水分和光照条件对核桃-黄豆农林复合系统中黄豆光合作用和生长的影响

doi:10.11707/j.1001-7488.20200421

摘要/Abstract

摘要：

目的: 研究核桃-黄豆农林复合系统中不同种植位置间作作物在不同水分、光照条件下的水分利用和碳代谢，为更好了解种间相互作用对植物生长的影响提供参考。方法: 2017年，在太行山南麓低山丘陵区核桃-黄豆农林复合系统中，测定不同种植位置黄豆在旱季(7月中旬)和雨季(8月下旬)的土壤含水量、凌晨和正午水势、正午茎秆导水损失率(PLC)、株高和基径、生物量以及根、茎、叶的非结构性碳(NSC)含量。结果: 1)在旱季，随着与核桃树距离的增加，土壤含水量降低，黄豆凌晨和正午水势下降，正午茎秆PLC上升，距核桃树1.5和2.5 m的黄豆光合速率和气孔导度较大，距核桃树0.6 m和单作的黄豆光合速率偏低，但总体上间作和单作的黄豆气体交换没有显著差异。旱季生物量、根冠比和NSC随着与核桃树距离增加而增大。2)在雨季，除距核桃树0.6 m处土壤含水量偏低外，其余位置均无显著性差异，土壤含水量比旱季高60%以上。不同种植位置黄豆凌晨水势没有显著性差异，但单作黄豆正午水势更低，茎秆PLC较间作黄豆严重。光合速率、气孔导度、生物量、NSC含量、根冠比均随着与核桃树距离增加而增大。根、茎、叶NSC含量均显著高于旱季，主要由淀粉储藏增加引起。结论: 在旱季，不同种植位置黄豆水分状况均受一定程度的干旱影响，复合系统中间作黄豆水分状况好于单作，但旱季水分胁迫没有显著影响光合作用和生长；遮荫的影响覆盖了水分状况改善的作用。在雨季，复合系统中黄豆主要受遮荫影响，距离树木越远生长情况越好。在研究年份水分不是主要限制因子的情况下，间作互利作用未体现，而复合系统中的光能竞争会导致间作黄豆生长量明显下降。

关键词: 核桃-黄豆复合系统, 种植位置, 水分状况, 光合作用, 生长, 非结构性碳

Abstract:

Objective: Agroforestry system has been widely used,because it can improve the utilization rate of natural resources. Regulation of inter-specific relationships in agroforestry system is an important way to ensure high yield and efficiency of this system,and water and light are the core contents of the regulation. In this study,the water use and carbon metabolism of intercropping crops in an agroforestry system under different water conditions were investigated,in order to better understand the effects of interspecific interactions on plant growth. Method: In 2017, soybeans were sownat different locations from walnut trees in the walnut-soybean agroforestry system in the southern foothills of Taihang Mountains.The soil moisture content,predawn and mid-day water potential,mid-day stem percentage loss of conductivity (PLC),plant height and basal diameter,biomass,and nonstructural carbohydrate (NSC) content of root,stem and leaf of soybean plants were measured in dry (mid-July)and rainy season(late August). Result: 1) In dry season,with the increase of distance from walnut tree,the surface soil moisture content decreased,the predawn and mid-day water potential of soybean plants decreased,and the mid-day stem PLC increased. The photosynthetic rate and stomatal conductance of soybean plants at 1.5 m and 2.5 m away from walnut tree were higher,while the photosynthetic rate of soybean plants at 0.6 m away from walnut tree and mono-cropped soybean plants was lower.However,there in general was no significant difference in gas exchange between intercropped and mono-cropped soybean. Biomass,root-shoot ratio and NSC increased with the increase of distance from walnut trees. 2) In rainy season,except for at 0.6 m away from walnut tree where the soil moisture content was low,there was no significant difference in the soil moisture content over other locations. The soil moisture content in the rainy season was more than 60% higher than that in the dry season. In rainy season,there was no significant difference in the predawn water potential of soybean plants at different locations,but the midday water potential in monoculture was lower,and the PLC was more severe than thosein intercropped soybean. Photosynthetic rate,stomatal conductance,biomass,NSC content and root-shoot ratio all increased with the increase of the distance from walnut tree. The NSC content of root,stem and leaf in the rainy season was significantly higher than that in the dry season,which was mainly caused by the increase of starch storage. Conclusion: In the dry season,the water situation of soybean atdifferent locations is affected by drought,and the water situation of soybean in the agroforestry system is better than that of mono-culture.However,the degree of water imbalance in the dry season doesnot significantly affect photosynthesis and growth,because the effects of shading overshadow the effects of water status. In the rainy season,soybeans in the agroforestry system are mainly affected by shading,so the farther away from the trees,the better the growth. Under the condition that water is not the limiting factorin the study year,the mutual benefit of intercropping could not be shown.In contrast,light energy competition in the agroforestry system would lead to obvious decrease of soybean growth.

