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Hydroponics Lecture 4 .pptx

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Summera Jahan

The pH, electrical conductivity, temperature, and dissolved oxygen levels of a hydroponic nutrient solution all greatly impact plant growth. The pH must be maintained between 5.5-6.5 for most crops and influences nutrient availability. Electrical conductivity measures the salt concentration and total ions available for uptake, with each plant species having an optimal range typically between 1.5-3.5 dS/m. Temperature affects nutrient absorption and uptake rates, with dissolved oxygen critical for root health and function.

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HYDROPONICS Lecture 4
PH level of the nutrient solution The pH value of the nutrient solution greatly affects plants growth. This is because the nutrients added to the nutrient solution are available for the uptake by the plant are soluble in water only at particular pH levels. The plants require a range of pH values to be maintained to ensure the availability of all the nutrients for uptake by the plants. Nutrient solution pH is typically managed between 5.5 and 6.5, and almost all hydroponically grown crops exhibit normal growth and nutrient uptake at this level. However, the optimum pH for maximum growth differs not only between species, but also between cultivar, climatic conditions, and soil, substrate, or nutrient solution conditions
The pH of a hydroponic nutrient solution fluctuates because of the unbalanced anion and cation exchange reaction with roots and there is no buffering capacity in hydroponics. The changes in the pH of a nutrient solution depend on the difference in the magnitude of nutrient uptake by plants, in terms of the balance of anions over cations. When the anions are taken up in higher concentrations than cations, for example, nitrate, the plant excretes OH or HCO3 anions, to balance the electrical charges inside, which which increases the pH of nutrient solution and this process is called physiological alkalinity. Precipitation/dissolution phenomena are often promoted by pH changes and, therefore, pH must be continuously controlled or buffered. Cations may form insoluble hydroxides at alkaline pH or other insoluble precipitates by reacting with other anionic nutrients. PH values above 7 may cause the precipitation of iron, zinc, copper, nickel, and manganese as insoluble hydroxides. Also, at high pH values and high dissolved CO2 concentrations, macronutrients like calcium and magnesium can precipitate as carbonates. At pH above 7, mostly the dissolved phosphorus reacts with calcium forming calcium
The reason for the reduction in phosphorus uptake at a high pH level is explained by the reduction in the concentration of H2PO4 , which is the substrate of the proton- coupled phosphate symporter in the plasma membrane, in the pH range of 5.68.5; conversely, a decrease in pH can increase the activity of proton-coupled solute transporters and enhance anion uptake Slightly acidic pH is optimum for hydroponic production because iron, manganese, calcium, and magnesium may form precipitates and become unavailable at pH above 7. In general, stabilizing the pH of a nutrient solution is necessary for optimum crop productivity in hydroponics, and maintaining an adequate nutrient solution.
Nutrient solution electrical conductivity It is an easy and accurate method of measuring total salt concentration. In soilless culture, the total salt concentration of a nutrient solution must be considered, and the nutrient solution EC is an indicator of electrolyte concentration of the solution and is related to the number of ions available to plants in the root zone. The EC is a measure of the total salts dissolved in the hydroponic nutrient solution. It is used for monitoring applications of fertilizers. In hydroponic production systems, EC management is one of the most important practices that affects the visual, nutritional, and phytochemical quality of leafy vegetables. However, managing the EC in moderately high levelsby adding major nutrients through stock solutionsis a technique that provides great potential to achieve high quality fresh vegetables.
