What is water that vanish out of an open container in terms of kinetic molecular theory of matter

According to the kinetic molecular theory of matter, water molecules possess kinetic energy due to their constant movement and collisions with each other. The rate of evaporation of water molecules increases with an increase in temperature and decreased atmospheric pressure. When a container of water is left open, the water molecules on the surface gain enough kinetic energy to overcome the intermolecular forces and evaporate into the atmosphere. Hence, the water that vanishes out of an open container is the result of the evaporating water molecules due to their kinetic energy.

Explain the need for gaps in railway lines in terms of kinetic molecular theory of matter

Railway tracks are made of metal, typically steel, which expands when it heats up and contracts when it cools down. This expansion and contraction of the metal tracks can cause them to buckle or bend, potentially causing derailments or other safety hazards. To allow for this expansion and contraction, gaps are left between the rails in railway lines.

The kinetic molecular theory of matter can help explain the need for these gaps. At high temperatures, the metal atoms in the rails have higher kinetic energy and therefore move around more rapidly. This increased movement causes the atoms to take up more space, causing the metal to expand. At lower temperatures, the kinetic energy of the atoms decreases and they move around less, allowing the metal to contract.

By leaving gaps between the rails in railway lines, the metal can expand and contract without buckling or bending. These gaps provide the rail with the necessary space to expand when it heats up, and to contract when it cools down, without causing damage to the track or compromising safety. Hence, the kinetic molecular theory of matter helps us understand the need for gaps in railway lines to maintain the safety and integrity of the tracks.