Answer:
P_2 = 1.62 atm
Explanation:
We know the formula for the rms speed of the ideal gas is given by
[tex]v_{rsm}=\sqrt{\frac{3PV}{m} }[/tex]
P= pressure of the surrounding
V= volume of the vessel
m= mass of the gas
Now, From this formula rms speed (v_rms) is directly proportional to square root is pressure.
Then
[tex]\frac{v_{rsm,1}}{v_{rsm,2}} =\sqrt{\frac{P_1}{P_2} }[/tex]
given that v_rsm,1= v0
and v_rsm,2=0.9v0
putting these values we get
[tex]\frac{v0}{0.9v0} =\sqrt{\frac{2}{P_2} }[/tex]
P_2 = 1.62 atm
Answer:
The pressure of the gas is 1.8 atm.
Explanation:
Given that,
Pressure of ideal gas= 2.0 atm
rms speed of the molecule = v₀
Reduced rms speed = 0.90 v₀
We know the formula of rms speed of the ideal gas
[tex]v_{rms}=\sqrt{\dfrac{3Pv}{m}}[/tex]
From this formula rms speed is directly proportional to square root is pressure.
We need to calculate the pressure of the gas
Using formula of rms speed
[tex]\dfrac{v_{rms}}{v_{rms}}=\sqrt{\dfrac{P_{1}}{P_{2}}}[/tex]
Put the value into the formula
[tex]\dfrac{v_{0}}{0.90v_{0}}=\sqrt{\dfrac{2.0}{P_{2}}}[/tex]
[tex]P_{2}=2.0\times0.90[/tex]
[tex]P_{2}=1.8\ atm[/tex]
Hence, The pressure of the gas is 1.8 atm.