Each plant species has an optimum uptake rate of the nutrient solution; excessively high or low levels of the nutrients in solution have a negative effect on plants. Therefore, it is crucial to determine the suitable EC level of nutrient solutions for growing plants. The optimal EC level range should be from 1.5 to 3.5 dS m1 for most hydroponic crops, but this value varies between crop species, growth stages and environmental conditions. Too low and too high EC would reduce yields, visual quality, phytochemical compounds and poor color and taste, and enhance the negative health effects due to nitrate accumulation. However, too high electrical conductivity in nutrient solution may reduce water absorption by plants and decrease photosynthesis. Higher EC means plants are exposed to salinity stress and high levels of nutrients, which hinders nutrient uptake and induces osmotic stress, ion toxicity and nutrient imbalance which reduces plant yield. e.g. the yield of tomatoes under the hydroponic system increased as EC of the nutrient solution increased from 0 to 3 dS m1 and decreased as the EC increased from 3 to 5 dS m1 due to an increase in water stress.
EC of Nutrient Solution Indicator of electrolyte Conc. The No. of ions available for plant uptake It is the measure of the total salts dissolved It helps to monitor the application of fertilizer Plant spp. have an optimum uptake rate of nutrients Too high or low EC reduces plant yield
Nutrient solution temperature Temperature of the nutrient solution is considered as one of the most important factors that determines crop yield and quality in hydroponic systems. The temperature of the nutrient solution affects the physiological process in the root, such as the absorption of water and nutrients. The thermal regulation of hydroponic solution can contribute towards improvement in the plant physiological processes. e.g. nutrient and water uptake for plants grown in glasshouses may be positively and adversely affected if the hydroponic solution temperature increases or decreases beyond optimum level. The nutrient solution temperature tends to determine the concentration of nutrients absorbed by the plant, as more nutrients are dissolved at higher temperatures and less at lower temperatures, consequently influencing the efficiency of the photosynthetic apparatus.
The uptake rate of N, P, K, Na, Fe, Mn, and Zn in Jojoba was significantly reduced at low temperatures. While, in cucumber, uptake of N, P, K, Ca, and Mg was increased when the temperature was raised in a closed hydroponic system from 12 to 20属C. But too high temperature in the root zone is one of the most significant limiting factors for cultivation in tropical hydroponics. In tropical environments where temperature is usually higher, instead of cooling the entire greenhouse air, the root zone cooling system could be an energy-efficient mechanism for hydroponic cultures. Therefore, it is very important to study the optimum nutrient temperature requirements for different crops grown in climates with adverse winter and summer conditions.
Dissolved oxygen levels in nutrient solution In hydroponic culture availability of enough dissolved O2 is crucial for plant health. Oxygen availability to roots grown in soilless culture can become limiting in case O2 demand exceeds O2 supply, inducing a reduction in root growth rate, ion, and water uptake, eventually reducing plant production. Plants grown in hydroponic systems under high temperatures can quickly deplete the dissolved O2 in the nutrient solution resulting in poor root aeration. The sensitivity of roots to low O2 concentration depends on its effect on mitochondrial respiration because it supplies most of the energy required for root function. Reduction in O2 levels in the nutrient solution could lead to poor roots, an increase the incidences of diseases and pests attacks, and a reduction in plant growth. As high oxygen around a plants roots affects the beneficial microorganisms that provide protection from pathogens and improve nutrient uptake.
Dissolved O2 concentration, is strongly dependent on: i) solution temperature ii) flow rate near the root zone, iii) on the growth rate of the crop, and iv) by the bacterial community present in the solution. The temperature has a direct relationship to the amount of oxygen consumed by the plant. The consumption of O2 increases when the temperature of the nutrient solution increases. Consequently, it produces an increase in the relative concentration of CO2 in the root environment if the root aeration is not adequate. For overcoming the limited oxygen exchange between the atmosphere and the nutrient solution in deep water culture hydroponics, the nutrient solution is aerated by an air bubbler connecting with the pump to provide adequate root oxygenation. So, it is important to make sure the nutrient solution is properly aerated to maintain enough oxygen for the plant cells found in the root mass since this is crucial to the function of the plants cells and the microbial world.

