Journal
FRONTIERS IN PLANT SCIENCE
Volume 12, Issue -, Pages -Publisher
FRONTIERS MEDIA SA
DOI: 10.3389/fpls.2021.669909
Keywords
apple; carbon balance; lidar; respiration; precision horticulture; growth; canopy photosynthesis model
Categories
Funding
- Ministry of Agriculture, Environment and Climate Protection of the federal state of Brandenburg
- agricultural European Innovation Partnership (EIP-AGRI) [80168342]
- German Research Foundation
- Open Access Publication Fund of TU Berlin
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The study investigated the fruit-bearing capacity (FBC) of apple trees through considering the inter-tree variability of leaf area. It was found that the variance of FBC was similar in two years, but each individual tree showed different FBC in both seasons, with FBC ranging from 84 to 179 fruit per tree depending on the total leaf area of the trees. The study also found that fruit quality, indicated by size and soluble solids content, showed enhanced percentages according to the seasonally total absorbed photosynthetic energy.
The capacity of apple trees to produce fruit of a desired diameter, i.e., fruit-bearing capacity (FBC), was investigated by considering the inter-tree variability of leaf area (LA). The LA of 996 trees in a commercial apple orchard was measured by using a terrestrial two-dimensional (2D) light detection and ranging (LiDAR) laser scanner for two consecutive years. The FBC of the trees was simulated in a carbon balance model by utilizing the LiDAR-scanned total LA of the trees, seasonal records of fruit and leaf gas exchanges, fruit growth rates, and weather data. The FBC was compared to the actual fruit size measured in a sorting line on each individual tree. The variance of FBC was similar in both years, whereas each individual tree showed different FBC in both seasons as indicated in the spatially resolved data of FBC. Considering a target mean fruit diameter of 65 mm, FBC ranged from 84 to 168 fruit per tree in 2018 and from 55 to 179 fruit per tree in 2019 depending on the total LA of the trees. The simulated FBC to produce the mean harvest fruit diameter of 65 mm and the actual number of the harvested fruit > 65 mm per tree were in good agreement. Fruit quality, indicated by fruit's size and soluble solids content (SSC), showed enhanced percentages of the desired fruit quality according to the seasonally total absorbed photosynthetic energy (TAPE) of the tree per fruit. To achieve a target fruit diameter and reduce the variance in SSC at harvest, the FBC should be considered in crop load management practices. However, achieving this purpose requires annual spatial monitoring of the individual FBC of trees.
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