According to Charles law, when pressure is kept constant,the volume of a given mass of gas is directly proportional to the absolute temperature.The given mass of gas starts to rise with the rise in temperature and reduces with reduction in temperature.
it will grow a pare of elephant trunks and fly away back to its native land of Moscow Australia.
Higher temperature means faster moving particles. Faster moving particles have more energetic collisions with the walls of the container, hence, they exert more pressure.
When the temperature of a gas increases, the Kinetic Energy of the particles increases. This means that they move faster and apply a greater force when they collide with the walls of the container. As pressure is the force per unit area on the container, the pressure increases. This is Gay-Lussac's "Pressure Temperature" Law: "P = kT".
The weaker the intermolecular forces, the easier the liquid evaporates. Higher vapor pressure the faster it evaporates. Thus, the weaker the attractive forces, the higher the vapor pressure and vice versa.
As a tire goes round and round heat builds up inside the heat expands the air inside the tire. On a normal day that he can dissipate but as the temperature on the outside increases is more difficult for the heat (energy) to leave the inside of the tire. As the temperature increases the pressure inside the tire also increases. It is that pressure that can cause the tire to explode.
find the mass of the container you will be using to measure something. The fill the container with ur substance. Measure it. Then subtract the mass of the container from the total mass
i need to explain what an absolute pressure gauge measures
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.
When the temperature of a gas increases, the Kinetic Energy of the particles increases. This means that they move faster and apply a greater force when they collide with the walls of the container. As pressure is the force per unit area on the container, the pressure increases. This is Gay-Lussac's "Pressure Temperature" Law: "P = kT".
If temperature increases, either the volume or the pressure must increase. Since you have limited the volume by closing the container, pressure must increase.
As the depth of the fluid increases, the pressure increases. To explain this mathematicaly you consider the Sg of the fluid times the height of the column multiplied by gravity will give you the pressure at the base of the column
Atoms in a gas move about randomly, and some will bounce against every surface of the container.
If the temperature remains constant and the volume of the container holding the gas decreases, the pressure of the gas will increase. This is because as the volume decreases, the gas particles have less space to move around, leading to more frequent collisions with the container walls, thus increasing the pressure.
As altitude increases, air pressure decreases. This is because the higher you go, the less air there is above you pressing down. The decrease in pressure with altitude follows a logarithmic pattern, with the rate of decrease slowing down the higher you go.
The gas particles will spread out to encompass the entire volume of the container. The particles are constantly in motion and will run into the walls of the container creating pressure (basically). If heated, the particles will move faster, and slower if cooled.
Increasing temperature generally increases solubility by providing more energy to overcome intermolecular forces, while increasing pressure can have varying effects depending on the substance. Smaller particle sizes increase surface area for interaction with solvent, enhancing solubility. Agitation helps disrupt solute-solvent interactions, facilitating dissolution and increasing solubility.
When a container of aerosol is heated, the particles inside gain more energy and move faster, increasing pressure and causing the container to explode. This is because the increased energy of the particles creates greater collisions against the container walls, leading to a build-up of pressure that can result in an explosion. The warning is necessary to prevent injury or damage due to the release of pressurized contents.
Pascal's principle states that a change in pressure applied to an enclosed fluid is transmitted undiminished to all portions of the fluid. In the case of the Cartesian diver, as pressure increases on the outside of the closed container, the volume of the air inside decreases, causing the diver to sink. When pressure decreases, the volume of air increases, causing the diver to rise. This is due to the principle that pressure applied to a fluid is transmitted equally in all directions.
An increase in temperature causes the gas inside the container to move faster, resulting in more frequent and forceful collisions with the container walls, thus increasing the pressure. Conversely, a decrease in temperature slows down the gas particles, leading to fewer collisions and a decrease in pressure.