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Hydroponics Lecture 4 .pptx

  • 2. PH level of the nutrient solution The pH value of the nutrient solution greatly affects plants growth. This is because the nutrients added to the nutrient solution are available for the uptake by the plant are soluble in water only at particular pH levels. The plants require a range of pH values to be maintained to ensure the availability of all the nutrients for uptake by the plants. Nutrient solution pH is typically managed between 5.5 and 6.5, and almost all hydroponically grown crops exhibit normal growth and nutrient uptake at this level. However, the optimum pH for maximum growth differs not only between species, but also between cultivar, climatic conditions, and soil, substrate, or nutrient solution conditions
  • 3. The pH of a hydroponic nutrient solution fluctuates because of the unbalanced anion and cation exchange reaction with roots and there is no buffering capacity in hydroponics. The changes in the pH of a nutrient solution depend on the difference in the magnitude of nutrient uptake by plants, in terms of the balance of anions over cations. When the anions are taken up in higher concentrations than cations, for example, nitrate, the plant excretes OH or HCO3 anions, to balance the electrical charges inside, which which increases the pH of nutrient solution and this process is called physiological alkalinity. Precipitation/dissolution phenomena are often promoted by pH changes and, therefore, pH must be continuously controlled or buffered. Cations may form insoluble hydroxides at alkaline pH or other insoluble precipitates by reacting with other anionic nutrients. PH values above 7 may cause the precipitation of iron, zinc, copper, nickel, and manganese as insoluble hydroxides. Also, at high pH values and high dissolved CO2 concentrations, macronutrients like calcium and magnesium can precipitate as carbonates. At pH above 7, mostly the dissolved phosphorus reacts with calcium forming calcium
  • 4. The reason for the reduction in phosphorus uptake at a high pH level is explained by the reduction in the concentration of H2PO4 , which is the substrate of the proton- coupled phosphate symporter in the plasma membrane, in the pH range of 5.68.5; conversely, a decrease in pH can increase the activity of proton-coupled solute transporters and enhance anion uptake Slightly acidic pH is optimum for hydroponic production because iron, manganese, calcium, and magnesium may form precipitates and become unavailable at pH above 7. In general, stabilizing the pH of a nutrient solution is necessary for optimum crop productivity in hydroponics, and maintaining an adequate nutrient solution.
  • 5. Nutrient solution electrical conductivity It is an easy and accurate method of measuring total salt concentration. In soilless culture, the total salt concentration of a nutrient solution must be considered, and the nutrient solution EC is an indicator of electrolyte concentration of the solution and is related to the number of ions available to plants in the root zone. The EC is a measure of the total salts dissolved in the hydroponic nutrient solution. It is used for monitoring applications of fertilizers. In hydroponic production systems, EC management is one of the most important practices that affects the visual, nutritional, and phytochemical quality of leafy vegetables. However, managing the EC in moderately high levelsby adding major nutrients through stock solutionsis a technique that provides great potential to achieve high quality fresh vegetables.
  • 6. Each plant species has an optimum uptake rate of the nutrient solution; excessively high or low levels of the nutrients in solution have a negative effect on plants. Therefore, it is crucial to determine the suitable EC level of nutrient solutions for growing plants. The optimal EC level range should be from 1.5 to 3.5 dS m1 for most hydroponic crops, but this value varies between crop species, growth stages and environmental conditions. Too low and too high EC would reduce yields, visual quality, phytochemical compounds and poor color and taste, and enhance the negative health effects due to nitrate accumulation. However, too high electrical conductivity in nutrient solution may reduce water absorption by plants and decrease photosynthesis. Higher EC means plants are exposed to salinity stress and high levels of nutrients, which hinders nutrient uptake and induces osmotic stress, ion toxicity and nutrient imbalance which reduces plant yield. e.g. the yield of tomatoes under the hydroponic system increased as EC of the nutrient solution increased from 0 to 3 dS m1 and decreased as the EC increased from 3 to 5 dS m1 due to an increase in water stress.
  • 7. EC of Nutrient Solution Indicator of electrolyte Conc. The No. of ions available for plant uptake It is the measure of the total salts dissolved It helps to monitor the application of fertilizer Plant spp. have an optimum uptake rate of nutrients Too high or low EC reduces plant yield
  • 8. Nutrient solution temperature Temperature of the nutrient solution is considered as one of the most important factors that determines crop yield and quality in hydroponic systems. The temperature of the nutrient solution affects the physiological process in the root, such as the absorption of water and nutrients. The thermal regulation of hydroponic solution can contribute towards improvement in the plant physiological processes. e.g. nutrient and water uptake for plants grown in glasshouses may be positively and adversely affected if the hydroponic solution temperature increases or decreases beyond optimum level. The nutrient solution temperature tends to determine the concentration of nutrients absorbed by the plant, as more nutrients are dissolved at higher temperatures and less at lower temperatures, consequently influencing the efficiency of the photosynthetic apparatus.
  • 9. The uptake rate of N, P, K, Na, Fe, Mn, and Zn in Jojoba was significantly reduced at low temperatures. While, in cucumber, uptake of N, P, K, Ca, and Mg was increased when the temperature was raised in a closed hydroponic system from 12 to 20属C. But too high temperature in the root zone is one of the most significant limiting factors for cultivation in tropical hydroponics. In tropical environments where temperature is usually higher, instead of cooling the entire greenhouse air, the root zone cooling system could be an energy-efficient mechanism for hydroponic cultures. Therefore, it is very important to study the optimum nutrient temperature requirements for different crops grown in climates with adverse winter and summer conditions.
  • 10. Dissolved oxygen levels in nutrient solution In hydroponic culture availability of enough dissolved O2 is crucial for plant health. Oxygen availability to roots grown in soilless culture can become limiting in case O2 demand exceeds O2 supply, inducing a reduction in root growth rate, ion, and water uptake, eventually reducing plant production. Plants grown in hydroponic systems under high temperatures can quickly deplete the dissolved O2 in the nutrient solution resulting in poor root aeration. The sensitivity of roots to low O2 concentration depends on its effect on mitochondrial respiration because it supplies most of the energy required for root function. Reduction in O2 levels in the nutrient solution could lead to poor roots, an increase the incidences of diseases and pests attacks, and a reduction in plant growth. As high oxygen around a plants roots affects the beneficial microorganisms that provide protection from pathogens and improve nutrient uptake.
  • 11. Dissolved O2 concentration, is strongly dependent on: i) solution temperature ii) flow rate near the root zone, iii) on the growth rate of the crop, and iv) by the bacterial community present in the solution. The temperature has a direct relationship to the amount of oxygen consumed by the plant. The consumption of O2 increases when the temperature of the nutrient solution increases. Consequently, it produces an increase in the relative concentration of CO2 in the root environment if the root aeration is not adequate. For overcoming the limited oxygen exchange between the atmosphere and the nutrient solution in deep water culture hydroponics, the nutrient solution is aerated by an air bubbler connecting with the pump to provide adequate root oxygenation. So, it is important to make sure the nutrient solution is properly aerated to maintain enough oxygen for the plant cells found in the root mass since this is crucial to the function of the plants cells and the microbial world.