Effects of Growing Grass on Microclimate Environment and Apple Leaves in Apple Orchard

doi:10.13304/j.nykjdb.2023.0067

Abstract

Abstract:

In order to explore the effects of grass on the microclimate environment and apple leaves in the orchard of Pishan farm， two treatments of clean tillage and natural grass were set， the upper， middle and lower canopy microclimate environment indexes of apples under the two treatments were evaluated by using grey relational analysis method. The results showed that compared with clean tillage treatment， under natural grass treatment the average daily air temperature in the middle canopy of apple tree canopy was decreased by 0.2 ℃， the average daily relative humidity of air was increased by 1 percentage point， the average daily light intensity was decreased by 2 132 lx， and the average daily wind speed in the lower canopy was decreased by 0.05 m·s^-1. The average daily soil temperature at 5， 10， 15， 20 and 25 cm underground under natural grass treatment decreased by 0.7， 0.6， 0.5， 0.3 and 0.2 ℃， respectively， compared with that under clean tillage treatment. Grey correlation analysis showed that natural grass treatment had better regulating effect on the microclimate environment of the upper， middle and lower canopy than that of clean tillage treatment， and the lower the canopy， the more obvious the regulating effect was. The leaf length， leaf width， leaf area， leaf thickness， fresh leaf weight， specific leaf weight and chlorophyll content of apple leaves under natural grass treatment were significantly increased compared with that under clean tillage treatment， and the average daily leaf temperature was decreased by 0.68 ℃. Path analysis showed that the leaf temperature of apple under clean tillage treatment was more affected by microclimate factors than that under natural grass treatment. The results could provide scientific reference for the further popularization of grass growing technology in orchards in arid and desert areas in China.

Key words: arid desert area, apple, natural grass, microclimate environment, leaf

摘要：

为探究生草对干旱荒漠区果园小气候环境及苹果叶片的影响，对皮山农场苹果园生草设置清耕与自然生草2个处理，运用灰色关联度分析法对2个处理下苹果园上、中、下冠层小气候环境指标进行综合评价。结果表明，与清耕处理相比，自然生草处理下苹果树冠中层日平均气温降低0.2 ℃，日平均空气相对湿度增加1个百分点，日平均光照强度降低2 132 lx，苹果树冠下层日平均风速降低0.05 m·s^-1。自然生草处理地下5、10、15、20、25 cm处土壤日平均温度分别比清耕处理降低0.7、0.6、0.5、0.3、0.2 ℃。灰色关联度分析表明，自然生草处理对苹果园上、中、下冠层小气候环境的调节作用均优于清耕处理，冠层越低调节作用越明显。自然生草处理苹果叶片的叶长、叶宽、叶面积、叶厚、叶鲜重、比叶重及叶绿素含量较清耕处理明显增加，日平均叶温降低0.68 ℃。通径分析发现，清耕处理苹果叶温比自然生草处理更易受果园小气候因子的影响。研究结果可为我国干旱荒漠区果园生草技术的进一步推广提供科学参考。

关键词: 干旱荒漠区, 苹果, 自然生草, 小气候环境, 叶片

CLC Number:

S661.1

Jun CHEN, Qi ZHANG, Mengyu YANG, Zhenyang YUAN. Effects of Growing Grass on Microclimate Environment and Apple Leaves in Apple Orchard[J]. Journal of Agricultural Science and Technology, 2023, 25(12): 158-167.

陈俊, 张琦, 杨梦宇, 袁振杨. 生草对苹果园小气候环境及苹果叶片的影响[J]. 中国农业科技导报, 2023, 25(12): 158-167.

