Answer:
[tex]P_2=135.73psi[/tex]
Explanation:
Hello,
In this case we use the Boyle's law which allows us to understand the volume-pressure behavior as an inversely proportional relationship:
[tex]V_1P_1=V_2P_2[/tex]
Whereas we solve for [tex]P_2[/tex] as the required final pressure:
[tex]P_2=\frac{V_1P_1}{V_2} =\frac{27.0L*14.7psi}{3.00L}\\ \\P_2=135.73psi[/tex]
Best regards.
Answer:
The final pressure of the helium would be 132.2 psi or 9.0 atm
Explanation:
Step 1:data given
The original volume of the balloon = 27.0 L
The original pressure = 14.7 psi = 1.00 atm
The volume will be reduced to 3.00 L
Step 2: Calculate the pressure
P1*V1 = P2¨V2
⇒with P1 = The original pressure = 14.7 psi = 1.00 atm
⇒with V1 = The original volume of the balloon = 27.0 L
⇒with P2 = the new pressure = TO BE DETERMINED
⇒with V2 = the reduced volume = 3.00 L
14.7 psi * 27.0 L = P2 * 3.00 L
P2 = (14.7 psi * 27.0 L) / 3.00 L
P2 = 132.3 psi
OR
1 atm * 27.0 L = P2 * 3.00 L
P2 = (27.0 atm*L ) / 3.00 L
P2 = 9.0 atm
The final pressure of the helium would be 132.2 psi or 9.0 atm
