high
You can't compare pressure with volume. Presumably, somebody was talking about something being greater AT constant pressure, compared to constant volume.
The greater the speed of gas particles in a container, the higher the overall average temperature and kinetic energy of the gas particles. And if volume was held constant, higher the pressure.
At a constant temperature, the volume and the pressure are inversely proportional, that it, the greater the volume, the lesser the pressure on the gas, and viceversa.
At a constant temperature, the volume and the pressure are inversely proportional, that it, the greater the volume, the lesser the pressure on the gas, and viceversa.
If pressure is kept constant, the volume will decrease.If volume is kept constant, the pressure will decrease.
The volume is constant. The pressure will increase.The volume is constant. The pressure will increase.
Thermodynamic properties are specific volume, density, pressure, and temperature. Other properties are constant pressure, constant volume specific heats, Gibbs free energy, specific internal energy and enthalpy, and entropy.
One is for constant pressure, the other is for constant volume. These are not the same; for example, if the pressure is maintained constant, and the gas is heated, the volume changes.
Increasing the temperature of a gas will increase it's pressure ONLY if the volume is held constant.
The pressure is now higher.
At constant temperature p.V=constant, so pressure INcreases when decreasing the volume.
If you allow the gas to contract, it will shrink in volume as you cool it and may also drop in pressure if the surroundings will allow it. Changes in pressure and volume can translate to work being done on or by the system. If you keep the volume constant it will only drop in pressure while cooling and no work will occur.