Key words: walnut-soybean agrforestry system, planting location, water status, photosynthesis, growth, nonstructural carbohydrate (NSC)

中图分类号:

S718.43

王林,代永欣,张劲松,孟平,孙胜,李豪,万贤崇. 水分和光照条件对核桃-黄豆农林复合系统中黄豆光合作用和生长的影响[J]. 林业科学, 2020, 56(4): 188-196.

Lin Wang,Yongxin Dai,Jinsong Zhang,Ping Meng,Sheng Sun,Hao Li,Xianchong Wan. Effects of Water and Light Conditions on Photosynthesis and Growth of Soybean in Walnut-Soybean Agroforestry System[J]. Scientia Silvae Sinicae, 2020, 56(4): 188-196.

图/表 8

图1

图2

表1

图3

图4

表2

图5

图6

参考文献 0

	何春霞, 郑宁, 张劲松, 等. 农林复合系统水热生态特征研究进展. 中国农业气象, 2016a. 37 (6): 633- 644.
	He C X , Zheng N , Zhang J S , et al. Research advances on hydrological and thermal characteristics of agroforestry system. Chinese Journal of Agrometeorology, 2016a. 37 (6): 633- 644.
	何春霞, 陈平, 孟平, 等. 华北低丘山区果药复合系统种间水分利用策略. 植物生态学报, 2016b. 40 (2): 151- 164.
	He C X , Chen P , Meng P , et al. Interspecific water use strategies of a Juglans regia and Isatis tinctoria/Senna tora agroforestry system in a hilly area of Northern China. Chinese Journal of Plant Ecology, 2016b. 40 (2): 151- 164.
	毛瑢, 曾德慧. 农林复合系统植物竞争研究进展. 中国生态农业学报, 2009. 17 (2): 379- 386.
	Mao R , Zeng D H . Research advances in plant competition in agroforestry systems. Chinese Journal of Eco-Agriculture, 2009. 17 (2): 379- 386.
	孟平, 张劲松. 中国复合农林业发展机遇与研究展望. 防护林科技, 2011. (1): 7- 10. doi: 10.3969/j.issn.1005-5215.2011.01.005
	Meng P , Zhang J S . Development opportunities & prospects of agroforestry in China. Protection Forest Science and Technology, 2011. (1): 7- 10. doi: 10.3969/j.issn.1005-5215.2011.01.005
	彭晓邦, 张硕新. 商洛低山丘陵区农林复合生态系统光能竞争与生产力. 生态学报, 2012. 32 (9): 2692- 2698.
	Peng X B , Zhang S X . Competition for light and crop productivity in an agro-forestry system in the Hilly Region, Shangluo, China. Acta Ecologica Sinica, 2012. 32 (9): 2692- 2698.
	孙守家, 孟平, 张劲松, 等. 华北石质山区核桃-绿豆复合系统氘同位素变化及其水分利用研究. 生态学报, 2010. 30 (14): 3717- 3726.
	Sun S J , Meng P , Zhang J S , et al. Deuterium isotope variation and water use in an agroforestry system in therocky mountainous area of North China. Acta Ecologica Sinica, 2010. 30 (14): 3717- 3726.
	王晶晶, 毕华兴, 孙于卜, 等. 果树树冠遮阴模型的改进. 南京林业大学学报:自然科学版, 2018. 42 (5): 135- 140.
	Wang J J , Bi H X , Sun Y B , et al. Improved model of canopy shading for fruit tree. Journal of Nanjing Forestry University:Natural Sciences Edition, 2018. 42 (5): 135- 140.
	王晶英, 郑桂萍, 张红燕, 等. 连作大豆根冠比增大原因的研究. 大豆科学, 1997. 16 (2): 45- 51.
	Wang J Y , Zheng G P , Zhang H Y , et al. Study on the reason of root-shoot ratio increasing of soybean on continuous cropping. Soybean Science, 1997. 16 (2): 45- 51.
	王林, 代永欣, 樊兴路, 等. 风对黄花蒿水力学性状和生长的影响. 生态学报, 2015. 35 (13): 4454- 4461.
	Wang L , Dai Y X , Fan X L , et al. Effects of wind on hydraulic properties and growth of Artemisia annua Linn. Acta Ecologica Sinica, 2015. 35 (13): 4454- 4461.
	王林, 代永欣, 郭晋平, 等. 刺槐苗木干旱胁迫过程中水力学失败和碳饥饿的交互作用. 林业科学, 2016. 52 (6): 1- 9.
	Wang L , Dai Y X , GuoJ P , et al. Interaction of hydraulicfailure and carbon starvationon Robinia pseudoacacia seedings during drought. Scientia Silvae Sinicae, 2016. 52 (6): 1- 9.
	王忠林, 李会科, 贺秀贤. 渭北旱塬花椒地埂林土壤抗蚀抗冲性研究. 水土保持研究, 2000. 7 (1): 33- 37. doi: 10.3969/j.issn.1005-3409.2000.01.009
	Wang Z L , Li H K , He X X . Study on soil anti-erosion and anti-scour of prickly ash at edges of terraces in drought upland of Weibei. Research of Soil and Water Conservation, 2000. 7 (1): 33- 37. doi: 10.3969/j.issn.1005-3409.2000.01.009
	赵英, 张斌, 王明珠. 农林复合系统中物种间水肥光竞争机理分析与评价. 生态学报, 2006. 26 (6): 1792- 1801. doi: 10.3321/j.issn:1000-0933.2006.06.021
	Zhao Y , Zhang B , Wang M Z . Assessment of competition for water, fertilizer and light between components in thealley cropping system. Acta Ecologica Sinica, 2006. 26 (6): 1792- 1801. doi: 10.3321/j.issn:1000-0933.2006.06.021
	Dietze M C , Sala A , Carbone M S , et al. Nonstructural carbon in woody plants. Annual Review of Plant Biology, 2014. 65 (1): 667- 687. doi: 10.1146/annurev-arplant-050213-040054
