NEET Test Series from KOTA - 10 Papers In MS WORD
WhatsApp Here
PHXI13:KINETIC THEORY
360355
One mole of ideal monoatomic gas \((\gamma=5 / 3)\) is mixed with one mole of diatomic gas \((\gamma=7 / 5)\). What is \(\gamma\) for the mixture? \(\gamma\) denotes the ratio of specific heat at constant pressure, to that at constant volume
360356
A diatomic gas molecule has translational, rotational and vibrational degrees of freedom. Then \(\dfrac{C_{P}}{C_{V}}\) is
1 1.67
2 1.4
3 1.33
4 1.29
Explanation:
For a diatomic gas having translational, rotational and vibrational degrees of freedom. \(C_{V}=\dfrac{7 R}{2}, C_{P}=\dfrac{9 R}{2} \Rightarrow \dfrac{C_{P}}{C_{V}}=\dfrac{9}{7}=1.29\)
PHXI13:KINETIC THEORY
360357
The molar specific heat relation for ideal gas is
1 \(C_{P}+C_{V}=R\)
2 \(C_{P}-C_{V}=R\)
3 \(C_{P} / C_{V}=R\)
4 \(C_{V} / C_{P}=R\)
Explanation:
\(C_{P}-C_{V}=R=\) Universal gas constant
PHXI13:KINETIC THEORY
360358
If \(C_{P}\) and \(C_{V}\) denote the specific heats of oxygen per unit mass at constant pressure and constant volume respectively. then
1 \(C_{P}-C_{V}=R / 16\)
2 \(C_{P}-C_{V}=R / 32\)
3 \(C_{P}-C_{V}=R\)
4 \(C_{P}-C_{V}=32 R\)
Explanation:
\(C_{P}-C_{V}=\dfrac{R}{M}\) Where \(C_{P} \& C_{V}\) are specific heat capacities. \(M\) is the molecular weight, \(M=32\) for oxygen gas
360355
One mole of ideal monoatomic gas \((\gamma=5 / 3)\) is mixed with one mole of diatomic gas \((\gamma=7 / 5)\). What is \(\gamma\) for the mixture? \(\gamma\) denotes the ratio of specific heat at constant pressure, to that at constant volume
360356
A diatomic gas molecule has translational, rotational and vibrational degrees of freedom. Then \(\dfrac{C_{P}}{C_{V}}\) is
1 1.67
2 1.4
3 1.33
4 1.29
Explanation:
For a diatomic gas having translational, rotational and vibrational degrees of freedom. \(C_{V}=\dfrac{7 R}{2}, C_{P}=\dfrac{9 R}{2} \Rightarrow \dfrac{C_{P}}{C_{V}}=\dfrac{9}{7}=1.29\)
PHXI13:KINETIC THEORY
360357
The molar specific heat relation for ideal gas is
1 \(C_{P}+C_{V}=R\)
2 \(C_{P}-C_{V}=R\)
3 \(C_{P} / C_{V}=R\)
4 \(C_{V} / C_{P}=R\)
Explanation:
\(C_{P}-C_{V}=R=\) Universal gas constant
PHXI13:KINETIC THEORY
360358
If \(C_{P}\) and \(C_{V}\) denote the specific heats of oxygen per unit mass at constant pressure and constant volume respectively. then
1 \(C_{P}-C_{V}=R / 16\)
2 \(C_{P}-C_{V}=R / 32\)
3 \(C_{P}-C_{V}=R\)
4 \(C_{P}-C_{V}=32 R\)
Explanation:
\(C_{P}-C_{V}=\dfrac{R}{M}\) Where \(C_{P} \& C_{V}\) are specific heat capacities. \(M\) is the molecular weight, \(M=32\) for oxygen gas
360355
One mole of ideal monoatomic gas \((\gamma=5 / 3)\) is mixed with one mole of diatomic gas \((\gamma=7 / 5)\). What is \(\gamma\) for the mixture? \(\gamma\) denotes the ratio of specific heat at constant pressure, to that at constant volume
360356
A diatomic gas molecule has translational, rotational and vibrational degrees of freedom. Then \(\dfrac{C_{P}}{C_{V}}\) is
1 1.67
2 1.4
3 1.33
4 1.29
Explanation:
For a diatomic gas having translational, rotational and vibrational degrees of freedom. \(C_{V}=\dfrac{7 R}{2}, C_{P}=\dfrac{9 R}{2} \Rightarrow \dfrac{C_{P}}{C_{V}}=\dfrac{9}{7}=1.29\)
PHXI13:KINETIC THEORY
360357
The molar specific heat relation for ideal gas is
1 \(C_{P}+C_{V}=R\)
2 \(C_{P}-C_{V}=R\)
3 \(C_{P} / C_{V}=R\)
4 \(C_{V} / C_{P}=R\)
Explanation:
\(C_{P}-C_{V}=R=\) Universal gas constant
PHXI13:KINETIC THEORY
360358
If \(C_{P}\) and \(C_{V}\) denote the specific heats of oxygen per unit mass at constant pressure and constant volume respectively. then
1 \(C_{P}-C_{V}=R / 16\)
2 \(C_{P}-C_{V}=R / 32\)
3 \(C_{P}-C_{V}=R\)
4 \(C_{P}-C_{V}=32 R\)
Explanation:
\(C_{P}-C_{V}=\dfrac{R}{M}\) Where \(C_{P} \& C_{V}\) are specific heat capacities. \(M\) is the molecular weight, \(M=32\) for oxygen gas
NEET Test Series from KOTA - 10 Papers In MS WORD
WhatsApp Here
PHXI13:KINETIC THEORY
360355
One mole of ideal monoatomic gas \((\gamma=5 / 3)\) is mixed with one mole of diatomic gas \((\gamma=7 / 5)\). What is \(\gamma\) for the mixture? \(\gamma\) denotes the ratio of specific heat at constant pressure, to that at constant volume
360356
A diatomic gas molecule has translational, rotational and vibrational degrees of freedom. Then \(\dfrac{C_{P}}{C_{V}}\) is
1 1.67
2 1.4
3 1.33
4 1.29
Explanation:
For a diatomic gas having translational, rotational and vibrational degrees of freedom. \(C_{V}=\dfrac{7 R}{2}, C_{P}=\dfrac{9 R}{2} \Rightarrow \dfrac{C_{P}}{C_{V}}=\dfrac{9}{7}=1.29\)
PHXI13:KINETIC THEORY
360357
The molar specific heat relation for ideal gas is
1 \(C_{P}+C_{V}=R\)
2 \(C_{P}-C_{V}=R\)
3 \(C_{P} / C_{V}=R\)
4 \(C_{V} / C_{P}=R\)
Explanation:
\(C_{P}-C_{V}=R=\) Universal gas constant
PHXI13:KINETIC THEORY
360358
If \(C_{P}\) and \(C_{V}\) denote the specific heats of oxygen per unit mass at constant pressure and constant volume respectively. then
1 \(C_{P}-C_{V}=R / 16\)
2 \(C_{P}-C_{V}=R / 32\)
3 \(C_{P}-C_{V}=R\)
4 \(C_{P}-C_{V}=32 R\)
Explanation:
\(C_{P}-C_{V}=\dfrac{R}{M}\) Where \(C_{P} \& C_{V}\) are specific heat capacities. \(M\) is the molecular weight, \(M=32\) for oxygen gas