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∙ 9y agoAt sea level, the atmospheric pressure is higher, which compresses the air and allows more oxygen molecules to be present in each breath. As you go higher in the atmosphere, the air pressure decreases, reducing the density of oxygen and making it harder to breathe in enough oxygen with each breath.
When higher energy ultraviolet radiations act on oxygen at higher levels of the atmosphere, they can break apart oxygen molecules (O2) into two individual oxygen atoms. These oxygen atoms can then combine with other oxygen molecules to form ozone (O3) through a series of reactions. This process is important for the formation of the ozone layer, which helps protect Earth from harmful UV radiation.
As altitude increases, air pressure decreases due to the decrease in the density of air molecules. This decrease leads to a decrease in the amount of oxygen available in the air. At higher altitudes, less oxygen is available for breathing, which can lead to symptoms like dizziness, shortness of breath, and fatigue.
At 10,000 feet altitude, the percentage of oxygen in the atmosphere remains the same as at sea level, which is about 21%. However, the partial pressure of oxygen decreases at higher altitudes, leading to lower oxygen levels available for breathing.
At higher altitudes, the air pressure decreases, leading to lower oxygen levels in the atmosphere. This reduction in oxygen can cause hypoxia, a condition where the body doesn't receive enough oxygen to function properly. As a result, individuals may experience altitude sickness symptoms like shortness of breath, fatigue, and dizziness.
Oxygen in the Earth's atmosphere exists as O2 molecules, while oxygen in rocks and minerals is typically bound to other elements in compounds such as oxides and silicates. Atmospheric oxygen is readily available for organisms to use in respiration, while oxygen in rocks is not easily accessible and requires chemical processes to release it. Additionally, the abundance of oxygen in the atmosphere is much higher compared to oxygen in rocks and minerals.
At higher elevations, the air pressure is lower, which means there is less oxygen available per breath. This can lead to lower oxygen levels in the blood, making it harder for the body to supply enough oxygen to tissues and organs, resulting in shortness of breath. The body may also compensate by increasing the respiratory rate to try to get more oxygen.
Because - the higher up the atmosphere you go - the less oxygen is in the air you breathe. Our bodies need a certain percentage of the air we breathe to be Oxygen - reduce the amount of oxygen in each breath, and it soon affects the body.
At higher altitudes, the air pressure is lower, resulting in less oxygen available per breath. This makes it harder for your body to get the oxygen it needs, leading to shortness of breath as your respiratory system works harder to compensate. Over time, your body can acclimate to the lower oxygen levels at higher altitudes.
We dont, we breath nitrogen and oxygen...but only the oxygen gets used by our bodies.
the environment which has the availability of oxygen it is called aerobic atmosphere and if the availability of oxygen is not there in atmosphere then it is anaerobic type We live in a aerobic atmosphere which has the oxygen available
As altitude increases, the air pressure decreases, which means there are fewer oxygen molecules available per breath. The decreased oxygen levels make it harder for the body to efficiently take in oxygen, leading to difficulty in breathing at higher altitudes.
protect the earth and havee oxygen to human breath
Earths atmosphere is mostly nitrogen (78%) and Oxygen (21%).It is the oxygen that is the essential gas for breathing.
When higher energy ultraviolet radiations act on oxygen at higher levels of the atmosphere, they can break apart oxygen molecules (O2) into two individual oxygen atoms. These oxygen atoms can then combine with other oxygen molecules to form ozone (O3) through a series of reactions. This process is important for the formation of the ozone layer, which helps protect Earth from harmful UV radiation.
As altitude increases, air pressure decreases due to the decrease in the density of air molecules. This decrease leads to a decrease in the amount of oxygen available in the air. At higher altitudes, less oxygen is available for breathing, which can lead to symptoms like dizziness, shortness of breath, and fatigue.
At 10,000 feet altitude, the percentage of oxygen in the atmosphere remains the same as at sea level, which is about 21%. However, the partial pressure of oxygen decreases at higher altitudes, leading to lower oxygen levels available for breathing.
Breathing is more difficult at high altitudes because the air is thinner, which means there is less oxygen available per breath. This can lead to altitude sickness in some individuals, as the body needs time to acclimate to the lower oxygen levels. The reduced air pressure at higher altitudes can also make it harder for the lungs to expand and take in an adequate amount of oxygen.