追氮量对不同品质类型小麦产量及光合性能的影响

doi:10.16035/j.issn.1001-7283.2022.02.019

Abstract

Abstract:

The experiment was carried out at the Beijing Experimental Base of the Institute of Crop Sciences, Chinese Academy of Agricultural Sciences during 2016-2017. A two-factor randomized block design was used to study the effects of topdressing nitrogen rates on the yield and physiological indicators of different gluten wheat. The tested materials were medium gluten varieties from the Huanghuai winter wheat area (Zhongmai 8 and Zhongmai 175); weak gluten varieties from the winter wheat area in the middle and lower reaches of the Yangtze River (Yangmai 22 and Yangmai 15). The results showed that increasing the rates of topdressing nitrogen had an increasing effect on the contents of chlorophyll a and b in the flag leaves and was more conducive to the formation of chlorophyll b. The effect was most obvious when the topdressing nitrogen rate was 135kg/ha. Under the experiment conditions, net photosynthetic rate, stomatal conductance, transpiration rate and leaf temperature of flag leaves of each wheat variety gradually increased with the increase of nitrogen topdressing rates and the growth rate also gradually increased with the highest nitrogen topping amount of 135kg/ha. The intercellular CO₂concentration of the flag leaf gradually decreased with the increase of the rates of topdressing nitrogen and all varieties showed the same trend of change. The grain yields of medium-gluten wheat varieties was significantly higher than that of weak-gluten wheat varieties. In the topdressing nitrogen range of 75-135kg/ha, the grain yield, the number of spikes, grains number per spike, 1000-grain weight, and the biological yield of each variety increased significantly with the increase of topdressing nitrogen rates and it reached the highest at 135kg/ha. In summary, under the same ecological conditions in this experiment, applying nitrogen fertilizer at the jointing stage was beneficial to increase the chlorophyll content of flag leaves of middle-gluten and weak-gluten wheat, improved its photosynthetic performance, promoted the absorption and accumulation of nitrogen by plants, and increased yield.

Key words: Wheat, Quality type, Yield, Photosynthetic performance, Topdressing nitrogen rate

Ma Ruiqi, Wang Demei, Wang Yanjie, Yang Yushuang, Zhao Guangcai, Chang Xuhong. Effects of Topdressing Nitrogen Rates on Yield and Photosynthetic Performance of Different Quality Types of Wheat[J].Crops, 2022, 38(2): 134-142.

Figures/Tables 10

Fig.1

Fig.2

Table 1

Effects of different treatments on chlorophyll contents of wheat flag leaves after anthesis"

品种 Variety	处理 Treatment	Chla [mg/(g FW)]					Chlb [mg/(g FW)]
		开花后天数Days after anthesis					开花后天数Days after anthesis
		0d	7d	14d	21d	28d	0d	7d	14d	21d	28d
中麦8号Zhongmai 8	B₁	3.46f	3.98g	3.40h	2.08j	1.58bc	1.18abc	1.28abc	0.96nh	0.49j	0.33e
	B₂	3.58ef	4.06fg	3.41gh	2.16i	1.66b	1.08e	1.31abc	1.02fg	0.54i	0.38d
	B₃	3.68de	4.47bc	3.75c	2.35h	1.85a	1.17abc	1.32abc	1.03f	0.63h	0.44b
中麦175 Zhongmai 175	B₁	3.60ef	4.09f	3.39h	2.43g	1.15e	1.21ab	1.07d	0.96h	0.73g	0.37d
	B₂	4.01c	4.38cd	3.45g	2.55ef	1.35d	1.08e	1.20c	0.99g	0.78f	0.39cd
	B₃	4.14b	4.44c	3.62de	2.67b	1.50c	1.10de	1.23bc	1.05e	0.82de	0.46a
扬麦22 Yangmai 22	B₁	4.18b	4.42cd	3.51f	2.63bc	1.13e	1.16bc	1.30abc	1.14c	0.84d	0.33e
	B₂	4.34a	4.53ab	3.66d	2.67b	1.40d	1.22a	1.27abc	1.30a	0.89bc	0.39cd
	B₃	4.42a	4.56a	4.02a	2.76a	1.56c	1.09de	1.34ab	1.31a	0.99a	0.40c
扬麦15 Yangmai 15	B₁	3.49fg	4.26e	3.43gh	2.50f	1.15e	1.17bc	1.04d	1.11d	0.80ef	0.33e
	B₂	3.80d	4.34de	3.61e	2.56de	1.36d	1.13cd	1.29abc	1.16c	0.87c	0.40c
	B₃	4.12b	4.38cd	3.95b	2.60cd	1.40d	1.16bc	1.38a	1.25b	0.92b	0.44b
中麦8号Zhongmai 8	B₁	5.26de	3.98g	4.35h	2.57i	1.91cd	2.93f	3.11d	3.54b	4.27a	4.80a
	B₂	4.66f	5.37d	4.42g	2.70h	2.04b	3.32d	3.35d	4.02b	4.38b	0.44b
	B₃	4.86e	5.78ab	4.78d	2.99g	2.29a	3.14e	3.40cd	3.65a	3.72c	4.19b
中麦175 Zhongmai 175	B₁	4.81ef	5.16e	4.35h	3.16f	1.52g	2.99f	3.84ab	3.51bc	3.33d	3.11g
	B₂	5.09cd	5.57c	4.44g	3.32e	1.74f	3.70bc	3.71bc	3.47bc	3.27de	3.46de
	B₃	5.25bc	5.66bc	4.68e	3.49c	1.97bc	3.75b	3.62bc	3.44c	3.24de	3.25efg
扬麦22 Yangmai 22	B₁	5.34b	5.72bc	4.66e	3.47cd	1.45g	3.59c	3.40cd	3.08e	3.13def	3.45de
	B₂	5.56a	5.80ab	4.96c	3.56b	1.79ef	3.56c	3.58bc	2.82f	2.99fg	3.60d
	B₃	5.51a	5.90a	5.33a	3.75a	1.97bc	4.07a	3.42cd	3.07e	2.80g	3.87c
扬麦15 Yangmai 15	B₁	4.66f	5.30de	4.54f	3.30e	1.48g	3.00ef	4.11a	3.09e	3.12ef	3.43de
	B₂	4.93de	5.63de	4.76d	3.43d	1.76ef	3.35d	3.36cd	3.11e	2.93fg	3.38ef
	B₃	5.29b	5.76ab	5.20b	3.52bc	1.84de	3.55c	3.18d	3.15e	2.84g	3.18fg

