when heat is added to cold water, the particles starts to move around. The particles now have more energy for motion. The temperature of the water also rises from the movement of the particles.
They fasten the movement of particles hence increasing the kinetic energy
Well when you observe brownian motion you can feel the heat and so the theory was developed from the temperature of the heat :) hope I helped
Well when you observe brownian motion you can feel the heat and so the theory was developed from the temperature of the heat :) hope I helped
FASOUH
I think you may be talking about the Kinetic theory of Molecules, which relates the temperature of matter (relative to absolute zero) to the average velocity of the molecules which make it up. For gases, it could be the Ideal Gas Law, which assumes that the gas is small particles whizzing around. You also may be thinking of Brownian Motion, which is not a law, but a phenomenon where extremely tiny particles can be observed to be buffeted by other random motion of molecules and particles.
The molecules are in a state of constant motion. The particles exert attractive force on one another. The particles possess kinetic energy due to their motion.
Well when you observe brownian motion you can feel the heat and so the theory was developed from the temperature of the heat :) hope I helped
Well when you observe brownian motion you can feel the heat and so the theory was developed from the temperature of the heat :) hope I helped
when heat is added to cold water, the particles starts to move around. The particles now have more energy for motion. The temperature of the water also rises from the movement of the particles.
FASOUH
K. Burdzy has written: 'Multidimensional Brownian excursions and potential theory' -- subject(s): Brownian motion processes, Potential theory (Mathematics)
I think you may be talking about the Kinetic theory of Molecules, which relates the temperature of matter (relative to absolute zero) to the average velocity of the molecules which make it up. For gases, it could be the Ideal Gas Law, which assumes that the gas is small particles whizzing around. You also may be thinking of Brownian Motion, which is not a law, but a phenomenon where extremely tiny particles can be observed to be buffeted by other random motion of molecules and particles.
The molecules are in a state of constant motion. The particles exert attractive force on one another. The particles possess kinetic energy due to their motion.
You can develop a general theory of the dynamics of turbulent flows and the motion of granular materials.
The observation about gases that proved molecules can move is their compressibility. This is further corroborated by the Brownian Motion theory.
brownian motion was accepted early on, but his special and general theories of relativity, and his theory regarding quanta took longer to be accepted by all.
Kazuaki Taira has written: 'Diffusion processes and partial differential equations' -- subject(s): Boundary value problems, Elliptic operators, Markov processes 'Brownian motion and index formulas for the de Rham complex' -- subject(s): Brownian motion processes, Hodge theory, Riemannian manifolds 'Brownian Motion and Index Formulas for the De Rham Complex (Mathematical Research (Vch Pub))'
"Brownian Motion and how it applies to everything" That would be a good name. Brownian Motion is the theory that all atoms are in a constant state of motion. You could explain how when heat energy is added it changes the physical characteristic of the chocolate from solid to liquid which happens because the atoms of the chocolate are moving at a faster rate constantly.