Calculating Oxygen Volume in Hospital Tanks Using Ideal Gas Law

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Oxygen in hospital tanks is stored at 65.0 atm and 288 K, and is administered at 1.00 atm and 297 K. To find the volume of oxygen in the patient's room, the ideal gas law can be applied without calculating the number of moles, as it remains constant. The relationship between the initial and final states can be expressed as (P1V1)/(T1) = (P2V2)/(T2), allowing for direct volume comparison. The calculation should yield a more reasonable volume than the initial 67 m^3 obtained. Understanding that n is constant simplifies the process significantly.
colton4286
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Oxygen for hospital patients is kept in special tanks, where the oxgen has a pressure of 65.0 atm and a temp. of 288 K. The tanks are stored in a separate room, and the oxygen is pumped to the patient's room, where it is administered at a pressure of 1.00 atm and a temp. of 297 K. What volume does 1.00 m^3 of oxygen in the tanks occupy at the conditions in the patient's room?

What I did was solve for the # of mols (n) given the tank information: n= PV/RT and used this n value to solve for volume: V= nRT/P. But I got 67 m^3 which is a much larger number than I expected. Am I heading in the right direction on this problem? Thanks!
 
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That sounds exactly right.
Note that you don't actually have to solve for the number of moles, all you need to know is that it stays constant.

n = PV/RT and n is constant, therefore:
(PV/RT)1 = (PV/RT)2 where 1 and 2 correspond to before and after the pumping, i.e. 1 is at 65 atm 288K and 2 is at 1atm 297K.
Also R is constant, so you can cancel that out.

Cheers
 
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