Difference betweem conduction and diffusion?

In summary, heat conduction and heat diffusion are interchangeable terms in the context of heat transfer. On a macroscopic level, they both refer to the flow of entropy through a system. While heat conduction is often associated with the vibrational freedom of atoms, it can also occur through the motion of free electrons in metals or through electromagnetic waves in transparent media. The term "heat" itself can refer to both the flow of entropy and a change in internal energy, but in the context of heat conduction, it refers to entropy. In some cases, the flow of entropy can be better understood on a macroscopic level before analyzing it on an atomic level. In metals, the electronic contribution to heat transport is dominant, while in impure metals
  • #1
indianaronald
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On an undergrad engineering level of talk, is there any difference between conduction and diffusion ways of heat transfer? Conduction occurs because of the vibrational freedom of atoms. And diffusion is, I think, because of diffusing of atoms?
 
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  • #3
indianaronald said:
On an undergrad engineering level of talk, is there any difference between conduction and diffusion ways of heat transfer? Conduction occurs because of the vibrational freedom of atoms. And diffusion is, I think, because of diffusing of atoms?
Heat conduction and heat diffusion are the same thing. On a macroscopic length scale, they both refer to the flow of entropy through the system. There may be some ambiguity when you try to define it in terms of microscopic parameters. When solving thermodynamics problems, one should ignore the atomic scale medium that actually transmits the energy.

Heat conduction is always entropy diffusion, regardless of the actual mechanism of energy transfer. Constraining the atomic scale mechanisms of heat conduction can over determine the mathematical problem.

Heat conduction doesn't have to occur through vibrating atoms (i.e., phonons). Heat conduction can also occur through free electrons vibrating on an atomic scale. This is why metals are such good heat conductors as well as electric conductors. The metals by definition conduct electricity by the flow of free carriers (electrons and holes).

The vibrating free electrons or free holes in a metal pass entropy much faster than vibrating atoms. So most of the heat conduction in a metal is actually carried by vibrating electrons that leave the atoms standing still. In a metal, the heat carried by atomic vibration is far less than the heat carried by free carriers.

In transparent media, entropy can also be carried by electromagnetic waves. Therefore, heat conduction can also occur due to the motion of photons. In meteorology, there are heat balance equations. Much of the "heat" carried upward is through infrared radiation, which is electromagnetic. Depending on context, this can be called heat flow or heat conduction.

The word "heat" can refer to the flow of entropy or a change in internal energy. In the phrases "heat conduction" and "heat conduction", the word heat refers to entropy not internal energy.

These two counter examples should help you understand that heat conduction is not always about vibrating atoms. Vibrating atoms may be a useful picture when analyzing heat flow in opaque insulators. However, the model fails when one is analyzing metals, semimetals or transparent insulators.

Entropy is sometimes referred to as a fluid. Entropy isn't made of loosely packed atoms, like gases. However, it has certain fluid-like properties. It is often useful to analyze the motion of entropy first on a macroscopic level before analyzing the motion on an atomic level. The fluid properties of entropy are not easily analyzed on an atomic level.

Solid state books often have a section on the heat capacity of both electrical insulators and metals. Here is one reference describing heat conductivity in metals:
"Introduction to Solid State Physics" seventh addition, by Charles Kittel (Wiley, 1996) pages 166-169.
Quote from bottom half of page 166:
"Do the electrons or the phonons carry the greater part of heat transport in a metal? In pure metals, the electronic contribution is dominant at all temperatures. In impure metals or in disordered alloys, the electron mean free path is reduced by collisions with impurities, and the phonon contribution may be comparable with the electronic contribution."

BTW: Phonons=Atomic vibrations.
 
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  • #4
Thanks a lot! That's a very detailed and explanatory answer. Helps a lot.
 
  • #5


Yes, there is a difference between conduction and diffusion as ways of heat transfer. Conduction is the transfer of heat through a medium by direct contact between molecules or atoms. This occurs because of the vibrational freedom of atoms, where energy is transferred from high energy particles to low energy particles. On the other hand, diffusion is the transfer of heat through a medium by the random movement of particles. This occurs because of the diffusing of atoms, where particles move from areas of high concentration to areas of low concentration.

In terms of undergrad engineering level, both conduction and diffusion are important concepts to understand in heat transfer. Conduction is often seen in solids, where heat is transferred from one end of an object to another. Diffusion, on the other hand, is seen in fluids and gases, where heat is transferred through the movement of particles.

It is also worth noting that conduction and diffusion can occur simultaneously in some cases. For example, in a solid, heat can be transferred through conduction from one end to another, while at the same time, diffusion can occur within the solid, transferring heat from hotter regions to cooler regions.

In summary, both conduction and diffusion are important ways of heat transfer and understanding the differences between them is crucial in the field of engineering.
 

1. What is the definition of conduction?

Conduction is the transfer of heat or electricity through a medium, such as a solid material, without any movement of the medium itself. This occurs through direct contact between molecules or particles in the medium.

2. How does conduction differ from diffusion?

Conduction and diffusion are two distinct mechanisms of heat or mass transfer. While conduction occurs through direct contact between molecules, diffusion occurs through random movement of molecules in a substance, resulting in the net movement of particles from regions of high concentration to low concentration.

3. What are some examples of conduction?

Examples of conduction include touching a hot pan and feeling the heat transfer from the pan to your hand, or placing a metal spoon in a hot cup of tea and observing how quickly the spoon heats up due to the transfer of heat through conduction.

4. How is conduction related to temperature?

The rate of conduction is directly proportional to the temperature difference between the two objects or regions in contact. This means that the greater the temperature difference, the faster the heat transfer will occur through conduction.

5. How is diffusion important in biological systems?

Diffusion plays a crucial role in many biological processes, such as the exchange of gases in the lungs and the movement of nutrients and waste products in and out of cells. It allows for substances to be distributed and transported throughout the body without the need for a pumping mechanism.

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