Diffusion can be explained by the kinetic-molecular theory.
The process of gas molecules in a container moving in straight lines, colliding with each other and the walls of the container can be explained by the kinetic-molecular theory. This theory describes how the behavior of gas molecules is influenced by their motion and energy.
Condensation is explained by the kinetic molecular theory as the process where gas molecules lose kinetic energy and come closer together, forming a liquid. This occurs when the temperature of the gas decreases, causing the molecules to slow down and stick together due to intermolecular forces.
Condensation can be explained by the kinetic-molecular theory. It occurs when gas molecules lose energy and come together to form a liquid. Combustion and oxidation are chemical processes that involve the reaction of substances with oxygen, rather than the behavior of gas molecules.
The kinetic molecular theory explains the dissolution that is the process by which a solute forms a solution in a solvent.It could be dissolved by adding Ionic compounds.
The kinetic molecular theory was designed to explain the behavior of gases by describing them as vast numbers of small particles in constant motion. It explains the relationship between the temperature, pressure, volume, and average kinetic energy of gas particles.
Atomic theory. And in much more weird detail: quantum physics.
Kinetic Molecular Theory's abbreviation is KMT or sometimes KMTG when it is the abbreviation for Kinetic Molecular Theory of Gas
100 degrees temperature can be explained by the kinetic molecular theory, which states that temperature is a measure of the average kinetic energy of particles in a substance. At 100 degrees, the particles in a substance have higher kinetic energy, leading to increased molecular motion and higher temperature.
kinetic theory.
interpretation of pressure on kinetic theory of gases
Newton explained his theory
In the particle theory, heat conduction is explained by the transfer of kinetic energy between particles. When a material is heated, its particles gain energy and vibrate more rapidly. These particles then collide with neighboring particles, transferring some of their energy and causing them to vibrate faster. This process continues throughout the material, leading to the overall transfer of heat.