	Dixon R K , Winjum J K , Andrasko K J , et al. Integrated land-use systems:Assessment of promising agroforest and alternative land-use practices to enhance carbon conservation and sequestration. Climatic Change, 1994. 27 (1): 71- 92. doi: 10.1007/BF01098474
	Galvez D A , Landhäusser S M , Tyree M T . Low root reserve accumulation during drought may lead to winter mortality in poplar seedlings. New Phytologist, 2013. 198 (1): 139- 148. doi: 10.1111/nph.12129
	Hsiao T C , Xu L K . Sensitivity of growth of roots versus leaves to water stress:biophysical analysis and relation to water transport. Journal of Experimental Botany, 2000. 51 (350): 1595- 1616. doi: 10.1093/jexbot/51.350.1595
	Klein T , Cohen S , Dan Y , et al. Hydraulic adjustments underlying drought resistance of Pinus halepensis. Tree Physiology, 2011. 31, 637- 648. doi: 10.1093/treephys/tpr047
	Landhäusser S M , Lieffers V J . Defoliation increases risk of carbon starvation in root systems of mature aspen. Trees, 2012. 26 (2): 653- 661. doi: 10.1007/s00468-011-0633-z
	McDowell N G , Pockman W T , Allen C D , et al. Mechanisms of plant survival and mortality during drought:why do some plants survive while others succumb to drought?, 178(4):719-739. New Phytologist, 2008. 178 (4): 719- 739. doi: 10.1111/j.1469-8137.2008.02436.x
	Meier I C , Knutzen F , Eder L M , et al. The deep root system of Fagus sylvatica on sandy soil:structure and variation across a precipitation gradient. Ecosystems, 2017. 21 (2): 1- 17.
	Mitchell P J , O'Grady A P , Tissue D T , et al. Drought response strategies define the relative contributions of hydraulic dysfunction and carbohydrate depletion during tree mortality. New Phytologist, 2013. 197 (3): 862- 872. doi: 10.1111/nph.12064
	O'Brien M J , Leuzinger S , Philipson C D , et al. Drought survival of tropical tree seedlings enhanced by non-structural carbohydrate levels. Nature Climate Change, 2014. 4 (8): 710- 714. doi: 10.1038/nclimate2281
	O'Keefe K , Nippert J B . An assessment of diurnal water uptake in a mesic prairie:evidence for hydraulic lift?. Oecologia, 2017. 183 (4): 963- 975. doi: 10.1007/s00442-017-3827-2
	Oliva J , Stenlid J , Martınez-Vilalta J . The effect of fungal pathogens on the water and carbon economy of trees:implications for drought-induced mortality. New Phytologist, 2014. 203, 1028- 1035. doi: 10.1111/nph.12857
	Rezig M , Sahli A , Harbaoui Y . Potato (Solanum tuberosum L.) and Sulla (Hedysarum coronarium L.) Intercropping in Tunisia:effects in water consumption and water use efficiency. Journal of Agricultural Science, 2013. 5 (10): 123.
	Sala A , Woodruff D R , Meizer F C . Carbon dynamics in trees:feast or famine. Tree Physiology, 2012. 32 (6): 764- 775. doi: 10.1093/treephys/tpr143
	Sevanto S , McDowell N G , Dickman L T , et al. How do trees die? A test of the hydraulic failure and carbon starvation hypotheses. Plant, Cell and Environment, 2014. 37 (1): 153- 161. doi: 10.1111/pce.12141
	Sun S J , Meng P , Zhang J S , et al. Hydraulic lift by Juglans regia relates to nutrient status in the intercropped shallow-root crop plant. Pant and Soil, 2014. 374, 629- 641.
	Wiley E , Helliker B . A re-evaluation of carbon storage in trees lends greater support for carbon limitation to growth. New Phytologist, 2012. 195 (2): 285- 289. doi: 10.1111/j.1469-8137.2012.04180.x
	Zhang D , Du G , Sun Z , et al. Agroforestry enables high efficiency of light capture, photosynthesis and dry matter production in a semi-arid climate. European Journal of Agronomy, 2018. 94 (3): 1- 11.
	Zhang Y J , Meinzer F C , Qi J H , et al. Midday stomatal conductance is more related to stem rather than leaf water status in subtropical deciduous and evergreen broadleaf trees. Plant Cell & Environment, 2013. 36 (1): 149- 58.

