At the molecular scale, increasing the temperature means that the gas molecules are more energetic and are impacting the walls of the container with more momentum, thus imparting more force to the wall per collision. At the macroscopic scale, the ideal gas law is PV = nRT, which tells us that pressure rises linearly with temperature at constant volume.
Because the pressure increases
The real answer is: Charles's Law. He found that if you increase the temperature of a constant pressure the volume increases also.
At the molecular scale, increasing the temperature means that the gas molecules are more energetic and are impacting the walls of the container with more momentum, thus imparting more force to the wall per collision. At the macroscopic scale, the ideal gas law is PV = nRT, which tells us that pressure rises linearly with temperature at constant volume.
Increasing the temperature of a gas adds energy to the gas. Pressure is energy density or energy per unit volume. Pressure is determined by the energy in a volume.
Pressure is determined by Force/Area, which is the Force a molecule exerts over a certain area. As the energy is added, the molecules move faster and faster(increased velocity) thus the Force exhibited by each molecule also increases, Force is directly proportional to pressure,
Because the pressure increases
The real answer is: Charles's Law. He found that if you increase the temperature of a constant pressure the volume increases also.
If temperature increases, either the volume or the pressure must increase. Since you have limited the volume by closing the container, pressure must increase.
temperature increase The pressure of a contained sample of gas can be increased by increasing its temperature, or by decreasing its volume, or by injecting additional mass into it.
As indicated by the Ideal Gas Laws, increasing temperature will tend to increase both volume and pressure. Of course, volume can't always increase, that depends upon the flexibility or inflexibility of the container that the gas is in, and if the volume does increase that will counteract the increase in pressure that would otherwise have happened. Temperature, pressure, and volume are all interconnected in a gas.
No, because the gas is in a rigid steel container, its volume cannot increase as the temperature increases (assuming the steel does not deform). Instead, the pressure of the gas inside the container will increase. Of course, if the pressure is high enough, the container will explode, lowering the pressure and causing the gas to expand.
decreasing the volume available for the gas or increasing its temperature
-increase the temperature of the super heated steam -lowering the condensing pressure -increasing the boiler pressure (Reheating, regeneration...)
If temperature increases, either the volume or the pressure must increase. Since you have limited the volume by closing the container, pressure must increase.
Any of the following: increasing the amount of gas; increasing the temperature; reducing the volume.
Because the pressure increases The real answer is: Charles's Law. He found that if you increase the temperature of a constant pressure the volume increases also.
temperature increase The pressure of a contained sample of gas can be increased by increasing its temperature, or by decreasing its volume, or by injecting additional mass into it.
Increasing the temperature of a gas will increase it's pressure ONLY if the volume is held constant.
Increasing the amount of a gas increases the temperature and pressure in a container
Increasing the amount of a gas increases the temperature and pressure in a container
by increasing temperature and pressure
The temperature
As indicated by the Ideal Gas Laws, increasing temperature will tend to increase both volume and pressure. Of course, volume can't always increase, that depends upon the flexibility or inflexibility of the container that the gas is in, and if the volume does increase that will counteract the increase in pressure that would otherwise have happened. Temperature, pressure, and volume are all interconnected in a gas.
it would change the pressure exerted by the gas in the container.
On an atomic scale, atoms are constantly vibrating. This vibration along with the electronic orbitals of the atom limit the minimum distance between two atoms. With increase in temperature the amplitude of this vibration increases. This leads to an increase in the minimum distance. This increase in the minimum distance manifests itself as an increase in the volume at a macroscopic scale.