You could increase its volume or cool it or both.
The volume of the gas would decrease by half as well according to Charles's Law, which states that the volume of a gas is directly proportional to its Kelvin temperature when pressure is constant. If the Kelvin temperature is reduced to half its original value, the volume of the gas will also be reduced by half.
If the volume of a gas is tripled at constant temperature, according to Boyle's Law, the pressure of the gas will decrease by a factor of 3. This is because pressure and volume are inversely proportional at constant temperature.
In a water pressure-volume diagram, the relationship between pressure and volume is inversely proportional. This means that as the volume of water decreases, the pressure increases, and vice versa.
An ideal gas will have a volume that is inversely proportional to the pressure (assuming constant temperature). For example, if you double the pressure, the volume will be reduced to 1/2 the original volume. For real gases, the behavior is usually somewhat different. In some cases, if you double the pressure, the volume will reduce to LESS than 1/2 the original volume. This is due to the attraction between the molecules, and this phenomenon is called "supercompressibility".
No, pressure and volume are inversely proportional. This means that as pressure increases, volume decreases, and vice versa.
If the pressure is doubled according to the ideal gas equation (PV = nRT), and the other variables remain constant, then the volume would be halved. This is because pressure and volume are inversely proportional when the other variables are constant in an ideal gas.
Assuming it's a bag of gas at constant temperature, four times the volume by the relationship: P1V1 = P2V2
If the volume of the container is reduced to one-half of its original size, the pressure will increase proportionally according to Boyle's Law. So if the original pressure was 10 psi, then the new pressure would be 20 psi when the volume is reduced by half.
This problem can be solved with the ideal gas law. The original pressure and volume of the container are proportional the final pressure and volume of the container. The original pressure was 1 atmosphere and the original volume was 1 liter. If the final volume is 1.8 liters, then the final pressure is 0.55 atmospheres.
The pressure is reduced to one third of the original pressure. The pressure will stay the same you are only changing the volume
When the mixture is placed in a container half the volume of the original container, the total pressure increases by a factor of two due to Boyle's Law, which states that pressure and volume are inversely proportional as long as temperature is constant. So, the total pressure of the mixture in the smaller container will be double the pressure of the mixture in the original container.
To increase the volume of a gas * reduce the pressure, or * increase the temperature, or * add more gas
The volume of the gas would decrease by half as well according to Charles's Law, which states that the volume of a gas is directly proportional to its Kelvin temperature when pressure is constant. If the Kelvin temperature is reduced to half its original value, the volume of the gas will also be reduced by half.
BOYLES LAW The relationship between volume and pressure. Remember that the law assumes the temperature to be constant. or V1 = original volume V2 = new volume P1 = original pressure P2 = new pressure CHARLES LAW The relationship between temperature and volume. Remember that the law assumes that the pressure remains constant. V1 = original volume T1 = original absolute temperature V2 = new volume T2 = new absolute temperature P1 = Initial Pressure V1= Initial Volume T1= Initial Temperature P2= Final Pressure V2= Final Volume T2= Final Temperature IDEAL GAS LAW P1 = Initial Pressure V1= Initial Volume T1= Initial Temperature P2= Final Pressure V2= Final Volume T2= Final Temperature Answer BOYLES LAW The relationship between volume and pressure. Remember that the law assumes the temperature to be constant. or V1 = original volume V2 = new volume P1 = original pressure P2 = new pressure CHARLES LAW The relationship between temperature and volume. Remember that the law assumes that the pressure remains constant. V1 = original volume T1 = original absolute temperature V2 = new volume T2 = new absolute temperature P1 = Initial Pressure V1= Initial Volume T1= Initial Temperature P2= Final Pressure V2= Final Volume T2= Final Temperature IDEAL GAS LAW P1 = Initial Pressure V1= Initial Volume T1= Initial Temperature P2= Final Pressure V2= Final Volume T2= Final Temperature
The pressure of the gas will decrease by a factor of four when the volume is expanded to four times its original volume at a constant temperature, according to Boyle's Law.
If you let it expand until the new pressure is the same as the original pressure, then the volume will be doubled. But if you want, you could restrict it to stay in the same volume as before. It could do that, but the pressure would double.
If the pressure on a gas increases fourfold, its volume will decrease proportionally. This relationship is described by Boyle's Law, which states that pressure and volume are inversely proportional at constant temperature.