I would think so. Oxygen is lighter than CO2. The solubility of CO2 is also higher than O2 in water, so there can be more of it in the water.
Check out the related link to learn more about measuring changes in O2 or CO2 and metabloc rates.
plants maintain balance of co2 and o2 in the atmosphere..
Since photosynthesis requires the carbon from CO2 and its not getting it, the entire process could come to a halt. This would usually occur in hot and dry conditions, where in higher temperatures, the enzyme has a higher affinity for binding to O2 than CO2.
This reaction is:2 CO2 = 2 CO + O2
When ther is a higher concentration of O2 than CO2, rubisco can bind O2 in place of CO2.
CO2
There is more Carbon Dioxide (CO2) when we breathe outbecause some of the Oxygen (O2) is absorbed into the blood via the lungs, and CO2 is removed from the blood, into the lungs. (O2 converts to CO2 in the body)However, this is only a small change so we still breathe out Oxygen: (which is why CPR works)Breathing In: 21% O2, 0.04% CO2Breathing Out: 17% O2, 4% CO2 (about 4% change in both)
O2 and Co2, but we breathe out the Co2 again + the O2 which is converted in more Co2
I would think so. Oxygen is lighter than CO2. The solubility of CO2 is also higher than O2 in water, so there can be more of it in the water.
O2 and CO2 are gases at rtp. As all gases and liquids are fluids, O2 and CO2 are considered fluids.
A compund ALWAYS consists of more than one element. O2 is not a compound CO2 is a compound.
Check out the related link to learn more about measuring changes in O2 or CO2 and metabloc rates.
trees convert CO2 to O2. CO2 is the cause of the warming The less trees there are to convert CO2, the more CO2 there will be
CO2 and N2O are related because they are both gases that have greater density than that of O2
plants maintain balance of co2 and o2 in the atmosphere..
Since photosynthesis requires the carbon from CO2 and its not getting it, the entire process could come to a halt. This would usually occur in hot and dry conditions, where in higher temperatures, the enzyme has a higher affinity for binding to O2 than CO2.