If the pressure of a gas is doubled, then the average kinetic energy per unit volume of the gas will be:
| 1. | half of its initial value. | 2. | double its initial value. |
| 3. | one-fourth of its initial value. | 4. | four times its initial value. |
Maxwell's speed distribution graph is drawn as shown below. The most probable speed of the gas molecules is:
1. 4 km/s
2. Between 3 km/s and 1 km/s
3. Any value between 2 km/s and 6 km/s
4. More than 4 km/s
If at a pressure of \(10^6\) dyne/cm2, one gram of nitrogen occupies \(2\times10^4\) c.c. volume, then the average energy of a nitrogen molecule in erg is:
| 1. | \(14\times10^{-13}\) | 2. | \(10\times10^{-12}\) |
| 3. | \(10^{6}\) | 4. | \(2\times10^{6}\) |
The translational kinetic energy of \(n\) moles of a diatomic gas at absolute temperature \(T\) is given by:
1. \(\frac{5}{2}nRT\)
2. \(\frac{3}{2}nRT\)
3. \(5nRT\)
4. \(\frac{7}{2}nRT\)
Two isotherms are drawn at temperatures as shown. The ratio of mean speed at is:
| 1. | 1: 4 | 2. | 1: 2 |
| 3. | 2: 1 | 4. | 4: 1 |
The translational kinetic energy of oxygen molecules at room temperature is \(60~\text J.\) Their rotational kinetic energy will be?
1. \(40~\text J\)
2. \(60~\text J\)
3. \(50~\text J\)
4. \(20~\text J\)
When the gas in an open container is heated, the mean free path:
1. Increases
2. Decreases
3. Remains the same
4. Any of the above depending on the molar mass
The change in the internal energy of an ideal gas does not depend on?
| 1. | Number of moles |
| 2. | Change in temperature |
| 3. | Specific heat at constant pressure \(C_p\) of the gas |
| 4. | Specific heat at constant volume \(C_v\) of the gas |
The figure shows a process for a gas in which pressure (P) and volume (V) of the gas change. If and are the molar heat capacities of the gas during the processes AB and BC respectively, then:
1.
2.
3.
4.
In the PV graph shown below for an ideal diatomic gas, the change in the internal energy is:
1.
2.
3.
4.