季节Season	与核桃树距离 Distance from walnut tress	土壤含水量 Soil moisture content(%)
旱季 Dry season	0.6 m	13.85±0.73a
	1.5 m	13.14±0.96ab
	2.5 m	12.00±0.65b
	单作Monoculture	11.09±0.57c
雨季 Rainy season	0.6 m	23.00±0.43a
	1.5 m	23.93±0.58b
	2.5 m	24.03±1.17b
	单作Monoculture	24.46±1.13b

季节Season	位置Position	株高Height/cm	基径Basal diameter/cm	根生物量Root biomass/g	茎生物量Stem biomass/g	叶生物量Leaf biomass/g	根冠比Root-shoot ratio
旱季 Dry season	0.6 m	28.74±2.22a	2.75±0.47a	0.49±0.19a	0.44±0.15a	1.44±0.23a	0.23±0.018a
	1.5 m	45.94±4.49b	3.96±0.68b	1.38±0.31b	1.32±0.44b	4.10±0.60b	0.25±0.017a
	2.5 m	49.63±7.91bc	4.64±0.41b	2.27±0.16c	1.72±0.37b	6.89±1.36c	0.27±0.017a
	单作Monoculture	55.57±3.58c	5.86±0.64c	4.52±0.75c	3.29±0.76c	10.94±1.93 d	0.33±0.016b
雨季 Rainy season	0.6 m	42.54±4.43a	3.98±1.08a	2.54±0.38a	2.80±1.76a	5.93±0.82a	0.27±0.017a
	1.5 m	54.14±7.01b	5.29±0.50b	4.64±0.60b	5.08±1.07ab	11.79±2.10b	0.29±0.017ab
	2.5 m	64.72±3.35c	6.95±0.41c	7.14±0.86c	6.70±3.62b	17.29±1.38c	0.32±0.011b
	单作Monoculture	77.16±2.06d	7.12±1.20c	11.84±2.09d	14.22±4.40c	23.31±7.20d	0.33±0.019b

