扁桃||冬小麦间作模式下树冠结构对间作区域光环境的影响

Effect of tree canopy structure on light condition in almond-winter wheat intercropping systems

  • 摘要: 本文研究了作物、果树间作模式下果树树冠结构对间作作物区域光环境的影响, 为果粮间作模式下适宜果树高光效树形结构的确定提供理论依据。以南疆地区扁桃(10 a)||冬小麦间作种植模式为研究对象, 扁桃树形分为疏散分层形、开心形、高干形、小冠半圆形4个树形处理, 以非间作的冬小麦大田为对照, 于冬小麦灌浆期对间作区域不同波段辐射强度、光谱组成和光合有效辐射(PAR)日变化规律进行分区测定。结果表明: 1)各树形对应间作区域光环境优劣程度从高至低依次为小冠半圆形、高干形、开心形、疏散分层形, 几个树形处理间作区域总辐射强度平均值分别为对照的55.63%、46.54%、37.87%和28.76%, 光合有效辐射强度依次为自然光对照的55.84%、44.57%、35.52%和26.40%; 2)与自然光对照相比, 间作区域各波段光照辐射强度均有不同程度降低, 其中PAR、蓝紫光、黄绿光和红橙光区域消减幅度高于总辐射平均值, 紫外、近红外和远红外区域消减幅度低于总辐射平均值。以疏散分层形西侧冠下区为例, 该区域总辐射消减为自然光的11.37%, 蓝紫光、黄绿光、红橙光和光合有效辐射分别消减至对照的7.98%、8.42%、8.62%和8.30%; 紫外光、近红外和远红外分别消减至对照的12.30%、15.94%和23.00%; 3)光质参数中“红橙光/远红外”比值对树冠结构特征变化敏感度高, 变异系数为23.34%, 可作为对间作区域光环境评价的主要指标; 4)冠幅、干高、树高、有无主干等树冠结构指标对间作区域特别是东侧区域的PAR日变化趋势影响大。综合以上结果, 南疆扁桃||冬小麦间作模式下, 控冠、提干、落头等整形修剪措施能够改善间作区域的光照条件, 以采用小冠半圆形树形间作区域光环境最优。

     

    Abstract: Intercropping of fruit trees and cereals is one of the major cropping patterns in South Xinjiang. As trees age and canopy volumes increase in intercropping systems, low-light stress due to tree canopy effect becomes the main drive behind dramatic reduction in yield. However, given the fragile ecological environment of South Xinjiang and food security, this system has continued for a long time now. In this study, the relationship between canopy structure and light condition in intercropping systems was determined in order to provide theoretical basis for choosing canopy structures suitable for optimal production. Almond tree (10 a) and winter wheat intercropping system was used to study the effects of 4 canopy structures (delayed open-central shape, open-center shape, high-stem shape and semicircle small-canopy shape) on radiation intensity of various wavebands, spectral composition and diurnal variations of photosynthetically active radiation (PAR) during wheat filling stage, with monoculture winter wheat as the control. The results showed that: 1) In terms of quality of light condition in intercropping systems, the order from high to low was semicircle small-canopy shape, high-stem shape, open-center shape and delayed open-central shape. The averages of radiation intensity under the 4 canopy shapes were respectively 55.63%, 46.54%, 37.87% and 28.76% of the control. Correspondingly, PAR intensities were 55.84%, 44.57%, 35.52% and 26.40% of the control. 2) Compared with the control, radiation intensity of each waveband decreased at various degrees. Reductions in PAR, blue-violet, yellow-green and red-orange light radiations were larger than average reduction in total radiation. However, reductions in ultraviolet, near infrared and far infrared light radiation were smaller than average reduction in total radiation. For example, in the eastern region under delayed open-central shape canopy, total radiation decreased to 11.37% of the control. Then blue-violet light, yellow-green light, red-orange light and PAR decreased respectively to 7.98%, 8.42%, 8.62% and 8.30% while ultraviolet light, near infrared light, far infrared light decreased to 12.30%, 15.94% and 23.00% of the control. 3) For all the light quality parameters, the ratio of red-orange light to far infrared light was most sensitive to canopy structure (CV = 23.34%). It can be used as a major indicator for light conditions in intercropping systems. 4) Canopy structure characteristics (e.g., canopy width, stem height, tree height and whether center stem) existed or had little effect on diurnal variation in PAR in intercropping systems, especially for regions east of the tree. Based on the above analysis, light conditions in intercropping systems can be improved by tree pruning such as canopy limitation, trunk height increase and head cut. Among the four canopy structures, semicircle small-canopy shape produced the best light conditions.

     

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