19 research outputs found

    EFFECT OF ENVIRONMENTAL FACTORS ON OPTIMUM TEMPERATURE AND PHOTOSYNTHETIC INTENSITY OF PLANTS ADAPTED TO VARIOUS CONDITIONS

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    Effects of short-term light of various intensities, CO_2 and temperature changes on the reaction of photosynthetic apparatus of cucumber plants grown for a long time at various levels of irradiation and temperature were studied. A shift of photosynthetic optimum temperature towards higher temperatures was observed with increase in light intensity. Temperature control is more efficient within a range of light intensities, limiting a linear part of photosynthetic light curve. For the plants grown at higher irradiation levels the maintenance of the optimum temperature provided more efficient utilization of the light of low intensities by them. At all the levels of irradiation an increase of growing air temperature of plants by 5℃ led to a shift of the photosynthetic optimum temperature by 1℃ towards higher temperature. The plants grown at 15℃ had a higher photosynthetic rate as compared with those grown at other temperatures. Low rates of CO_2 uptake were observed at a temperature of 30℃. An increase of CO_2 content up to 0.1% at irradiation of 70W/m^2 insignificantly affected the rates of CO_2 uptake as compared with natural concentration. Simultaneous rise of the irradiation level and temperature provided an increase of CO_2 positive effect on photosynthesis. The result indicates that it is necessary to control temperature regime taking into account CO_2 concentration in the air and the preceding light and temperature conditions of plant growth

    EFFECT OF ENVIRONMENTAL FACTORS ON OPTIMUM TEMPERATURE AND PHOTOSYNTHETIC INTENSITY OF PLANTS ADAPTED TO VARIOUS CONDITIONS

    No full text
    Effects of short-term light of various intensities, CO_2 and temperature changes on the reaction of photosynthetic apparatus of cucumber plants grown for a long time at various levels of irradiation and temperature were studied. A shift of photosynthetic optimum temperature towards higher temperatures was observed with increase in light intensity. Temperature control is more efficient within a range of light intensities, limiting a linear part of photosynthetic light curve. For the plants grown at higher irradiation levels the maintenance of the optimum temperature provided more efficient utilization of the light of low intensities by them. At all the levels of irradiation an increase of growing air temperature of plants by 5℃ led to a shift of the photosynthetic optimum temperature by 1℃ towards higher temperature. The plants grown at 15℃ had a higher photosynthetic rate as compared with those grown at other temperatures. Low rates of CO_2 uptake were observed at a temperature of 30℃. An increase of CO_2 content up to 0.1% at irradiation of 70W/m^2 insignificantly affected the rates of CO_2 uptake as compared with natural concentration. Simultaneous rise of the irradiation level and temperature provided an increase of CO_2 positive effect on photosynthesis. The result indicates that it is necessary to control temperature regime taking into account CO_2 concentration in the air and the preceding light and temperature conditions of plant growth

    EFFECT OF VARIOUS TEMPERATURES IN THE ROOT ZONE AND LIGHT INTENSITIES ON PHOTOSYNTHESIS AND TRANSPIRATION OF TOMATO PLANTS

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    Photosynthetic intensity, transpiration and stomatal resistance (R_s) of tomato plant leaves were studied at various light intensities and temperatures in the root zone. Temperature regime had an insignificant effect on a gas exchange of plants at an irradiation of 900μmol m^<-2> s^<-1>. Less irradiation, 180μmol m^<-2> s^<-1>, resulted in a relatively greater effect of temperature on CO_2 uptake. Transpiration rate and stomatal resistance to CO_2 varied slightly within a wide range of temperature changes. An increase and decrease of R_s were observed only at low (<14) and high (>28℃) temperatures, respectively. Reverse dependence was found for the process of transpiration. The highest transpiration coefficient Ph/T was observed at 20℃. The results indicate that it is necessary to take all the aspects of plant activity into account for determining optimal growth conditions

    EFFECT OF VARIOUS TEMPERATURES IN THE ROOT ZONE AND LIGHT INTENSITIES ON PHOTOSYNTHESIS AND TRANSPIRATION OF TOMATO PLANTS

    No full text
    Photosynthetic intensity, transpiration and stomatal resistance (R_s) of tomato plant leaves were studied at various light intensities and temperatures in the root zone. Temperature regime had an insignificant effect on a gas exchange of plants at an irradiation of 900μmol m^ s^. Less irradiation, 180μmol m^ s^, resulted in a relatively greater effect of temperature on CO_2 uptake. Transpiration rate and stomatal resistance to CO_2 varied slightly within a wide range of temperature changes. An increase and decrease of R_s were observed only at low (28℃) temperatures, respectively. Reverse dependence was found for the process of transpiration. The highest transpiration coefficient Ph/T was observed at 20℃. The results indicate that it is necessary to take all the aspects of plant activity into account for determining optimal growth conditions

    PHOTOSYNTHESIS AND ABSORPTION OF MINERAL NUTRIENT IN TOMATO PLANTS UNDER VARIOUS ROOT ZONE TEMPERATURE AND LIGHT CONDITIONS

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    Effect of various light and temperature regimes in the root zone on the light stage of photosynthesis, gas exchange, growth processes and absorption of mineral nutrients by tomato plants were studied. Optimum temperatures for dry matter accumulation and absorption of mineral nutrients were found to be shifted when the irradiation condition were changed. A shift of optimum temperatures for dry matter accumulation and absorption of mineral nutrients was found to be due to a change in irradiation conditions. It was 1.6℃ per 70 Wm^ within the range of 50-175 Wm^. The maximum absorption of mineral nutrients did not always coinside with the optimums of dry matter accumulation. For example, at 50 Wm^ the maximum amounts of P, Ca and Mg were absorbed at higher temperatures as compared with the optimum temperatures for dry matter accumulation. Only for N and K these temperatures coinsided. At 175 Wm^ the maximum absorption of N, P, K, Ca, Mg was at the temperatures corresponding to those optimal for dry matter accumulation. These data are of particular importance for precise regulation of temperatures and concentrations of mineral nutrients under controlled conditions of the hydroponic green houses
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