[1]	王凯,张大鹏,宋立宁,吕林有,刘建华. 氮沉降和降水增加对榆树幼苗不同器官碳氮磷分配格局的影响[J]. 林业科学, 2020, 56(3): 172-183.
[2]	杨保国, 贾宏炎, 郝建, 李运兴, 庞圣江, 刘士玲, 张培, 牛长海, 蔡道雄. 不同林龄柚木人工林心边材生长变异特征[J]. 林业科学, 2020, 56(1): 65-73.
[3]	郭雯, 雷刚, 漆良华, 王一, 徐瑞晶, 张建. 海南岛簕竹属5个竹种雨季光合特性与叶片形态结构性状[J]. 林业科学, 2019, 55(8): 63-72.
[4]	赵志江, 郭文霞, 康东伟, 崔莉, 赵联军, 李俊清. 川西亚高山岷江冷杉和紫果云杉径向生长对气候因子的响应[J]. 林业科学, 2019, 55(7): 1-16.
[5]	贾荛祯, 王明, 王传华. 川金丝猴食源地衣长松萝生长、存活与生理学特征对模拟氮沉降的响应[J]. 林业科学, 2019, 55(7): 17-26.
[6]	王艺, 贾忠奎, 马履一, 邓世鑫, 朱仲龙, 桑子阳. 4种植物生长调节剂对红花玉兰嫩枝扦插生根的影响[J]. 林业科学, 2019, 55(7): 35-45.
[7]	沈乐, 徐建民, 李光友, 陆钊华, 杨雪艳, 朱映安, 胡杨, 宋佩宁, 郭文仲. 尾叶桉与巨桉杂种F₁代生长性状遗传分析[J]. 林业科学, 2019, 55(7): 68-76.
[8]	薛春泉, 徐期瑚, 林丽平, 何潇, 曹磊, 李海奎. 基于异速生长和理论生长方程的广东省木荷生物量动态预测[J]. 林业科学, 2019, 55(7): 86-94.
[9]	吴丽芳, 魏晓梅, 陆伟东. 白刺花胚性愈伤组织诱导及体细胞胚发生[J]. 林业科学, 2019, 55(7): 170-177.
[10]	哈蓉, 马亚平, 曹兵, 郭芳芸, 宋丽华. 模拟CO₂浓度升高对宁夏枸杞营养生长与果实品质的影响[J]. 林业科学, 2019, 55(6): 28-36.
[11]	蒋铮, 于倩楠, 乔明锋, 肖娟, 张子良, 尹华军. 云杉幼树根系分泌物对2种草本植物种子萌发和幼苗生长的影响[J]. 林业科学, 2019, 55(6): 160-166.
[12]	肖遥, 易飞, 韩东花, 卢楠, 杨桂娟, 赵鲲, 王军辉, 麻文俊. 楸树种间和种内杂种生长与光合系统氮素利用及分配的差异分析[J]. 林业科学, 2019, 55(5): 55-64.
[13]	官纪元, 樊卫国. 不同磷水平下刺梨实生苗生长及根系形态特征与内源激素含量的关系[J]. 林业科学, 2019, 55(4): 51-61.
[14]	夏永杰, 庞勇, 刘鲁霞, 陈博伟, 董斌, 黄庆丰. 高精度DEM支持下的多时期航片杉木人工林树高生长监测[J]. 林业科学, 2019, 55(4): 108-121.
[15]	何怀江, 张忠辉, 张春雨, 郝珉辉, 姚杰, 解蛰, 高海涛, 赵秀海. 采伐强度对东北针阔混交林林分生长和物种多样性的短期影响[J]. 林业科学, 2019, 55(2): 1-12.