Figures/Tables 7

References 26

1	王艳廷, 冀晓昊, 吴玉森, 等.我国果园生草的研究进展[J].应用生态学报, 2015, 26(6): 1892-1900.
	WANG Y T, JI X H, WU Y S, et al.. Research progress of cover crop in Chinese orchard [J]. Chin. J. Appl. Ecol., 2015, 26(6): 1892-1900.
2	寇建村, 杨文权, 韩明玉.我国果园生草研究进展[J].草业科学, 2010, 27(7): 154-159.
	KOU J C, YANG W Q, HAN M Y. Research progress on interplanting grass in orchard in China [J]. Pratac. Sci., 2010, 27(7): 154-159.
3	焦润安, 焦健, 李朝周.生草对油橄榄园土壤性质和油橄榄成花生理的影响[J].草业学报, 2018, 27(7): 133-144.
	JIAO R A, JIAO J, LI C Z. The effect of sod-culture on orchard soil properties and the floral physiology of olives [J]. Acta Pratac. Sin., 2018, 27(7): 133-144.
4	梅立新, 李会科.渭北旱地苹果园生草小气候效应研究[J].干旱区农业研究, 2010, 28(1): 187-192.
	MEI L X, LI H K. Effects of interplanting different herbage on microclimate in apple orchards in the area of Weibei plateau [J]. Agric. Res. Arid Areas, 2010, 28(1): 187-192.
5	焦润安, 张舒涵, 李毅, 等.生草影响果树生长发育及果园环境的研究进展[J].果树学报, 2017, 34(12): 1610-1623.
	JIAO R A, ZHANG S H, LI Y, et al.. Research progress about the effect of sod-culture on the growth and de-velopment of fruit and orchard environment [J]. J. Fruit Sci., 2017, 34(12): 1610-1623.
6	白岗栓, 邹超煜, 杜社妮.渭北旱塬果园自然生草对土壤水分及苹果树生长的影响[J].农业工程学报, 2018, 34(3): 151-158.
	BAI G S, ZOU C Y, DU S N. Effects of self-sown grass on soil moisture and tree growth in apple orchard on Weibei dry plateau [J]. Trans. Chin. Soc. Agric. Eng., 2018, 34(3): 151-158.
7	吴玉森, 张艳敏, 冀晓昊, 等.自然生草对黄河三角洲梨园土壤养分、酶活性及果实品质的影响[J].中国农业科学, 2013, 46(1): 99-108.
	WU Y S, ZHANG Y M, JI X H, et al.. Effects of natural grass on soil nutrient, enzyme activity and fruit quality of pear orchard in Yellow River Delta [J]. Sci. Agric. Sin., 2013, 46(1): 99-108.
8	李会科, 张广军, 赵政阳, 等.生草对黄土高原旱地苹果园土壤性状的影响[J].草业学报, 2007, 16(2): 32-39.
	LI H K, ZHANG G J, ZHAO Z Y, et al.. Effects of interplanted herbage on soil properties of non-irrigated apple orchards in the Loess Plateau [J]. Acta Pratac. Sin., 2007, 16(2): 32-39.
9	惠竹梅, 李华, 龙妍, 等.葡萄园行间生草体系中土壤微生物数量的变化及其与土壤养分的关系[J].园艺学报, 2010, 37(9): 1395-1402.
	HUI Z M, LI H, LONG Y, et al.. Variation of soil microbial populations and relationships between microbial factors and soil nutrients in cover cropping system of vineyard [J]. Acta Hortic. Sin., 2010, 37(9): 1395-1402.
10	王中堂, 沙建川, 解小锋, 等.枣园生草处理对土壤养分和细菌群落的影响[J].核农学报, 2022, 36(2): 456-465.
	WANG Z T, SHA J C, XIE X F, et al.. Effects of different grasses cultivation on soil nutrient and bacterial community in Chinese jujube orchard [J]. Acta Agric. Nucl. Sin., 2022, 36(2): 456-465.
11	李芳东, 吕德国, 秦嗣军, 等.生草覆盖苹果园不同衰老时期叶片光合生理特性的比较[J].经济林研究, 2014, 32(1): 65-69, 75.
	LI F D, LYU D G, QIN S J, et al.. Comparison of photosynthetic physiological characteristics of different aging-degree leaves of apple orchard under grass coverage management [J]. Nonw. For. Res., 2014, 32(1): 65-69, 75.
12	陈久红, 马建江, 李永丰, 等.行间生草对‘库尔勒香梨’果园小气候、光合特性及果实品质的影响[J].北方园艺, 2019(22): 49-59.
	CHEN J H, MA J J, LI Y F, et al.. Effects of herbage on ecological environment and photosynthetic characteristics fruits quality of ‘Korla Fragrant Pear’ [J]. Northern Hortic., 2019(22): 49-59.
13	李会科, 梅立新, 高华. 黄土高原旱地苹果园生草对果园小气候的影响[J].草地学报, 2009, 17(5): 615-620.
	LI H K, MEI L X, GAO H. Effect of grass planting on the microclimate of apple orchard in the dryland area of Loess Plateau [J]. Acta Agrestia Sin., 2009, 17(5): 615-620.
