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Chemistry-

General

Easy

Question

The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

Relation between $T subscript 1 end subscript$ and $T subscript 2 end subscript$ is:

$T_{1} = T_{2}$
$T_{1} > T_{2}$
$T_{1} < T_{2}$
cannot be predicted

The correct answer is: cannot be predicted

Related Questions to study

The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

The point Q refers to:

The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

The point Q refers to:

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The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

The shaded area represents:

The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

The shaded area represents:

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.The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

In the above graph the point 'P' refers to:

.The gas molecules randomly move in all directions and collide with each other and with the wall of the container. It is difficult to determine the speed of an individual molecule but it has become possible to work out the distribution of molecules among different molecular speeds. This is known as Maxwell Boltzmann distribution. Consider the following graph about Maxwell's distribution of speeds at two different temperatures $T subscript 1 end subscript$ and $T subscript 2 end subscript$ :

In the above graph the point 'P' refers to:

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