Yuta Miyoshi, K. Hidaka, T. Okayasu, D. Yasutake, M. Kitano
{"title":"Effects of Local CO2 Enrichment on Strawberry Cultivation during the Winter Season","authors":"Yuta Miyoshi, K. Hidaka, T. Okayasu, D. Yasutake, M. Kitano","doi":"10.2525/ECB.55.165","DOIUrl":null,"url":null,"abstract":"Carbon dioxide (CO2) concentration is one of the most important environmental factors in crop production. Within the range of suitable CO2 concentration for crops, an increase of CO2 concentration results in an increase in net crop photosynthesis (Cure and Acock, 1986; Keutgen et al., 1997) and thereby promotes photosynthate translocation, which directly controls the crop yield and quality (Troughton and Currie, 1977; David et al., 2014). Therefore, in greenhouse horticulture, CO2 enrichment is commonly used to realize high crop productivity (Kawashima et al., 2008). In strawberry production, CO2 enrichment has been practiced since the 1970s (Kato et al., 2015), and is used widely today in strawberry-cultivation greenhouses (Wada et al., 2010). In areas of scant solar radiation during the winter season, daytime enrichment of CO2 increased crop yield by 40% (Kawashima, 1991), while in areas of abundant solar radiation, early morning enrichment of CO2 increased crop yield by 16% (Shigeno et al., 2001). The effect of CO2 enrichment on increasing yield is well established; however, a normative CO2 enrichment strategy has not been determined (Mizukami et al., 2011). Moreover, a previous study revealed the ineffectiveness of industrystandard methods for enriching CO2 (Miyoshi et al., 2013). At our experimental site in the northern Kyushu area during the winter strawberry production season, CO2 was generally enriched in the greenhouse using a fuel-burning CO2 generator only early in the morning. CO2 concentrations inside the greenhouse began to increase with the beginning of CO2 enrichment and reached a maximum of approximately 2,000 ppm. However, beginning greenhouse ventilation to cool the greenhouse rapidly decreases the CO2 concentration inside the greenhouse. Consequently, the CO2 concentration decreases to outdoor levels before noon, when photosynthetic photon flux density (PPFD) becomes sufficient for strawberry crop photosynthesis. Thus, greenhouse ventilation renders CO2 enrichment ineffective with regard to increasing photosynthesis in the strawberry crop. In this study, we propose a new local CO2 enrichment system. The system enriches CO2 in close proximity to the crops and thereby enables efficient control of CO2 concentration even when the greenhouse ventilation system is active. We applied the system to a strawberry greenhouse with ventilation windows to examine the effect of this local CO2 enrichment. We also examined the effects of CO2 enrichment system on physiological functions such as photo-","PeriodicalId":11762,"journal":{"name":"Environmental Control in Biology","volume":"55 1","pages":"165-170"},"PeriodicalIF":0.0000,"publicationDate":"2017-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"15","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Environmental Control in Biology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.2525/ECB.55.165","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Agricultural and Biological Sciences","Score":null,"Total":0}
引用次数: 15
Abstract
Carbon dioxide (CO2) concentration is one of the most important environmental factors in crop production. Within the range of suitable CO2 concentration for crops, an increase of CO2 concentration results in an increase in net crop photosynthesis (Cure and Acock, 1986; Keutgen et al., 1997) and thereby promotes photosynthate translocation, which directly controls the crop yield and quality (Troughton and Currie, 1977; David et al., 2014). Therefore, in greenhouse horticulture, CO2 enrichment is commonly used to realize high crop productivity (Kawashima et al., 2008). In strawberry production, CO2 enrichment has been practiced since the 1970s (Kato et al., 2015), and is used widely today in strawberry-cultivation greenhouses (Wada et al., 2010). In areas of scant solar radiation during the winter season, daytime enrichment of CO2 increased crop yield by 40% (Kawashima, 1991), while in areas of abundant solar radiation, early morning enrichment of CO2 increased crop yield by 16% (Shigeno et al., 2001). The effect of CO2 enrichment on increasing yield is well established; however, a normative CO2 enrichment strategy has not been determined (Mizukami et al., 2011). Moreover, a previous study revealed the ineffectiveness of industrystandard methods for enriching CO2 (Miyoshi et al., 2013). At our experimental site in the northern Kyushu area during the winter strawberry production season, CO2 was generally enriched in the greenhouse using a fuel-burning CO2 generator only early in the morning. CO2 concentrations inside the greenhouse began to increase with the beginning of CO2 enrichment and reached a maximum of approximately 2,000 ppm. However, beginning greenhouse ventilation to cool the greenhouse rapidly decreases the CO2 concentration inside the greenhouse. Consequently, the CO2 concentration decreases to outdoor levels before noon, when photosynthetic photon flux density (PPFD) becomes sufficient for strawberry crop photosynthesis. Thus, greenhouse ventilation renders CO2 enrichment ineffective with regard to increasing photosynthesis in the strawberry crop. In this study, we propose a new local CO2 enrichment system. The system enriches CO2 in close proximity to the crops and thereby enables efficient control of CO2 concentration even when the greenhouse ventilation system is active. We applied the system to a strawberry greenhouse with ventilation windows to examine the effect of this local CO2 enrichment. We also examined the effects of CO2 enrichment system on physiological functions such as photo-
二氧化碳(CO2)浓度是作物生产中最重要的环境因子之一。在作物适宜的CO2浓度范围内,CO2浓度的增加导致作物净光合作用的增加(Cure and Acock, 1986;Keutgen et al., 1997),从而促进光合作用转运,直接控制作物的产量和品质(Troughton and Currie, 1977;David et al., 2014)。因此,在温室园艺中,通常采用CO2富集来实现作物高产(Kawashima et al., 2008)。在草莓生产中,CO2富集自20世纪70年代以来一直在实践(Kato等人,2015),并且今天在草莓栽培温室中广泛使用(Wada等人,2010)。在冬季太阳辐射不足的地区,白天CO2的富集可使作物产量增加40% (Kawashima, 1991),而在太阳辐射充足的地区,清晨CO2的富集可使作物产量增加16% (Shigeno et al., 2001)。CO2富集对提高产量的作用已得到证实;然而,规范的CO2富集策略尚未确定(Mizukami et al., 2011)。此外,先前的一项研究揭示了富集CO2的行业标准方法的有效性(Miyoshi et al., 2013)。在我们位于九州北部地区的试验点,在冬季草莓生产季节,温室内通常只在清晨使用燃料燃烧CO2发生器富集CO2。随着CO2富集的开始,温室内的CO2浓度开始增加,最高达到约2000 ppm。然而,开始温室通风使温室降温会迅速降低温室内的二氧化碳浓度。因此,在中午之前,当光合光子通量密度(PPFD)达到草莓作物光合作用所需时,CO2浓度降低到室外水平。因此,温室通风使二氧化碳富集在增加草莓作物光合作用方面无效。在本研究中,我们提出了一种新的局部CO2富集系统。该系统在靠近作物的地方富集二氧化碳,因此即使在温室通风系统处于激活状态时也能有效地控制二氧化碳浓度。我们将该系统应用于一个带有通风窗的草莓温室,以检验这种局部二氧化碳富集的效果。我们还研究了CO2富集系统对光合作用等生理功能的影响