/(万株/hm²)	最高茎蘖数/(万/hm²)	成穗数/(万/hm²)	分蘖率	分蘖成穗率
藏青3000	N₁	333.35±17.41a	740.04±38.65bcd	532.83±27.83b	2.22	0.72
	N₂	325.05±5.79a	796.38±14.17abc	541.54±9.64b	2.45	0.68
	N₃	327.57±23.40a	815.65±58.28ab	432.30±30.89cd	2.49	0.53
	N₄	336.46±10.44a	817.60±25.37abc	408.80±12.68d	2.43	0.50
	CK	323.13±5.59a	665.64±11.51d	432.67±7.48cd	2.06	0.65
6927	N₁	332.91±12.33a	792.32±29.35abc	647.43±30.93a	2.38	0.82
	N₂	331.08±5.48a	867.41±14.35a	631.12±12.41a	2.62	0.73
	N₃	332.02±14.73a	883.16±39.18a	518.76±37.06b	2.66	0.59
	N₄	325.35±11.93a	845.91±31.00ab	490.56±15.22bc	2.60	0.58
	CK	323.13±22.91a	710.88±50.40cd	519.20±8.98b	2.20	0.73

品种	处理	拟合方程	R²	t₁/d	t₂/d	(t₂-t₁)/d	T_max/d	V_mean/(g/d)	V_max/(g/d)
藏青3000	N₁	y=53.263/(1+28.02e^-0.168^t)	0.985^**	12	27.68	15.68	19.84	1.49	2.24
	N₂	y=46.991/(1+41.049e^-0.21^t)	0.997^**	11.42	23.96	12.54	17.69	1.64	2.47
	N₃	y=47.47/(1+20.433e^-0.185^t)	1.000^**	9.19	23.43	14.24	16.31	1.46	2.20
	N₄	y=44.833/(1+15.445e^-0.165^t)	0.995^**	8.61	24.57	15.96	16.59	1.23	2.24
	CK	y=40.877/(1+57.268e^-0.205^t)	0.999^**	13.32	26.17	12.85	19.75	1.40	2.09
6927	N₁	y =37.675/(1+24.471e^-0.169^t)	0.997^**	10.76	24.41	13.65	17.58	1.09	1.64
	N₂	y=33.446/(1+118.778e^-0.258^t)	0.966^**	13.41	23.62	10.21	18.52	1.44	2.16
	N₃	y=33.196/(1+41.279e^-0.2^t)	0.993^**	12.02	25.19	13.17	18.6	1.11	1.66
	N₄	y=32.578/(1+84.948e^-0.234^t)	0.999^**	13.35	24.61	11.26	18.98	1.27	1.91
	CK	y=30.828/(1+51.075e^-0.192^t)	0.983^**	13.63	27.35	13.72	20.49	0.99	1.48

品种	处理	拟合方程	R²	t₁/d	t₂/d	(t₂-t₁)/d	T_max/d	V_mean/(g/d)	V_max/(g/d)
藏青3000	N₁	y=53.263/(1+28.02e^-0.168^t)	0.985^**	12	27.68	15.68	19.84	1.49	2.24
	N₂	y=46.991/(1+41.049e^-0.21^t)	0.997^**	11.42	23.96	12.54	17.69	1.64	2.47
	N₃	y=47.47/(1+20.433e^-0.185^t)	1.000^**	9.19	23.43	14.24	16.31	1.46	2.20
	N₄	y=44.833/(1+15.445e^-0.165^t)	0.995^**	8.61	24.57	15.96	16.59	1.23	2.24
	CK	y=40.877/(1+57.268e^-0.205^t)	0.999^**	13.32	26.17	12.85	19.75	1.40	2.09
6927	N₁	y =37.675/(1+24.471e^-0.169^t)	0.997^**	10.76	24.41	13.65	17.58	1.09	1.64
	N₂	y=33.446/(1+118.778e^-0.258^t)	0.966^**	13.41	23.62	10.21	18.52	1.44	2.16
	N₃	y=33.196/(1+41.279e^-0.2^t)	0.993^**	12.02	25.19	13.17	18.6	1.11	1.66
	N₄	y=32.578/(1+84.948e^-0.234^t)	0.999^**	13.35	24.61	11.26	18.98	1.27	1.91
	CK	y=30.828/(1+51.075e^-0.192^t)	0.983^**	13.63	27.35	13.72	20.49	0.99	1.48

品种	处理	产量/(kg/hm²)	氮肥农学利用率/(kg/kg)	氮肥偏生产力/(kg/kg)
藏青3000	N₁	5811.23±59.71a	54.42±1.27a	83.02±0.85a
	N₂	4685.28±243.19b	15.55±1.41c	27.16±1.41c
	N₃	4154.08±419.05bc	7.83±1.47d	15.10±1.52d
	N₄	3520.38±553.93cd	4.40±1.56d	10.20±1.61d
	CK	2002.13±29.74e	—	—
6927	N₁	4357.88±311.86bc	35.22±4.65b	62.26±4.46b
	N₂	3761.81±9.72bcd	10.84±0.13cd	10.90±0.03d
	N₃	3656.7±39.66bcd	6.41±0.12d	13.30±0.14d
	N₄	2852.15±160.96d	2.78±0.43d	8.27±0.47d
	CK	1892.63±15.88e	—	—

过量施氮对西藏河谷农区青稞生长发育的影响

Effects of Excessive Nitrogen Application on the Growth and Development of Highland Barley in Tibet Valley Agricultural Area

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	千粒重	平均灌浆速率	最大灌浆速率
千粒重	1
平均灌浆速率	0.675^*	1
最大灌浆速率	0.747^*	0.9236^**	1

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