有机物料还田对夏玉米穗位叶光合性能及氮代谢的影响

doi:10.3724/SP.J.1006.2022.13048

摘要/Abstract

摘要：

明晰不同物料还田对夏玉米穗位叶光合性能及氮代谢的影响, 为有效利用农业废弃物提供理论依据。2018—2019年在川中丘陵区石灰性紫色土上进行大田试验, 设置无物料还田(CK)、蚕豆秸秆还田(faba bean straw, FS)、油菜秸秆还田(rape straw, RS)、猪粪还田(pig manure, PM) 4个处理, 研究不同物料还田下夏玉米产量、叶片光合性能及氮代谢的特征。结果表明: (1) 不同有机物料还田第2年FS处理的玉米籽粒增产效果最佳, 比CK显著增加24.85%。 (2) 各物料还田处理的夏玉米叶面积指数、叶面积积累速率、群体光合势和光合色素含量, 随生育期推进均呈先增后降的趋势。与CK比, FS、PM处理提高叶面积指数、叶面积积累速率和群体光合势, 但RS处理有降低效果; 夏玉米六叶期光合色素含量在处理间差异不显著, 吐丝期叶绿素b、总叶绿素和类胡萝卜素含量均是RS处理比CK显著增加, 但吐丝后20 d时FS处理的叶绿素a、b、总叶绿素含量分别比RS处理显著增加34.67%、42.08%、36.24%。(3) 有机物料还田显著增加夏玉米穗位叶硝酸还原酶活性, 各还田处理的营养器官氮素积累与转运表现为FS、PM > RS。主成分分析结果表明, 不同物料还田下夏玉米光合性能、氮代谢能力表现为FS > PM > CK > RS。综上, 不同有机物料还田对玉米光合性能和氮代谢影响不同, 对比无物料还田和油菜秸秆还田, 蚕豆秸秆和猪粪还田更有利于提高叶片光合氮代谢能力, 促进营养器官中的光合代谢产物向籽粒运输, 从而为夏玉米籽粒产量的增加奠定基础。

关键词: 物料还田, 夏玉米, 光合性能, 氮代谢

Abstract:

The objective of this study is to clarify the effects of returning different materials on photosynthetic performance and nitrogen metabolism of summer maize, and to provide a theoretical basis for the effective use of agricultural wastes. Field experiments were conducted on calcareous purple soil in hilly areas of central Sichuan in 2018 and 2019. Four treatments were set up, including no material returning (CK), faba bean straw (faba bean straw, FS), rape straw (rape straw, RS), and pig manure (pig manure, PM) returned. The yield, photosynthetic performance, and nitrogen metabolism of summer maize by different materials returned were studied. The experimental results show that: (1) By different organic materials returned, the effect of FS in the second year on maize grain yield was the best, which was significantly increased by 24.85% compared with the CK. (2) The leaf area index, leaf area accumulation rate, leaf area duration, and photosynthetic pigment content of summer maize each material returned all increased first and then decreased with the growth period. Compared with CK, FS, and PM could improve leaf area index, leaf area accumulation rate, and leaf area duration of summer maize, but the effect of RS was decreasing. The photosynthetic pigment content of summer maize at 6-leaf stage was not significantly different among treatments. The chlorophyll b, total chlorophyll, and carotenoid content of RS at silking stage were the higher than CK. At 20 days after silking, the contents of chlorophyll a, b, and total chlorophyll of FS were significantly increased by 34.67%, 42.08%, and 36.24% compared with RS, respectively. (3) Organic material returned significantly increased the nitrate reductase activity of summer maize, and the nitrogen accumulation and transport in vegetative organs of each returning treatment were FS, PM > RS. The results of principal component analysis revealed that the photosynthetic performance and nitrogen metabolism capacity of summer maize by different materials returned to the field were FS > PM > CK > RS. In summary, the effects of different organic materials returned on photosynthetic performance and nitrogen metabolism of maize were different. Compared with no material and rape straw returned, faba bean straw and pig manure returned can improve the photosynthetic nitrogen metabolism ability of leaves, promote the transport of photosynthetic metabolites in vegetative organs to grains, and lay the foundation for the increase of grain yield of summer maize.

Key words: material returning, summer maize, photosynthetic performance, nitrogen metabolism

裴丽珍, 陈远学, 张雯雯, 肖华, 张森, 周元, 徐开未. 有机物料还田对夏玉米穗位叶光合性能及氮代谢的影响[J]. 作物学报, 2022, 48(8): 2115-2124.

