土壤水分含量对小麦耗水特性和旗叶/根系衰老特性的影响

doi:10.3724/SP.J.1006.2023.21052

Abstract

Abstract:

The objective of this study is to clarify the effect of soil water content on wheat grain yield and the physiological reasons for its formation. During the winter wheat growing season from 2019 to 2021, four kinds of soil water content treatments were set under the field conditions of the wheat test station in Shijiawangzi village, Xiaomeng town, Yanzhou district, Shandong province: No-irrigation (W0), and the relative water content of the soil in the 0-40 cm soil layer was supplemented to 65% (W1), 75% (W2), and 85% (W3) at jointing and anthesis stages, and the winter wheat variety was Jimai 22. The effects of soil water content on water consumption, leaf and root senescence, and grain yield of wheat were studied. The results showed that the number of kernel number and 1000-kernel weight of W2 treatment were significantly higher than those of other treatments, and the highest grain yield and water use efficiency were obtained. Compared with W0, W1, and W3, the grain yield was 48.49%, 20.80%, 8.68% (2019-2020) and 46.87%, 17.36%, 7.53% (2020-2021), respectively. The water use efficiency was 21.70%, 14.25%, 15.59% (2019-2020) and 25.44%, 11.90%, 13.39% (2020-2021), respectively. Compared with the other treatments, root length density in the 40-100 cm soil layer, superoxide dismutase activity and root activity in the 40-60 cm soil layer in W2 treatment were significantly higher than those in other treatments after anthesis, and the content of malondialdehyde was significantly lower than those in other treatments. After anthesis, the superoxide dismutase activity of flag leaves in W2 treatment was significantly higher than that in W0 and W1 treatments, but there was no significant difference in W3 treatment, and the content of malondialdehyde was significantly lower than that in W0 and W1 treatments, but there was no significant difference in W3 treatment. W2 treatment increased significantly water consumption, daily water consumption, water consumption model coefficient, and soil water storage consumption in the 40-120 cm soil layer from anthesis to maturity. In conclusion, the appropriate soil moisture content could promote root growth, delay plant aging, and then improve the absorption and utilization of deep soil moisture, ensure the supply of water during grain filling, and improve significantly grain yield in wheat. Under the conditions of this experiment, the effect of W2 treatment was the best when the relative water content of 0-40 cm soil layer was increased by 75% at the jointing and anthesis stages in wheat.

Key words: wheat, water consumption characteristics, senescence characteristics, grain yield

ZHANG Zhen, SHI Yu, ZHANG Yong-Li, YU Zhen-Wen, WANG Xi-Zhi. Effects of different soil water content on water consumption by wheat and analysis of senescence characteristics of root and flag leaf[J].Acta Agronomica Sinica, 2023, 49(7): 1895-1905.

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年份 Year	处理 Treatment	穗数 Spike number (×10⁴ hm^-2)	穗粒数 Kernel number	千粒重 1000-kernel weight (g)	籽粒产量 Grain yield (kg hm^-2)	水分利用效率 Water use efficiency (kg hm^-2 mm^-1)
2019-2020	W0	543.23±19.13 c	32.62±0.77 c	37.26±0.66 c	6285.82±459.86 d	16.27±0.34 c
	W1	602.40±14.50 b	33.03±0.96 c	38.47±0.98 c	7726.80±326.98 c	17.33±0.29 b
	W2	642.73±16.89 a	38.39±1.06 a	44.25±0.85 a	9333.90±323.69 a	19.80±0.45 a
	W3	660.61±16.54 a	34.81±0.68 b	40.56±0.78 b	8588.70±289.65 b	17.13±0.36 b
2020-2021	W0	559.74±17.89 c	33.25±1.25 c	38.61±0.68 c	7042.74±236.95 d	16.94±0.23 c
	W1	617.11±17.99 b	33.66±1.22 c	39.03±0.85 c	8813.56±258.97 c	18.99±0.33 b
	W2	660.76±13.69 a	40.99±1.36 a	47.65±0.95 a	10,343.60±215.98 a	21.25±0.28 a
	W3	682.72±19.78 a	36.50±0.96 b	41.85±0.77 b	9619.27±321.58 b	18.74±0.29 b