Table 1

Fig.3

Fig.4

Fig.5

Fig.6

Fig.7

Table 2

Table 3

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品种/处理 Variety/Treatment	籽粒产量 Grain yield (kg/hm²)	千粒重 1000-grain weight (g)	穗数 Ears number (×10⁴/hm²)	穗粒数 Grain number per spike	生物产量 Biological yield (kg/hm²)	氮肥偏生产力 PFPN (kg/kg)
中麦8号Zhongmai 8	8 038.0a	40.67a	563.3b	33.04c	17 978.9b	38.7a
中麦175 Zhongmai 175	8 037.2a	40.91a	675.0a	32.38c	21 662.3a	38.7a
扬麦22 Yangmai 22	6 937.1b	40.02b	504.3c	40.84a	16 550.2c	33.4b
扬麦15 Yangmai 15	6 624.5b	40.96a	440.4d	37.96b	14 907.1d	31.9b
B₁	7 156.9b	40.03c	529.0b	34.73b	16 601.4c	39.8a
B₂	7 432.0a	40.54b	539.8b	36.32ab	17 305.1b	35.4b
B₃	7 638.7a	41.35a	568.5a	37.12a	19 417.3a	31.8c

品种 Variety	处理 Treatment	籽粒产量 Grain yield (kg/hm²)	千粒重 1000-grain weight (g)	穗数 Ears number (×10⁴/hm²)	穗粒数 Grain number per spike	生物产量 Biological yield (kg/hm²)	氮肥偏生产力 PFPN (kg/kg)
中麦8号	B₁	7 696.0abcd	40.16def	569.7b	32.33de	17 745.0d	42.8a
Zhongmai 8	B₂	8 038.7ab	40.74bcd	545.7bc	33.07de	16 278.3e	38.3b
	B₃	8 379.2a	41.11bc	574.5b	33.73cde	19 913.4c	34.9bcd
中麦175	B₁	7 814.1abc	39.91def	670.2a	31.33e	20 188.7c	43.4a
Zhongmai 175	B₂	8 057.3ab	40.37cdef	675.0a	32.13e	21 552.9b	38.4b
	B₃	8 240.2a	42.44a	679.8a	33.67cde	23 245.2a	34.3bcde
扬麦22	B₁	6 711.7de	39.66f	483.5e	38.20abc	14 562.0f	37.3bc
Yangmai 22	B₂	6 934.0cde	39.87ef	507.5de	41.93a	16 602.5e	33.0cde
	B₃	7 165.6bcde	40.55bcde	521.8cd	42.40a	18 486.1d	29.9ef
扬麦15	B₁	6 406.0e	40.38cdef	392.6g	37.07bcd	13 910.0f	35.6bcd
Yangmai 15	B₂	6 697.8de	41.19bc	430.9f	38.13abc	14 786.8f	31.9def
	B₃	6 769.6de	41.30b	497.9de	38.67ab	16 024.3e	28.2f

Effects of Topdressing Nitrogen Rates on Yield and Photosynthetic Performance of Different Quality Types of Wheat

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