PEI Li-Zhen, CHEN Yuan-Xue, ZHANG Wen-Wen, XIAO Hua, ZHANG Sen, ZHOU Yuan, XU Kai-Wei. Effects of organic material returned on photosynthetic performance and nitrogen metabolism of ear leaf in summer maize[J]. Acta Agronomica Sinica, 2022, 48(8): 2115-2124.

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土层 Soil layer (cm)	pH	有机质 Organic matter (g kg^-1)	全氮 Total nitrogen (g kg^-1)	碱解氮 Alkali-hydrolyzed nitrogen (mg kg^-1)	有效磷 Available phosphorus (mg kg^-1)	速效钾 Available potassium (mg kg^-1)
0-20	7.81	18.02	0.89	80.48	12.03	48.49
20-40	8.00	7.09	0.50	45.20	4.98	36.88

处理 Treatment	总氮 Total nitrogen (g kg^-1)	硝酸还原酶 Nitratase (nmol h^-1 g^-1)	谷氨酰胺合成酶 Glutamine synthetase (μmol h^-1 g^-1)
无物料还田CK	24.54±0.33 ab	112.14±8.47 b	7.84±0.68 a
蚕豆秸秆还田FS	26.03±0.62 ab	158.38±13.90 ab	8.50±1.60 a
油菜秸秆还田RS	23.16±1.68 b	165.36±15.11 a	8.65±0.34 a
猪粪还田PM	26.27±0.40 a	180.78±21.46 a	8.87±0.60 a

年份 Year	处理 Treatment	花前积累量Accumulation before silking (kg hm^-2)	花后积累量 Accumulation after silking (kg hm^-2)	转运量 Volume of transshipment (kg hm^-2)	转运率 Transport rate (%)	氮素转运量对籽粒的贡献率 Contribution rate of nitrogen transport amount to grain (%)
2018	无物料还田CK	46.89±3.23 bc	21.35±1.79 b	25.53±4.75 ab	53.54±8.54 a	66.93±4.62 a
	蚕豆秸秆还田FS	54.76±0.98 ab	23.58±1.45 ab	31.19±2.20 a	56.86±3.14 a	69.84±3.24 a
	油菜秸秆还田RS	42.97±6.39 c	23.82±2.87 ab	19.15±3.04 b	44.32±4.14 a	73.06±0.46 a
	猪粪还田PM	58.83±1.96 a	30.06±2.53 a	28.77±1.38 ab	49.04±3.08 a	49.64±7.19 b
2019	无物料还田CK	51.83±2.19 b	18.60±2.32 b	33.23±2.00 c	60.57±2.50 b	60.07±5.02 b
	蚕豆秸秆还田FS	63.51±2.05 a	18.44±0.85 b	45.07±1.20 a	70.99±0.40 a	60.91±6.36 b
	油菜秸秆还田RS	57.97±1.77 ab	20.20±1.27 b	37.77±2.55 bc	65.04±2.72 b	84.56±1.66 a
	猪粪还田PM	65.08±2.87 a	25.54±1.71 a	39.54±1.27 ab	60.83±0.99 b	47.45±4.62 b

主成分 Principal component	特征值Eigenvalue	贡献率 Contribution rate (%)	累积贡献率 Cumulative contribution rate (%)
PC1	6.344	70.485	70.485
PC2	1.348	14.980	85.465
PC3	0.664	7.378	92.843
PC4	0.374	4.156	96.999
PC5	0.179	1.991	98.990
PC6	0.058	0.643	99.633
PC7	0.014	0.160	99.792
PC8	0.011	0.117	99.909
PC9	0.008	0.091	100.000

指标 Index	主成分载荷矩阵Principal component loading matrix		主成分特征向量Principal component feature vector
指标 Index	PC1	PC2	PC1	PC2
LAI (X₁)	0.780	0.544	0.096	0.135
LAAR (X₂)	0.819	0.508	0.116	0.104
LAD (X₃)	0.887	0.205	0.212	-0.096
Chl a (X₄)	0.976	0.099	0.264	-0.183
Chl b (X₅)	0.976	0.144	0.253	-0.155
Carotin (X₆)	0.888	0.335	0.180	-0.018
NR (X₇)	0.024	0.951	-0.229	0.568
GS (X₈)	0.357	0.807	-0.095	0.398
TN (X₉)	0.523	0.487	0.034	0.164