我国4种主要苹果树形光合能力差异研究

Analysis of photosynthetic capacity of four apple canopy structures in China

  • 摘要: 光合作用是影响果树生长发育的重要因素, 果实的产量和品质主要取决于树冠内叶片的光合作用分布。本研究主要目的是利用三维树冠光合耦合模型模拟比较我国4种主要苹果树形(小冠疏层形、疏散分层形、纺锤形和开心形)光合能力的三维分布和日变化。试验于2010-2012年在富士苹果(Malus domestica Borkh. cv. "Fuji")园进行, 通过实测确定三维树冠内叶片和辐射分布, 根据不同辐射下叶片最大光合速率经验公式计算叶片净光合速率(Pn)在三维树冠空间内的分布。结果表明, Pn的三维分布和相对辐射相似, 在树冠上部变化平缓, 在树冠内随辐射的降低而急剧减少; 光合总量的分布主要取决于叶面积密度。通过对4种主要苹果树形光合能力分析研究发现, 当PAR=1 500 μmol·m-2·s-1时, 4种树形的Pn分别为: 小冠疏层形6.72 μmol·m-2·s-1、疏散分层形7.52 μmol·m-2·s-1、纺锤形7.24 μmol·m-2·s-1、开心形9.88 μmol·m-2·s-1。不同树形日光合总量的差异主要与叶面积指数相关; 在晴天, 单位地面上4种树形的日光合总量分别为: 小冠疏层形665.5 mmol·m-2·d-1、疏散分层形791.7 mmol·m-2·d-1、纺锤形752.6 mmol·m-2·d-1、开心形601.1 mmol·m-2·d-1。研究表明, 4种苹果树形中开心形树冠Pn高, 有利于提高果实品质; 而其他3种树形的光合总量大, 有利于提高果实产量。

     

    Abstract: Photosynthesis is the most important factor influencing the growth and development of fruit trees. Using field data to model the three-dimensional (3-D) distribution of photosynthesis in hedgerow tree crops in hourly time steps is critical for the accurately estimation of orchard yield and quality. Here in this study, a coupled model was used to simulate the 3-D distribution and diurnal variations of net photosynthetic rate of four canopy structures of apple trees. The four apple tree canopy structures were small and sparse canopy (APS-Ⅰ), dispersed stratified canopy (APS-Ⅱ), spindle canopy (APS-Ⅲ), and open-center canopy (APS-Ⅳ). The experiment was conducted in four "Fuji" apple (Malus domestica Borkh. cv. "Fuji") orchards during the 2010-2012 growth seasons. While the coupled model was based the 3-D distributions of canopy radiation and leaf area from direct field measurements, the leaf photosynthesis model was based on mechanistic knowledge of C3 plants. Experiential equations best described foliage photosynthetic capacity for different canopy positions. The results showed that 3-D distribution of leaf net photosynthetic rate (Pn) was similar to that of relative radiation. A flat curve was observed for canopy top of the 3-D Pn distribution, decreasing rapidly with decreasing photosynthetically active radiation (PAR). However, the 3-D distribution of total photosynthetic rate of a unit cell depended mainly on leaf area density pattern. Average Pn of the four apple tree canopy structures determined by the coupled model were 6.72 μmol·m-2·s-1 for APS-Ⅰ, 7.52 μmol·m-2·s-1 for APS-Ⅱ, 7.24 μmol·m-2·s-1 for APS-Ⅲ and 9.88 μmol·m-2·s-1 for APS-Ⅳ, and with canopy top PAR of 1 500 μmol·m -2·s-1. The diurnal variation in Pn was largely driven by PAR, depicted in di-peak curves. Differences in canopy Pn were related to the differences in leaf area index (LAI) of the tree canopy. Under clear day conditions, total photosynthesis per unit ground area was 665.5 mmol·m-2·d-1 for APS-I, 791.7 mmol·m-2·d-1 for APS-Ⅱ, 752.6 mmol·m-2·d-1 for APS-Ⅲ and 601.1 mmol·m-2·d-1 for APS-Ⅳ. There was strong agreement between the measured and simulated Pn for the different tree canopy structures. This showed that the coupled model reliably predicted Pn for the different tree canopy structures. The results also showed that the open-center apple tree canopy enhanced fruit quality with bigger Pn while the other canopies enhanced yield with high canopy photosynthetic rate. The main aim of tree pruning was to remove useless shoots and leaves, which parts were easily identified by 3-D plots. Overall, the coupled model performed well in predicting instantaneous photosynthetic rates for different apple tree canopy structures in 3-D space.

     

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