14	白岗栓, 郭江平, 杜建会.自然生草对渭北旱塬苹果园小气候及果实灼伤和早期落叶病的影响[J].草地学报, 2021, 29(2): 324-332.
	BAI G S, GUO J P, DU J H. Effects of natural grass on microclimate of apple orchard, fruit sunburn and leaf early deciduous diesease in Weibei dry plateau [J]. Acta Agrestia Sin., 2021, 29(2): 324-332.
15	郭晓睿, 宋涛, 邓丽娟, 等.果园生草对中国果园土壤肥力和生产力影响的整合分析[J].应用生态学报, 2021, 32(11): 4021-4028.
	GUO X R, SONG T, DENG L J, et al.. Effects of grass growing on soil fertility and productivity of orchards in China: a metaanalysis [J]. Chin. J. Appl. Ecol., 2021, 32(11): 4021-4028.
16	杨梦宇, 张琦, 袁振杨, 等. 温室生草对南疆桃叶片、果实质量的影响[J].中国农业科技导报, 2021, 23(3): 178-185.
	YANG M Y, ZHANG Q, YUAN Z Y, et al.. Effects of intercropping grass on peach leaf and fruit quality in greenhouse of Southern Xinjiang [J]. J. Agric. Sci. Technol., 2021, 23(3): 178-185.
17	董亚芳, 尚忠海, 钟显, 等.文冠果光合日变化及其与环境因子相关性的初步研究[J].河南农业科学, 2010(6): 58-61, 70.
	DONG Y F, SHANG Z H, ZHONG X, et al.. Elementary study on diurnal viration of photosynthesis and its correlation to environmental factors in xanthoceras sorbifolia bunge [J]. J. Henan Agric. Sci., 2010(6): 58-61, 70.
18	李文杨, 岳建华, 孟岩, 等.葡萄叶片SPAD值与测定位置及光合色素含量的关系[J].经济林研究, 2019, 37(2): 67-72, 81.
	LI W Y, YUE J H, MENG Y, et al.. Correlation between SPAD value and photosynthetic pigment content in Vitis vinifera leaves [J]. Nonw. For. Res., 2019, 37(2): 67-72, 81.
19	杨玮, 孙红, 郑立华, 等.基于土壤参数的冬小麦产量预测模型[J].农业工程学报, 2013, 29(23): 118-123.
	YANG W, SUN H, ZHENG L H, et al.. Prediction model of winter wheat yield based on soil parameters [J]. Trans. Chin. Soc. Agric. Eng., 2013, 29(23): 118-123.
20	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.
	YANG M Y, ZHANG Q, YUAN Z Y, et al.. Effect of growing grass on soil physicochemical properties of greenhouse in Southern Xinjiang [J]. Acta Agric. Bor-Occid. Sin., 2020, 29(4): 587-594.
21	宋同清, 肖润林, 彭晚霞, 等.覆盖与间作对亚热带丘陵幼龄茶园土壤环境和生产的影响[J].农业工程学报, 2006, 22(7): 60-64.
	SONG T Q, XIAO R L, PENG W X, et al.. Effects of straw mulching and white clover intercropping on soil environment and the production of tea in young tea plantation in subtropical hilly region [J]. Trans. Chin. Soc. Agric. Eng., 2006, 22(7): 60-64.
22	张义, 谢永生, 郝明德, 等.不同地表覆盖方式对苹果园土壤性状及果树生长和产量的影响[J].应用生态学报, 2010, 21(2): 279-286.
	ZHANG Y, XIE Y S, HAO M D, et al.. Effects of different patterns surface mulching on soil properties and fruit trees growth and yield in an apple orchard [J]. Chin. J. Appl. Ecol., 2010, 21(2): 279-286.
23	王锐, 闫鹏科, 马婷慧, 等.行内生草对土壤微环境和酿酒葡萄品质的影响[J].干旱区农业研究, 2020, 38(3): 195-203.
	WANG R, YAN P K, MA T H, et al.. Effects of intra-row planted grass on soil microenvironment and wine grape quality [J]. Agric. Res. Arid Areas, 2020, 38(3): 195-203.
24	WU J Y, CHEN M G, DONG C Y, et al.. Effects of land cover on soil temperature,humidity and moisture in phoebe bournei forest [J]. Agric. Sci. Technol., 2015, 16(12): 2725-2729.
25	马正岩.旱地苹果园人工干预自然生草技术与采前不同时期施钾的效果研究[D].杨凌: 西北农林科技大学, 2022.
	MA Z Y. Artificial intervention of natural grass growing technology in dryland apple orchard and effect of potassium application in different periods before mining [D]. Yangling: Northwest A & F University, 2022.
26	赵建贵, 高安琪, 韦玉翡, 等.温室环境因子对番茄叶温的影响[J].山西农业科学, 2020, 48(8): 1271-1274.
	ZHAO J G, GAO A Q, WEI Y F, et al.. Effect of greenhouse environmental factors on leaf temperature of tomato [J]. J. Shanxi Agric. Sci., 2020, 48(8): 1271-1274.

