High efficiency sweet cherry orchard systems research

Abstract

The large tree size, and delicate nature and small size of the fruit, makes production of sweet cherries Fig. 6 - Planar UFO sweet cherry canopy architectural orchard designs: A) vertical-trellis UFO with 18,725 upright leaders per ha or B) Vtrellis UFO with 24,996 inclined leaders per ha, in theory with 33% higher yield potential, but slightly less training, harvest and pruning efficiency. Fig. 6 - Progettazione dell’architettura della chioma in piano “UFO” su ciliegio dolce: A) sostegni verticali per UFO con 18725 fusti verticali per ha o B) sostegno a V per UFO con 24996 fusti inclinati per ha, in teoria con il 33% in più di potenziale produttivo, ma leggermente meno per quanto riguarda efficienza di allevamento, raccolta e potatura. A B Lang 34 among the most traditionally labor-intensive tree fruits. Great improvements in orchard efficiencies have been achieved over the past two decades, prompted by the development of precocious, vigorcontrolling rootstocks such as the Gisela (Gi) series. Recent training systems research has focused on canopy architectural designs that improve various orchard efficiencies, including: 1) light interception and distribution whit minimization of shade; 2) bloom, fruit development and ripening for more uniform fruit harvest; 3) balanced, quantifiable crop load management for achieving high fruit quality; 4) simplified strategies for fruitwood development and maintenance to reduce hand-pruning labor; 5) partial mechanization to reduce pruning and harvest labor; 6) utilization of protective orchard covers to mitigate the risk of crop damage from rain, hail, frost, and wind; and 7) better spray coverage for protection from insect pests and diseases. Across several sites in North America, the NC140 regional research project has evaluated the performance of three sweet cherry cultivars on dwarfing (Gi3), semi-dwarfing (Gi5), and semi-vigorous (Gi6) rootstocks trained to “threedimensional” and “two-dimensional” (planar) canopy architectures over nine years to date. The planar Super Slender Axe (SSA) training system had the highest early yields on a per tree and per orchard basis, but the planar Upright Fruiting Offshoots (UFO) training system sustained higher cumulative yields upon reaching maturity. The three-dimensional Tall Spindle Axe (TSA) trees had higher early yields than those trained to the three-dimensional Kym Green Bush (KGB) canopy architecture, but the KGB trees achieved nearly comparable cumulative yields. Fruitwood renewal strategies are critical for maintenance of yields and fruit quality. Profitable yields of high quality fruit are achievable for each of the canopy architectures, but each also has specific advantages and challenges, including suitability for specific rootstocks and cultivars. These are discussed, including comparisons of the two- vs. three-dimensional canopy architectures developed as single leader (SSA vs. TSA) and multiple leader (UFO vs. KGB) training systems. The advantages of utilizing the natural light interception efficiencies and growth habit of sweet cherry in the simplified structure of UFO-style planar canopy architectures is expanding beyond sweet cherries to many other major trees fruits around the world as well.