No, they are not, but due to the fact that the forces of attraction between them are weak, every gas molecule, from a single ion of Hydrogen to biggest molecules will have the same weak forces of repulsion, resulting in them taking up the same ammount of space.
No, gas, liquid, and solid particles do not have the same weight. The weight of a particle is dependent on its mass, gravity acting upon it, and its volume. Gas particles have the least weight as they are highly spread out, while solid particles have higher weight due to their compact structure.
During condensation, the gas particles lose energy and slow down, causing them to come closer together. At this point, not all gas particles have turned into liquid; there are still some gas particles that have not lost enough energy to condense. This process continues until all the gas particles have condensed into a liquid state.
Gas particles move at different speeds due to their kinetic energy, which is related to the temperature of the gas. At higher temperatures, gas particles have more kinetic energy and move faster on average, leading to a range of speeds rather than all particles moving at the same speed. This distribution of speeds is described by the Maxwell-Boltzmann distribution.
All gas particles are in constant random motion and collide with each other and the walls of the container. They have negligible volume compared to the volume of the container and exert pressure on the walls of the container due to their collisions. The average kinetic energy of the gas particles is directly proportional to the temperature of the gas.
Gas particles move randomly in all possible directions and travel in a straight path.
No, gas, liquid, and solid particles do not have the same weight. The weight of a particle is dependent on its mass, gravity acting upon it, and its volume. Gas particles have the least weight as they are highly spread out, while solid particles have higher weight due to their compact structure.
No, they are not.
They are all made of matter; just in different states.
During condensation, the gas particles lose energy and slow down, causing them to come closer together. At this point, not all gas particles have turned into liquid; there are still some gas particles that have not lost enough energy to condense. This process continues until all the gas particles have condensed into a liquid state.
D. Particles exert attractive forces. In real gases, the particles do not always move in the same direction, have the same kinetic energy, or have difficulty diffusing due to interactions between the particles leading to attractive forces that are not present in ideal gases.
Argon gas particles move faster on average than helium gas particles due to their larger molar mass. Helium gas is a lighter noble gas with a lower molar mass, therefore, its particles move slower compared to argon.
Gas particles move at different speeds due to their kinetic energy, which is related to the temperature of the gas. At higher temperatures, gas particles have more kinetic energy and move faster on average, leading to a range of speeds rather than all particles moving at the same speed. This distribution of speeds is described by the Maxwell-Boltzmann distribution.
No
Solid particles have the least kinetic energy, followed by liquid particles, and then gas particles. In solids, particles vibrate in fixed positions with minimal movement, while in liquids, particles have more energy and can move around each other. Gas particles have the highest kinetic energy, as they move rapidly and have more freedom of motion.
Non compressed gas has the gas particles spread out more. But when compressed packed more tightly therefore taking up less room but yet still has the same amount of atoms. So you still have the same weight but just that the particles are packed more tightly.
All gas particles are in constant random motion and collide with each other and the walls of the container. They have negligible volume compared to the volume of the container and exert pressure on the walls of the container due to their collisions. The average kinetic energy of the gas particles is directly proportional to the temperature of the gas.
Gas particles move randomly in all possible directions and travel in a straight path.