# principle behind conduction

by aaaa202
Tags: conduction, principle
 P: 958 I am studying some simple models of how conduction arises on a microscopic level. A central idea is the following: Look at two leads attached by a conducting channel. Initially the system as a whole is in equilibrium which especially means that the chemical potential μ is the same everywhere. Now the crucial idea is: Apply a voltage V across the two leads. This lowers the energy levels in one lead respect to the other keeping their chemical potentials separated by qV, which then is what gives rise to conduction. I have underlined what I think to be the crucial step that I don't understand. To lower the potential means physically that we somehow connect one lead to a collection of negative charge (i.e. the negative pole of a battery) and the other lead to a collection of positive charge (the positive pole of a battery). The electrons in the lead connected to the negative pole will then have a potential relative to the electrons in the lead connected to the positive ones. But physically how do we go from this observation to chemical potentials being shifted. The chemical potential is a variable that maximizes entropy for a system which can exchange particles, so more a less something which controls the amount of particles in a system.
PF Gold
P: 10,786
Not sure if this answers your question, but I found it so I figured I'd post it in case it does.
From wiki: http://en.wikipedia.org/wiki/Chemica...ical_potential

 The abstract definition of chemical potential given above—total change in free energy per extra mole of substance—is more specifically called total chemical potential.[8][9] If two locations have different total chemical potentials for a species, some of it may be due to potentials associated with "external" force fields (Electric potential energy differences, gravitational potential energy differences, etc.), while the rest would be due to "internal" factors (density, temperature, etc.)[8] Therefore the total chemical potential can be split into internal chemical potential and external chemical potential:
 Sci Advisor P: 3,267 You must be careful which potential to use. You have ##dU=TdS-Udq +\mu dn## Hence mu is the change of energy with entropy S and charge q being kept constant. However you are shifting charged electrons with charge ne, so you have ## dU=TdS +(\mu-eU) dn ## The expression in the brackets is known as electrochemical potential and has to be equal for two systems which may exchange electrons.

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