冠层 Canopy	处理 Treatment	气温 Air temperature	空气相对湿度Relative humidity of air	光照强度 Light intensity	风速 Wind speed	加权关联度Weighted relevance	加权关联序Weighted correlation order
上层Super stratum	清耕Clean tillage	0.086 4	0.073 9	0.095 7	0.123 7	0.094 9	6
上层Super stratum	自然生草Natural grass	0.129 4	0.085 1	0.103 4	0.131 0	0.112 2	5
中层Middle layer	清耕Clean tillage	0.106 6	0.083 1	0.176 5	0.139 1	0.126 3	3
中层Middle layer	自然生草Natural grass	0.181 9	0.103 8	0.157 4	0.211 7	0.163 7	2
下层Sub stratum	清耕Clean tillage	0.127 4	0.099 3	0.106 7	0.159 0	0.123 1	4
下层Sub stratum	自然生草Natural grass	0.255 2	0.221 7	0.101 9	0.317 0	0.223 9	1
权重Weight		0.256 6	0.221 8	0.180 4	0.341 2	—	—

冠层 Canopy	处理 Treatment	气温 Air temperature	空气相对湿度Relative humidity of air	光照强度 Light intensity	风速 Wind speed	加权关联度Weighted relevance	加权关联序Weighted correlation order
上层Super stratum	清耕Clean tillage	0.086 4	0.073 9	0.095 7	0.123 7	0.094 9	6
上层Super stratum	自然生草Natural grass	0.129 4	0.085 1	0.103 4	0.131 0	0.112 2	5
中层Middle layer	清耕Clean tillage	0.106 6	0.083 1	0.176 5	0.139 1	0.126 3	3
中层Middle layer	自然生草Natural grass	0.181 9	0.103 8	0.157 4	0.211 7	0.163 7	2
下层Sub stratum	清耕Clean tillage	0.127 4	0.099 3	0.106 7	0.159 0	0.123 1	4
下层Sub stratum	自然生草Natural grass	0.255 2	0.221 7	0.101 9	0.317 0	0.223 9	1
权重Weight		0.256 6	0.221 8	0.180 4	0.341 2	—	—

处理 Treatment	变量Variable	直接作用 Direct action	间接作用Indirect action					决策系数Decision coefficient
处理 Treatment	变量Variable	直接作用 Direct action	气温 Air temperature	空气相对湿度Relative humidity of air	光照强度Light intensity	土壤温度 Soil temperature	合计Total	决策系数Decision coefficient
清耕 Clean tillage	气温 Air temperature	-0.539	—	0.324	1.219	-0.047	1.496	-1.322
	空气相对湿度 Relative humidity of air	-0.418	0.417	—	-0.889	0.047	-0.425	0.531
	光照强度 Light intensity	1.247	-0.527	0.298	—	-0.046	-0.275	0.869
	土壤温度 Soil temperature	-0.051	-0.499	0.386	1.133	—	1.020	-0.101
自然生草 Natural grass	气温 Air temperature	-0.890	—	0.211	1.745	-0.126	1.829	-2.463
	空气相对湿度 Relative humidity of air	-0.286	0.657	—	-1.272	0.145	-0.471	0.351
	光照强度 Light intensity	1.780	-0.872	0.204	—	-0.128	-0.795	0.337
	土壤温度 Soil temperature	-0.150	-0.748	0.276	1.511	—	1.038	-0.290