年份 Year	处理 Treatment	耗水来源 Water consumption sources (mm)			总耗水量 Total water consumption amount (mm)	占总耗水量的比例 Ratio of the total water consumption amount (%)
		灌水量 I	降雨量 P	土壤贮水消耗量 SWC		灌水量 I	降雨量 P	土壤贮水消耗量 SWC
		2019-2020	W0	0		163	224.26±6.36 a	387.26±10.25 d	0	42.09±1.14 a	57.91±2.69 a
W1	88.97±14.56 c		163	200.78±5.69 b	452.75±8.89 c	19.61±1.06 c	36.00±1.21 b	44.35±2.58 b
W2	115.28±12.63 b		163	197.15±4.56 b	475.43±9.58 b	24.25±1.89 b	34.28±1.03 c	41.47±1.21 c
W3	150.00±15.96 a		163	187.52±5.32 c	500.52±10.59 a	29.97±1.59 a	32.57±0.96 d	37.46±2.10 d
2020-2021	W0	0	202.5	213.25±4.36 a	415.75±10.07 d	0	48.71±1.36 a	51.29±2.69 a
	W1	59.56±10.26 c	202.5	201.95±3.69 b	464.01±8.26 c	12.84±1.35 c	43.64±1.68 b	43.52±1.05 b
	W2	81.40±8.25 b	202.5	202.97±4.69 b	486.87±8.56 b	16.72±1.54 b	41.59±1.64 c	41.69±1.23 c
	W3	119.34±11.69 a	202.5	190.56±3.59 c	513.40±9.65 a	22.66±1.14 a	39.44±1.89 d	37.90±1.84 d

年份 Year	处理 Treatment	播种-拔节期Sowing-jointing			拔节期-开花期Jointing-anthesis			开花期-成熟期Anthesis-maturity
年份 Year	处理 Treatment	CW (mm)	DW (mm d^-1)	PW (%)	CW (mm)	DW (mm d^-1)	PW (%)	CW (mm)	DW (mm d^-1)	PW (%)
2019- 2020	W0	185.56± 4.25	1.08± 0.05	47.92± 1.26 a	103.45± 496 c	5.17± 0.23 c	26.71± 2.46 b	98.25± 9.68 c	2.28± 0.65 c	25.37± 1.69 c
	W1	185.56± 4.25	1.08± 0.05	40.99± 1.36 b	116.17± 3.69 b	5.81± 0.25 b	25.66± 1.69 b	151.02± 11.26 b	3.51± 0.46 b	33.35± 1.58 b
	W2	185.56± 4.25	1.08± 0.05	39.03± 1.65 c	117.14± 5.51 b	5.86± 0.19 b	24.64± 2.18 b	172.73± 8.46 a	4.02± 0.23 a	36.33± 2.36 a
	W3	185.56± 4.25	1.08± 0.04	37.07± 0.69 d	157.16± 6.98 a	7.86± 0.21 a	31.40± 2.36 a	157.80± 8.74 b	3.67± 0.31 b	31.53± 2.14 b
2020- 2021	W0	232.54± 5.26	1.27± 0.03	55.93± 1.23 a	64.52± 3.25 c	3.23± 0.29 c	15.52± 2.96 b	118.69± 5.42 d	2.63± 0.15 c	28.55± 1.84 c
	W1	232.54± 5.26	1.27± 0.03	50.12± 1.69 b	74.62± 2.69 b	3.73± 0.24 b	16.08± 3.21 b	156.85± 4.26 c	3.49± 0.16 b	33.80± 2.08 b
	W2	232.54± 5.26	1.27± 0.03	47.76± 1.24 c	77.05± 3.65 b	3.85± 0.26 b	15.83± 1.98 b	177.28± 4.89 a	3.94± 0.24 a	36.41± 1.69 a
	W3	232.54± 5.26	1.27±0.03	45.29± 1.34 d	116.18± 2.85 a	5.81± 027 a	22.63± 2.37 a	164.68± 3.96 b	3.66± 0.19 b	32.08± 1.69 b

Effects of different soil water content on water consumption by wheat and analysis of senescence characteristics of root and flag leaf

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