Approximately 90 to 100 Pg of carbon moves back and forth between the atmosphere and the oceans, and between the atmosphere and the land biosphere. Although these exchange rates are large relative to the total amount of carbon stored in the atmosphere, the concentration of CO 2 was constant
Marine plants and animals play a role in the uptake and release of carbon dioxide in the ocean. Plants, primarily phytoplankton but also macrophytes such as this seaweed, take up carbon dioxide and release oxygen, which oxygen-dependent animals need to survive.
Marine plants and animals play a role in the uptake and release of carbon dioxide in the ocean. Plants, primarily phytoplankton but also macrophytes such as this seaweed, take up carbon dioxide and release oxygen, which oxygen-dependent animals need to survive.
at 280 parts per million (ppm) by volume for at least 1,000 years prior to the industrial era. Atmospheric concentrations of CO 2 were constant because the carbon being removed from the atmosphere in some places exactly matched the CO 2 being added to the atmosphere in other places.
Today, CO 2 concentrations in the atmosphere are increasing as a direct result of human activities such as deforestation and the burning of fossil fuels (e.g., coal and oil). Over the past 150 years, CO 2 concentrations in the atmosphere have increased by as much as 30 percent (from 280 to 370 ppm).
All trees, nearly all plants from cold climates, and most agricultural crops respond to increasing atmospheric CO 2 levels by increasing the amount of CO 2 they take up for photosynthesis . It is believed that the increased uptake in land plants from rising atmospheric CO 2 levels roughly counterbalanced the CO 2 released from cutting down tropical rain forests and other agricultural practices in the decade of the 1980s. In the 1990s, the land biosphere was estimated to take up approximately 1 Pg more CO 2 than it released each year.
Most of the CO 2 released from the burning of fossil fuels and other human activities (e.g., cement manufacturing) is stored either in the atmosphere or in the oceans. The CO 2 that remains in the atmosphere acts as a greenhouse gas, absorbing long-wavelength radiation (heat) in the atmosphere. CO 2 taken up by the oceans does not affect the Earth's heat balance, so an understanding of the air-sea exchange of CO 2 is an essential part of understanding the Earth's climate system and the potential impact of future CO 2 emissions.
Phototropism benefits plants by allowing them to grow towards a light source, maximizing their exposure to sunlight for photosynthesis.
Phototropism is light-induced plant growth. It helps plants adapt in several ways. First, phototropism helps plants maximise sunshine exposure, which is essential for photosynthesis. Plants can maximise light absorption and photosynthetic efficiency by bending or growing towards light.
Phototropism aids plant light competition. Plants compete for light in dense vegetation or woods. Plants can maximise sunlight and minimise shadowing from neighbouring plants by growing towards light.
Phototropism helps plants maximise light energy use, growth, and survival in their ecological niche.
Learn more about Phototropism, here:
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c. hydrogen
b. nitrogen
d. all of the above are in the atmosphere
Answer:
The answer would be C. hydrogen
Explanation:
There is basically no hydrogen in the atmosphere as it barely makes up 0.0001 % of the atmosphere
Hope this helps ;) and if it does i would appreciate for this to be the brainliest answer =).
Whats the answer to this?
Answer:
Polymerase chain reaction is a method widely used to rapidly make millions to billions of copies of a specific DNA sample, allowing scientists to take a very small sample of DNA and amplify it to a large enough amount to study in detail.
Explanation:
that's the answer