处理 Treatment	变量Variable	直接作用 Direct action	间接作用Indirect action					决策系数Decision coefficient
处理 Treatment	变量Variable	直接作用 Direct action	气温 Air temperature	空气相对湿度Relative humidity of air	光照强度Light intensity	土壤温度 Soil temperature	合计Total	决策系数Decision coefficient
清耕 Clean tillage	气温 Air temperature	-0.539	—	0.324	1.219	-0.047	1.496	-1.322
	空气相对湿度 Relative humidity of air	-0.418	0.417	—	-0.889	0.047	-0.425	0.531
	光照强度 Light intensity	1.247	-0.527	0.298	—	-0.046	-0.275	0.869
	土壤温度 Soil temperature	-0.051	-0.499	0.386	1.133	—	1.020	-0.101
自然生草 Natural grass	气温 Air temperature	-0.890	—	0.211	1.745	-0.126	1.829	-2.463
	空气相对湿度 Relative humidity of air	-0.286	0.657	—	-1.272	0.145	-0.471	0.351
	光照强度 Light intensity	1.780	-0.872	0.204	—	-0.128	-0.795	0.337
	土壤温度 Soil temperature	-0.150	-0.748	0.276	1.511	—	1.038	-0.290

[1]	Lili SHAN. Effects of Low Temperature During Booting Stage on Rice Physiology and Alleviating Effect of Exogenous Melatonin [J]. Journal of Agricultural Science and Technology, 2023, 25(9): 23-33.
[2]	Yitong XIAO, Shuai LIU, Chenlian HOU, Qi LIU, Fuzhong LI, Wuping ZHANG. Organ Segmentation and Phenotypic Analysis of Soybean Plants Based on Three-dimensional Point Clouds [J]. Journal of Agricultural Science and Technology, 2023, 25(8): 115-125.
[3]	Yingxue ZHU, Qi WANG, Xianfa MA, Yusheng JIAO, Jinxu GAO, Weijia MAO, Jia FU, Xuedong SUN, Ye YUAN. Leaf Color Characteristic Value and Nitrogen Diagnosis Model of Tobacco During Growth Period [J]. Journal of Agricultural Science and Technology, 2023, 25(7): 54-62.
[4]	Lu MENG, Jingwen FAN, Xinyu SAI, Lusheng ZENG, Xiangyun SONG, Dejie CUI. Effects of Lime on Soil Improvement and Plant Growth in Apple Orchards [J]. Journal of Agricultural Science and Technology, 2023, 25(4): 197-204.
[5]	Mingjie SHAO, Yanqi CHEN, Wenke LIU. Effects of Red-blue LED Bight Supply Modes on Growth and Quality of Purple Leaf Lettuce Under Continuous Light [J]. Journal of Agricultural Science and Technology, 2023, 25(4): 77-85.
[6]	Tongtong ZHENG, Wendi YANG, Ning WANG, Junjie MA, Long LIU, Qingyuan GUO. Morphological and Polygenetic Identification of Pathogen of Wheat Leaf Blight [J]. Journal of Agricultural Science and Technology, 2023, 25(2): 111-118.
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[11]	Shimin LI, Qiong DONG, Youfan JIN, Shuping LI, Meng LI, Tingbiao LIU, Xingjie ZHAO, Jing CHEN, Ping YE, Meng LYU. Response and Evaluation of Leaf Traits and Physiological Parameters of Cyphoma betacea Seedlings Under Shading Environment [J]. Journal of Agricultural Science and Technology, 2023, 25(1): 72-82.
[12]	Fengguang HE, Ganran DENG, Zhende CUI, Shuang ZHENG, Guojie LI, Ling LI, Shuangmei QIN. Operating Performance of Self-propelled Silage Cassava Stem and Leaf Harvester [J]. Journal of Agricultural Science and Technology, 2022, 24(8): 109-115.
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[14]	Qi LIU, Bin CHEN, Songlin SUN, Mingtao XIAO, Chaoran SUN. Research on Mechanical Characteristics of Clamping Conveyor for Leafy Vegetables [J]. Journal of Agricultural Science and Technology, 2022, 24(4): 116-125.
[15]	Dingyang ZHANG, Saifei QIU, Wenhua RAO, Xueping GUO, Fang CAO, Tianyun ZHAI, Xiong GUAN, Xiaohong PAN. Inhibitory Effect of Nano-Mg（OH）₂ with Different Morphology on Pathogen Mango Phoma Leaf Spot [J]. Journal of Agricultural Science and Technology, 2022, 24(3): 140-147.