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《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2024年20

Page:

30-36

Research Field:

Publishing date:

Info

Title:

Effects of Different Supplementary Light on Growth and Photosynthetic Characteristics of Strawberry in Greenhouse

Author(s):

YANG Mengyu; XU Linyun; SONG Yiqian; WANG Degang; TANG Yuwei; YANG Yifan

(Institute of Agricultural Science of Fourth Division of Xinjiang Production and Construction Corps，Kekedala，Xinjiang 835000)

Keywords:

greenhouse strawberry; supplementary light; photosynthesis characteristics; fruit quality

PACS:

S 668.4

DOI:

10.11937/bfyy.20241749

Abstract:

Taking the ‘Miaoxiang 7’ strawberry as the test material，a strawberry supplementary light experiment was conducted at the 69th greenhouse base.Four common supplementary light types were set up,red blue ratio 9∶1 waterproof LED supplementary light (T1)，full spectrum waterproof LED plant supplementary light (T2)，red blue light ratio 5∶1 waterproof LED supplementary light (T3)，and no supplementary light (CK).The effects of different types of supplementary light on the growth，development，and photosynthetic characteristics of greenhouse strawberries were explored.The membership function method was used to comprehensively evaluate indicators such as strawberry fruit quality and yield，and the optimal treatment was selected，in order to provide reference for high-quality production of greenhouse strawberries in Yili region.The results showed that different supplementary light treatments could increase the size and thickness of strawberry leaves，increase chlorophyll content，and improve the photosynthetic parameters of strawberry plants，which was beneficial for strawberry growth and development.It could also increase the single fruit weight，soluble sugar content，vitamin C content，and soluble solids content of the fruit，improve fruit quality，and increase yield.In summary，the red blue ratio of 9∶1 waterproof LED supplementary light was more beneficial for strawberry growth and development，improving fruit quality，and increasing yield as a greenhouse strawberry supplementary light source.

References:

［1］林琭,王红宁,肖建红.灌溉频率对基质栽培‘红颜’草莓叶片光合特性、产量及品质的影响［J］.中国果树,2020(5):81-86.［2］杨梦宇,张琦,袁振杨,等.生草对南疆温室桃园土壤理化性状的影响［J］.西北农业学报,2020,29(4):587-594.［3］时向东,蔡恒,焦枫,等.光质对作物生长发育影响研究进展［J］.中国农学通报,2008,24(6):226-230.［4］王昊,马文礼,陈永伟,等.不同补光位置下草莓光合特性、光能和电能利用效率研究［J］.中国农业科技导报,2020,22(7):29-36.［5］王任远,贾金金,张中华,等.不同LED复合光谱对草莓生长发育和品质的影响［J］.河北农业大学学报,2022,45(6):53-59.［6］杨肖芳,张豫超,苗立祥,等.LED补光对不同设施栽培草莓品种营养生长与果实品质的影响［J］.浙江农业科学,2023,64(4):864-869.［7］陈善飞,陈晖,陈善忠,等.大棚栽培草莓高压钠灯补光效果试验［J］.中国果树,2015(3):49-51,85.［8］陈晨,陈雪琼,陈月珍,等.叶面施氮对芹菜叶绿素含量及代谢有关基因表达的影响［J］.植物生理学报,2023,59(8):1533-1542.［9］潘师峰,徐志刚,许亚良,等.光质对蔬菜作物类胡萝卜素合成与调控研究进展［J］.中国蔬菜,2023(1):20-33.［10］许亚楠,闫家榕,孙鑫,等.红光和远红光在调控植物生长发育及应答非生物胁迫中的作用［J］.植物学报,2023,58(4):622-637.［11］钱舒婷,李建明.补光灯类型对设施草莓光合特性与产量的影响［J］.西北农林科技大学学报(自然科学版),2019,47(4):41-48.［12］张晶,谢淑琴,叶丙鑫,等.不同补光光质对日光温室草莓生长结果的影响［J］.中国果树,2019(1):54-57.［13］程芳芳,李红卫,余辉,等.不同补光方式对大棚草莓生产的影响［J］.农学学报,2021,11(1):80-84.［14］岳高峰,王丽萍,韩志强.不同补光时长对草莓开花及产量品质的影响［J］.江苏农业科学,2020,48(18):144-148.［15］王玉琪,梁颖,张泽锦,等.弱光区提高番茄产量和品质的栽培措施［J］.中国瓜菜,2023,36(5):59-65.［16］傅敏杰,朱志玉,朱月清,等.UV-B补光对大棚茄子果实农艺性状和抗病性的影响［J］.北方园艺,2022(1):65-71.［17］王竞,唐雪东,程存刚,等.不同光质补光对富士苹果果实品质的影响［J］.果树学报,2024（3）：459-469.［18］李莹,王水莲,赵霞,等.不同光质配比对油葵芽苗生长及芳香物质的影响［J］.华北农学报,2023,38(S1):161-169.［19］王丽娟,白义奎,王铁良.不同光质处理对草莓生理特性的影响［J］.河南农业大学学报,2017,51(1):25-28,52.［20］刘庆,连海峰,刘世琦,等.不同光质LED光源对草莓光合特性、产量及品质的影响［J］.应用生态学报,2015,26(6):1743-1750.

Memo

Memo:

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Common functions

Last Update: 2024-10-29