Effects of Soil Temperature and Moisture on the Physiological Mechanism of Plant Buds Soil temperature is an important environmental factor that directly or indirectly affects plant growth and development. Many physiological processes (such as stomatal conductance, transpiration, transmission of nutrients, and absorption of carbon dioxide) are closely related to temperature. In these physiological processes, soil moisture content also directly influences the change of this amount. Monitoring of soil moisture temperature A soil moisture temperature detector can be used. The soil temperature can change many factors of the plant. For the budding plants, it directly affects the physiological function of the bud.
Through the use of soil moisture temperature and speed tester to detect the soil temperature, and view the roots of plants to view, found that a higher soil temperature can change the root growth, respiration and nutrient absorption. In the process of plant germination and bud growth, higher soil temperature, external mechanical resistance, and lower matrix potential are the main causes of poor crop germination, low emergence rate, and low seedling rate. It has been reported that low soil temperatures combined with a high-humidity environment can cause the soil to breed pathogens that cause crops to induce various types. Improper root zone temperatures can cause shoot water deficits by altering the balance between root water uptake and shoot water consumption. The effect of soil moisture on crops during seedling growth is also extremely large. In the control of seedling moisture, soil moisture temperature tester can be used to measure and control.
Plant root growth is very sensitive to changes in soil temperature, and each species has an optimal temperature range for root development. The optimum temperature for root development and activity is usually determined based on their combined effects on root dryness, length, meristem, nutrient uptake, water uptake, and microbial interactions.
In the process of plant growth, if there is a certain difference between the temperature and the optimum temperature in the soil, the structure and function of the root will change accordingly, and the root system at a low temperature will be smaller than the temperature at the conventional temperature. Each crop has its own optimum temperature at which the crop's root system develops optimally, but exceeding this range causes certain changes in the crop's root system, through the use of a temperature and humidity monitor. To detect temperature and humidity changes in the soil, understand the optimum temperature and humidity in the plant, and then adjust the development of the root system to avoid changes in the physiological mechanism of plant seedlings caused by dissatisfaction with temperature and humidity.
Through the use of soil moisture temperature and speed tester to detect the soil temperature, and view the roots of plants to view, found that a higher soil temperature can change the root growth, respiration and nutrient absorption. In the process of plant germination and bud growth, higher soil temperature, external mechanical resistance, and lower matrix potential are the main causes of poor crop germination, low emergence rate, and low seedling rate. It has been reported that low soil temperatures combined with a high-humidity environment can cause the soil to breed pathogens that cause crops to induce various types. Improper root zone temperatures can cause shoot water deficits by altering the balance between root water uptake and shoot water consumption. The effect of soil moisture on crops during seedling growth is also extremely large. In the control of seedling moisture, soil moisture temperature tester can be used to measure and control.
Plant root growth is very sensitive to changes in soil temperature, and each species has an optimal temperature range for root development. The optimum temperature for root development and activity is usually determined based on their combined effects on root dryness, length, meristem, nutrient uptake, water uptake, and microbial interactions.
In the process of plant growth, if there is a certain difference between the temperature and the optimum temperature in the soil, the structure and function of the root will change accordingly, and the root system at a low temperature will be smaller than the temperature at the conventional temperature. Each crop has its own optimum temperature at which the crop's root system develops optimally, but exceeding this range causes certain changes in the crop's root system, through the use of a temperature and humidity monitor. To detect temperature and humidity changes in the soil, understand the optimum temperature and humidity in the plant, and then adjust the development of the root system to avoid changes in the physiological mechanism of plant seedlings caused by dissatisfaction with temperature and humidity.