Bacteria
Nitrogen-fixing bacteria, such as Rhizobium and Azotobacter, are responsible for converting atmospheric nitrogen into nitrates through a process called nitrogen fixation. These bacteria can be found in the soil and form symbiotic relationships with plants to provide them with usable forms of nitrogen.
Nitrogen fixation by certain bacteria in soil converts atmospheric nitrogen into a form usable by plants. Plants take up nitrogen from soil through their roots, incorporating it into their tissues. When plants and animals die, decomposers break down their remains, releasing nitrogen back into the soil. Some nitrogen is also released back into the atmosphere through processes like denitrification.
Nitrogen-fixing bacteria in the soil and root nodules of certain plants, as well as cyanobacteria in water, convert nitrogen gas (N2) into ammonia (NH3) or nitrate (NO3-), which are forms of nitrogen that can be used by plants for growth. This process is known as nitrogen fixation.
Nitrification is important in the nitrogen cycle because it converts ammonia, a form of nitrogen that is not readily usable by plants, into nitrate, which is a form of nitrogen that plants can easily absorb and use for growth. This process helps to replenish the soil with essential nutrients, supporting plant growth and overall ecosystem health.
Photosynthesis is not a pathway by which plants obtain nitrogen in a usable form. Plants use nitrogen from the soil in the form of nitrate or ammonium through processes like nitrogen fixation by bacteria, absorption by roots, and uptake through mycorrhizal fungi.
Nitrogen-fixing bacteria, such as Rhizobium and Azotobacter, are responsible for converting atmospheric nitrogen into nitrates through a process called nitrogen fixation. These bacteria can be found in the soil and form symbiotic relationships with plants to provide them with usable forms of nitrogen.
Nitrogen-fixing bacteria, such as Rhizobium and Azotobacter, are needed to convert atmospheric nitrogen into a usable form like ammonia that plants can absorb. These bacteria form symbiotic relationships with plants or live freely in the soil.
The most usable form of nitrogen for plants is nitrate (NO3-).
The organism that converts solar energy into usable chemical energy is a plant through the process of photosynthesis.
Nitrogen fixation by certain bacteria in soil converts atmospheric nitrogen into a form usable by plants. Plants take up nitrogen from soil through their roots, incorporating it into their tissues. When plants and animals die, decomposers break down their remains, releasing nitrogen back into the soil. Some nitrogen is also released back into the atmosphere through processes like denitrification.
Nitrogen fixing bacteria will enable some plants to convert atmospheric oxygen to a form that can be used by plants. The plants are then eaten by animals.
Thyere is a process. We use habor process for that.
Nitrogen-fixing bacteria are needed to convert atmospheric nitrogen into a usable form for plants. These bacteria form symbiotic relationships with certain plants, like legumes, to provide them with a source of nitrogen for growth and development.
Nitrogen-fixing bacteria in the soil and root nodules of certain plants, as well as cyanobacteria in water, convert nitrogen gas (N2) into ammonia (NH3) or nitrate (NO3-), which are forms of nitrogen that can be used by plants for growth. This process is known as nitrogen fixation.
Nitrogen gas in the air is converted into usable forms by soil bacteria through a process called nitrogen fixation. Plants then take up these forms of nitrogen from the soil. When organisms consume plants, they obtain nitrogen from the plants, and the nitrogen cycles through the food chain as organisms are consumed by other organisms.
nitrogen fixing bacteria
Nitrification is important in the nitrogen cycle because it converts ammonia, a form of nitrogen that is not readily usable by plants, into nitrate, which is a form of nitrogen that plants can easily absorb and use for growth. This process helps to replenish the soil with essential nutrients, supporting plant growth and overall ecosystem health.