Novel Low Tunnel Coverings and Plant Type Affect Productivity of Day-neutral Strawberries

IF 1 4区农林科学 Q3 HORTICULTURE

Horttechnology Pub Date : 2024-06-01 DOI:10.21273/horttech05409-24

Richard Gaisser, Kaspar Kuehn, Marvin Pritts

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引用次数: 0

Abstract

Growers producing day-neutral strawberries (Fragaria ×ananassa) in temperate climates face challenges when attempting to extend the season and mitigate the effects of rain. Conventional plastic coverings over low tunnels have been used for these purposes, but they often exacerbate heat-induced problems in summer. We examined two approaches for addressing this challenge. The first was to start dormant bare root ‘Albion’ strawberry plants in small pots in the greenhouse, then plant them into the field in spring so they could begin production before the onset of consistently high temperatures. Plants set in small pots on 26 Feb in the greenhouse and field planted on 6 May were compared with bare root plants set directly into the field on 6 May. The second approach used various low tunnel coverings to modify the light and temperature environment around the plants. Three coverings were woven nets embedded with reflective strips at various densities that allowed 50%, 60%, and 70% light transmission, and these were intended to lower temperatures under the covers by reflecting infrared radiation. A fourth covering was a polyethylene plastic embedded with optically active additives that shift incident light into wavelengths that are more photosynthetically active. Two other covers were standard commercial polyethylene plastics, and the final treatment was an uncovered control. Over the 2020 and 2021 growing seasons (hot and dry vs. moderate and wet, respectively), plots were harvested once or twice a week from June through October and fruit yield, size, and marketability were assessed. In both years, strawberry plants started in the greenhouse produced significantly higher yields than bare root plants over the season (30.5% and 43.7%). Bare root plants were less responsive to cover type than greenhouse plants. In 2020, yields tended to be higher in the middle of summer in plots with reflective coverings that reduced temperature and higher later in the season with coverings of wavelength-shifting film. Polyethylene covers that increased temperature without shifting the light spectrum had lower yields. Under the cooler conditions of 2021, plants under covers that increased temperature tended to have higher yields. In a third year (2023), bare root plants were covered with a reflective covering from 29 Jun until 1 Sep, then this cover was replaced with polyethylene with optical additives as the weather cooled and light levels dropped. This sequenced treatment was compared with uncovered plots and plots covered with standard commercial polyethylene plastic. Plants under the two-phase sequential covering performed significantly better than uncovered plots or those covered with standard polyethylene plastic alone.

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新型低矮隧道覆盖物和植物类型影响日光中性草莓的产量

在温带气候条件下生产日光中性草莓（Fragaria ×ananassa）的种植者在试图延长草莓生长期和减轻降雨影响时面临着挑战。传统的塑料薄膜覆盖在低矮的隧道上可以达到上述目的，但在夏季往往会加剧热引起的问题。我们研究了两种应对这一挑战的方法。第一种是将休眠期的裸根 "阿尔比恩 "草莓植株放入温室的小花盆中，然后在春季将其种植到田间，这样它们就能在持续高温到来之前开始生产。2 月 26 日在温室小花盆中栽种、5 月 6 日在田间种植的植株与 5 月 6 日直接在田间种植的裸根植株进行了比较。第二种方法是使用各种低矮的隧道覆盖物来改变植物周围的光照和温度环境。其中三种覆盖物是编织网，内嵌不同密度的反光条，透光率分别为 50%、60% 和 70%，目的是通过反射红外辐射来降低覆盖物下的温度。第四种覆盖物是一种聚乙烯塑料，内嵌光学活性添加剂，可将入射光转换成光合作用更活跃的波长。另外两个覆盖物是标准的商用聚乙烯塑料，最后一个处理是未覆盖的对照。在 2020 年和 2021 年的生长季节（分别为炎热干燥和温和潮湿），从 6 月到 10 月，每周对地块进行一次或两次采收，并对果实产量、大小和适销性进行评估。在这两年中，在温室中开始种植的草莓植株在整个季节的产量明显高于裸根植株（30.5% 和 43.7%）。裸根植株对覆盖类型的反应不如温室植株。2020 年，采用反射性覆盖物降温的地块在盛夏产量往往较高，而采用波长偏移薄膜覆盖物的地块在后期产量往往较高。聚乙烯覆盖物在不改变光谱的情况下提高了温度，但产量较低。在 2021 年较凉爽的条件下，温度升高的覆盖物下的植物产量往往较高。第三年（2023 年），裸根植物从 6 月 29 日到 9 月 1 日一直覆盖反光罩，然后随着天气转凉，光照度下降，再用添加了光学添加剂的聚乙烯罩代替。这种有序的处理方法与无覆盖物的地块和覆盖标准商用聚乙烯塑料的地块进行了比较。与未覆盖的地块或仅覆盖标准聚乙烯塑料的地块相比，两阶段有序覆盖下的植物表现明显更好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Horttechnology 农林科学-园艺

CiteScore

2.30

自引率

10.00%

发文量

审稿时长

3 months

期刊介绍： HortTechnology serves as the primary outreach publication of the American Society for Horticultural Science. Its mission is to provide science-based information to professional horticulturists, practitioners, and educators; promote and encourage an interchange of ideas among scientists, educators, and professionals working in horticulture; and provide an opportunity for peer review of practical horticultural information.