That depends on the kind of plant. There are two major types:1. Tidal turbines
2. tidal barrages
1. Tidal turbines are like wind-turbines but underwater. They need a current speed of at least 1m/s to start producing energy but current models are not economically viable for anything below 2m/s
2. Tidal barrages are like dams across a bay or an estuary. Theyutilizethe difference in water level between high and low tide. They open their gates as the tide comes in to allow the water to collect behind the dam. at the highest point of the tide the gates close until low tide is reached. the water is then release via turbines until the water level behind the dam is equal to the sea level. When the tide comes in again the cycle repeats. These kind of tidal plants need a difference between high and low tide of at least 5-7 meters although the bigger the difference the better.
To calculate the minimum amount of energy required for a plant to produce 15.0 g of glucose (C6H12O6) through photosynthesis, we first need to know the energy associated with glucose formation. The process of photosynthesis requires approximately 2870 kJ of energy to synthesize 1 mole of glucose. Since 15.0 g of glucose corresponds to about 0.083 moles (using the molar mass of glucose, 180 g/mol), the minimum energy absorbed would be around 240 kJ (0.083 moles × 2870 kJ/mole).
Chloroplast in a plant cell can convert light energy into chemical energy that is required in plant cells.
In order for a plant to begin photosynthesis, it needs energy from the sun, water and nutrients from the soil
An elementary-level answer would be : chemical and light energy Light energy from the sun Chemical from the plant itself. light would be when the sun gives its light to help the plant grow like a light bulb, and chemical is like the plant taking the water, and soil and using it and the plant itself is chemical
The compensation point is the specific light intensity at which the rate of photosynthesis equals the rate of respiration in plants. At this point, there is no net exchange of oxygen; the amount produced through photosynthesis is balanced by the amount consumed during respiration. This concept is crucial for understanding plant growth and survival in various lighting conditions, as it indicates the minimum light required for a plant to maintain its energy balance.
The minimum CO2 level required for optimal plant growth is around 150 parts per million (ppm).
To calculate the minimum amount of energy required for a plant to produce 15.0 g of glucose (C6H12O6) through photosynthesis, we first need to know the energy associated with glucose formation. The process of photosynthesis requires approximately 2870 kJ of energy to synthesize 1 mole of glucose. Since 15.0 g of glucose corresponds to about 0.083 moles (using the molar mass of glucose, 180 g/mol), the minimum energy absorbed would be around 240 kJ (0.083 moles × 2870 kJ/mole).
The energy from earth is required. This energy is used to create electricity.
The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.
In general, as with most scientific fields, the individual position will bring with it different requirements. However, for the most part you should assume that a four year degree in plant biotechnology will be required as the absolute minimum.
Chloroplast in a plant cell can convert light energy into chemical energy that is required in plant cells.
The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.The meaning is that, when you raise an object, due to its position it will have a kind of energy stored; this can be converted into other kinds of energy when it falls down. A practical example is water in a hydroelectric plant - when it falls down, electricity is generated.
The best type of power plant to generate the most clean energy at a low cost would probably be wind and power energy. However, the issue of space would eventually come into play as it is not the most practical.
Chlorophyll is a pigment found in plant cells that plays a crucial role in photosynthesis. It absorbs light energy from the sun and converts it into chemical energy that is used by the plant to produce glucose and oxygen. This process is vital for the plant's growth and survival.
In order for a plant to begin photosynthesis, it needs energy from the sun, water and nutrients from the soil
An elementary-level answer would be : chemical and light energy Light energy from the sun Chemical from the plant itself. light would be when the sun gives its light to help the plant grow like a light bulb, and chemical is like the plant taking the water, and soil and using it and the plant itself is chemical
hydro power plant