Abstract
Tomatoes require higher irradiance, although the incidence of physiological disorders in fruit increases at high temperatures. Near-infrared (800–2500 nm) (NIR) reflective materials are effective tools to suppress rising air temperatures in greenhouses. We examined the physiological and morphological changes in tomato growth and fruit quality when grown in a high tunnel covered with NIR reflective film (NR) and in another covered with polyolefin film (PO; control). There was no relationship between the fruit cracking rate and mean daytime temperature under NR. The fruit temperature at the same truss was lower and the increase in air temperature was slow under NR. Fruit dry matter (DM) content under NR was also significantly decreased. These findings suggest that the reduction in fruit cracking under NR results from a decrease in fruit DM content as a consequence of lower fruit temperature and a decrease in total DM (TDM). Total fruit yield did not differ, whereas TDM was significantly decreased under NR. This was considered to result from a lower transmitted photosynthetic photon flux density (400–700 nm) (PPFD) and LAI, and lower photosynthetic capacity in single leaves because of a decrease in both total nitrogen and chlorophyll content. We conclude that NR film reduces fruit cracking in exchange for a slight reduction in TDM.
Highlights
Tomatoes are one of the most commercially valuable vegetables in the world
Kimura at al. [40] showed that tunnels covered with UV-cut film tended to reduce the incidence of fruit cracking. These results suggest that the reduction in fruit cracking under NIR reflective film (NR) resulted from a decrease in fruit dry matter (DM) content caused by lower fruit temperature and decreased total DM (TDM), and the effects of the wavelength properties of NR
NIR reflective film suppressed the extreme increase in air and fruit temperatures in the high tunnel, and total yield did not differ between the high tunnels
Summary
The demand for tomatoes has increased in Asia and their production and cultivated area have been rising [1]. Tomatoes require high irradiance [2]; the air temperature in greenhouses tends to increase to levels inappropriate for tomato growth, when the amount of solar radiation entering the greenhouse increases in high-temperature regions and seasonally. It is necessary to develop material and management strategies for the greenhouse to improve fruit quality in high-temperature regions and seasons. A simulation study of NIR-filtering materials, used to cover a greenhouse in the Netherlands, indicated that tomato production in the summer could increase by 8.6% because the air temperature inside the greenhouse would be lower by 2.0 ◦ C at noon and crop transpiration would decrease [4].
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