水氮互作对花针期花生叶片光合性能及荧光特性的影响

doi:10.11923/j.issn.2095-4050.cjas2022-0056

摘要/Abstract

摘要：

于铁岭市花生示范基地防雨棚中进行，设正常灌水（田间持水量75%左右）和花针期干旱处理（土壤含水量自然减少持续8 d，植株萎蔫后复水至正常水处理），副处理设0、90、180 kg/hm² 3个氮水平，研究花针期氮对干旱条件下花生叶片光合性能与荧光特性的影响，以期为花生花针期遇干旱时合理施用氮肥提供理论依据。结果表明，干旱胁迫显著降低了土壤相对含水量、净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)和胞间CO₂浓度(Ci)，提高了叶绿素含量。干旱处理下Pn、Tr、Gs、Ci、叶绿素含量均以90 kg/hm²施氮水平最高。干旱处理下初始荧光(F₀)显著升高，并随施氮量的增加而增大；最大光化学效率(Fv/Fm)、量子效率(ΦPSⅡ)、电子传递速率(ETR)和光化学猝灭系数(qP)都明显降低，但干旱胁迫使非光化学猝灭系数(NPQ)增大。干旱处理条件下Fv/Fm、ΦPSⅡ、ETR和qP均以90 kg/hm²施氮水平最高。不施(0 kg/hm²)或过量(180 kg/hm²)施氮肥均不利于花生叶片光合作用。因此，花针期干旱胁迫条件下以90 kg/hm²较适宜提高花生叶片的光合作用和荧光特性，最终获得高产。

关键词: 花针期, 花生, 干旱, 氮素, 光合作用, 荧光特性

Abstract:

The study was carried out in the Experimental Station of Tieling, a normal irrigation (soil water content was about 75%) and a short-term drought-stress (soil water content was naturally reduced by 8 days, and re-watered to normal after wilting) at flowering-pegging stage of peanut were set up, with three nitrogen levels (0, 90, 180 kg/hm²), to explore the effect of nitrogen application on photosynthesis and fluorescence characteristics of peanut under drought, thus providing reference for nitrogen application at peanut flowering-pegging stage. The results showed that soil water content, net photosynthetic rate (Pn), transpiration rate (Tr), stomatal conductance (Gs) and intercellular CO₂ concentration (Ci) were significantly reduced, but chlorophyll content of peanut was increased under drought-stress. Under drought-stress, Pn, Tr, Gs, Ci and chlorophyll content of 90 kg/hm² treatment were the best among the three levels of nitrogen application. Under drought-stress, the initial fluorescence of leaf (F₀) was significantly increased with the increase of nitrogen; the maximum photochemical efficiency of photosystemⅡ(Fv/Fm), the quantum efficiency of electron transport (ФPSⅡ), the electron transport rate (ETR) and the photochemical quenching co-efficient (qP) significantly declined, but the non-photochemical quenching co-efficient (NPQ) was significantly increased. Under drought-stress, Fv/Fm, ФPSⅡ, ETP and qP reached the highest level at 90 kg/hm² nitrogen application level. No application (0 kg/hm²) or excessive application (180 kg/hm²) of nitrogen fertilizer was not conducive to photosynthesis of peanut leaves. All results suggest that 90 kg/hm² is the optimal nitrogen level to improve photosynthesis and fluorescence characteristics of peanut, and achieve high yield.

Key words: flowering-pegging stage, peanut, drought, nitrogen, photosynthesis, fluorescent characteristics

修俊杰, 刘学良, 韩彦龙, 谢志强. 水氮互作对花针期花生叶片光合性能及荧光特性的影响[J]. 农学学报, 2023, 13(6): 25-31.

XIU Junjie, LIU Xueliang, HAN Yanlong, XIE Zhiqiang. Effect of Nitrogen Application on Photosynthesis and Fluorescent Characteristics of Peanut Under Drought-stress in Flowering-Pegging Stage[J]. Journal of Agriculture, 2023, 13(6): 25-31.

图/表 4

参考文献 28

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水分处理	氮素水平	1 d	2 d	3 d	4 d	5 d	6 d	7 d	8 d
干旱处理	N₀	75.95a	71.74d	66.62d	54.41d	48.24d	41.61d	37.43d	32.75d
	N₁	72.87e	64.98e	56.41e	45.13e	38.25e	34.82e	27.94e	25.19e
	N₂	72.12f	60.05f	48.85f	32.51f	25.03f	22.66f	20.57f	19.31f
正常灌水	N₀	75.04b	76.11a	73.55b	71.98c	69.63c	72.23c	77.55a	77.05b
	N₁	74.78c	75.18b	72.23c	73.01b	70.43b	75.13a	73.55c	78.13a
	N₂	74.01d	73.45c	75.05a	74.65a	72.32a	72.65b	75.63b	76.83c

水分处理	氮素水平	1 d	2 d	3 d	4 d	5 d	6 d	7 d	8 d
干旱处理	N₀	75.95a	71.74d	66.62d	54.41d	48.24d	41.61d	37.43d	32.75d
	N₁	72.87e	64.98e	56.41e	45.13e	38.25e	34.82e	27.94e	25.19e
	N₂	72.12f	60.05f	48.85f	32.51f	25.03f	22.66f	20.57f	19.31f
正常灌水	N₀	75.04b	76.11a	73.55b	71.98c	69.63c	72.23c	77.55a	77.05b
	N₁	74.78c	75.18b	72.23c	73.01b	70.43b	75.13a	73.55c	78.13a
	N₂	74.01d	73.45c	75.05a	74.65a	72.32a	72.65b	75.63b	76.83c

器官	氮素水平	干物质量/g		水分胁迫指数
器官	氮素水平	干旱处理	正常灌水	水分胁迫指数
根	N₀	5.54c	6.11c	0.09b
	N₉₀	6.22b	7.63b	0.18a
	N₁₈₀	7.26a	8.68a	0.16a
茎	N₀	7.68c	8.31c	0.08b
	N₉₀	10.28b	13.74b	0.25a
	N₁₈₀	11.19a	14.82a	0.24a
叶	N₀	8.45c	11.34c	0.25c
	N₉₀	9.88b	16.92b	0.42b
	N₁₈₀	10.83a	21.26a	0.49a
果	N₀	5.73c	6.71c	0.14c
	N₉₀	12.22a	14.72b	0.17b
	N₁₈₀	11.64b	15.27a	0.24a
整株	N₀	27.40c	32.46c	0.16c
	N₉₀	38.58b	54.01b	0.29b
	N₁₈₀	40.92a	60.53a	0.32a

器官	氮素水平	干物质量/g		水分胁迫指数
器官	氮素水平	干旱处理	正常灌水	水分胁迫指数
根	N₀	5.54c	6.11c	0.09b
	N₉₀	6.22b	7.63b	0.18a
	N₁₈₀	7.26a	8.68a	0.16a
茎	N₀	7.68c	8.31c	0.08b
	N₉₀	10.28b	13.74b	0.25a
	N₁₈₀	11.19a	14.82a	0.24a
叶	N₀	8.45c	11.34c	0.25c
	N₉₀	9.88b	16.92b	0.42b
	N₁₈₀	10.83a	21.26a	0.49a
果	N₀	5.73c	6.71c	0.14c
	N₉₀	12.22a	14.72b	0.17b
	N₁₈₀	11.64b	15.27a	0.24a
整株	N₀	27.40c	32.46c	0.16c
	N₉₀	38.58b	54.01b	0.29b
	N₁₈₀	40.92a	60.53a	0.32a