Question:
A flat plate is moving normal to its plane through a gas under the action of a constant force $F$. The gas is kept at a very low pressure. The speed of the plate $v$ is much less than the average speed $u$ of the gas molecules. Which of the following options is/are true?
A flat plate is moving normal to its plane through a gas under the action of a constant force $F$. The gas is kept at a very low pressure. The speed of the plate $v$ is much less than the average speed $u$ of the gas molecules. Which of the following options is/are true?
Updated On: Jun 14, 2022
- The pressure difference between the leading and trailing faces of the plate is proportional to $uv$
- The resistive force experienced by the plate is proportional to $v$
- The plate will continue to move with constant non-zero acceleration, at all times
- At a later time the external force $F$ balances the resistive force
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The Correct Option is D
Solution and Explanation
Consider area $A$ of the plate moving towards right (see figure). In next dt time, only those particles of the gas can collide with the plate (on its right face) as are within $( v + u ) dt$ distance from it. Number of these particles $= n ( u + y )$ dt $A$, where $n$ is number of gas particles per unit volume. Only half of these particles will collide with the plate, the other half will be moving away from it.
$\therefore$ Number of particles, colliding with the plate from right, in dt time $=\frac{1}{2} n(u+v)$ dt $A$ Upon collision each particle (of mass $m$ ) imparts momentum of $2 m ( u + v )$ to the plate towards left, as they are moving with a velocity $u+v$ relative to the plate.
The force applied on the right face of the plate by the collisions $=\frac{\text { momentum imparted }}{\text { time }}$
$=\frac{\left[\frac{1}{2} n(u+v) d t A\right][2 m(u+v)]}{d t}=m n A(u+v)^{2}$
$\therefore$ Pressure on the right face of plate $=\frac{\text { Force }}{\text { Area }}=\frac{m n A(u+v)^{2}}{A}=m n(u+v)^{2}$
Similarly, pressure on its left plate $= mn ( u - v )^{2}$ [The particles on the left, move in with a velocity u-v relative to the plate].
And, the difference of pressure $=m n\left[(u+v)^{2}-(u-v)^{2}\right]=4\, mn\, uv\, \propto$ uv With passage of time, $v$ will increase (or decrease) such that the resistive force (due to this pressure difference) balances $F$ : Also, the resistive force is proportional to v
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Concepts Used:
Kinetic Molecular Theory of Gases
Postulates of Kinetic Theory of Gases:
- Gases consist of particles in constant, random motion. They continue in a straight line until they collide with each other or the walls of their container.
- Particles are point masses with no volume. The particles are so small compared to the space between them, that we do not consider their size in ideal gases.
- Gas pressure is due to the molecules colliding with the walls of the container. All of these collisions are perfectly elastic, meaning that there is no change in energy of either the particles or the wall upon collision. No energy is lost or gained from collisions. The time it takes to collide is negligible compared with the time between collisions.
- The kinetic energy of a gas is a measure of its Kelvin temperature. Individual gas molecules have different speeds, but the temperature and
kinetic energy of the gas refer to the average of these speeds. - The average kinetic energy of a gas particle is directly proportional to the temperature. An increase in temperature increases the speed in which the gas molecules move.
- All gases at a given temperature have the same average kinetic energy.
- Lighter gas molecules move faster than heavier molecules.
