GREPhysics.NET: GR8677 #50

GR8677 #50

Problem

GREPhysics.NET Official Solution

Advanced Topics $\Rightarrow$ }Solid State Physics

Recall $R_H=-\frac{1}{nec}$ , where the sign shows that the charge carrier is negative. ( $n$ is the electron density, $e$ electron charge, $c$ speed of light)

The Hall effect has to do with a bar of metal placed in a magnetic field. An electric current runs through it perpendicular to the field direction. However, the magnetic field term in the Lorentz force creates a force perpendicular to both the magnetic field and electric field. This ``pulls" the current astride from its original straight path. Charge starts accumulating on one side of the slab from this force, even as current continues to flow perpendicular to the accumulation direction. In equilibrium, the magnetic force balances the electric force from this charge accumulation. Apply some basic EM theory, and one can derive the Hall coefficient ( $R_H$ ) defined above.

Alternate Solutions

There are no Alternate Solutions for this problem. Be the first to post one!

Comments

Albert
2009-10-17 09:00:23

I do not think it is C.

One can refer to the link below. The Hall effect tells not the sign of the charge carrier but the carrier density as well as the magnetic field. I may be wrong, I am not too sure but Wikipedia suggests otherwise.

http://en.wikipedia.org/wiki/Hall_effect#Quantum_Hall_effect

hdcase
2009-10-25 21:26:33

The answer is C because if you were to stick an unknown semiconductor in a magnetic field with a perpendicular voltage you could measure the charge accumulation (in the direction perpendicular to both the magnetic field and the electrical field) to determine whether holes or electrons were moving along the direction of the applied current.

Reply to this comment

aaa
2007-07-14 13:54:32

aaa
2007-07-14 13:55:34

c is the answer

Reply to this comment

Post A Comment!

You are replying to:

Bare Basic LaTeX Rosetta Stone
LaTeX syntax supported through dollar sign wrappers $, ex., $\alpha^2_0$ produces $\alpha^2_0$ .
type this...	to get...
$\int_0^\infty$	$\int_0^\infty$
$\partial$	$\partial$
$\Rightarrow$	$\Rightarrow$
$\ddot{x},\dot{x}$	$\ddot{x},\dot{x}$
$\sqrt{z}$	$\sqrt{z}$
$\langle my \rangle$	$\langle my \rangle$
$\left( abacadabra \right)_{me}$	$\left( abacadabra \right)_{me}$
$\vec{E}$	$\vec{E}$
$\frac{a}{b}$	$\frac{a}{b}$

The Sidebar Chatbox...
Scroll to see it, or resize your browser to ignore it...

<a href="http://www6.shoutmix.com/?grephysics">View shoutbox</a>
ShoutMix chat widget

Free 3D Virtual World. Largest User-Created Fantasy World. Don't Play, Experience. Join Now!

Bored, got time to kill, and want to earn micro-cash by mindlessly clicking on links? Join CrownGPT. Click Offers. Click the Paid to Click button... then click to your heart's delight.

FREE 3D Virtual World Chat - Join Second Life Today!

All-Solutions List | Latest Comments | Unanswered Questions (Cries for Help!) |::| About

This site is not affiliated with ETS, nor is it officially endorsed (yet) by ETS. This site is the work of an individual named Yosun Chang. The solutions, sans user comments and ETS questions, are © 2005 by Yosun Chang except where noted. All rights reserved. / The comments appending particular solutions are due to the respective users. / Educational Testing Service, ETS, the ETS logo, Graduate Record Examinations, and GRE are registered trademarks of Educational Testing Service. The examination questions are © 1997 and © 2001 by ETS.

Bare Basic LaTeX Rosetta Stone