GREPhysics.NET
GR | # Login | Register
   
  GR8677 #29
Problem
GREPhysics.NET Official Solution    Alternate Solutions
Verbatim question for GR8677 #29
Electromagnetism}Right Hand Rule

Note: this is a negative test charge. So, for the test charge, one has to either choose the opposite direction as that yielded by the Right Hand Rule or one could use the Left Hand Rule, which is just the RHR done with the left hand.

Suppose the current is a straight line pointing upwards along the page. The RHR for the current shows a magnetic field that's coming out of the page from the left side of the current and a field going into the page on the right side.

The problem wants the test charge to go parallel to the current. Applying the Lorentz Force, where F\propto \vec{v}\times \vec{B}, one finds that no matter the direction of approach, the only way for the force to point parallel to the current is for the velocity to go towards the wire. (Check this: Suppose the charge comes in from the left; the force would point parallel to the current. Suppose the charge comes in from the right; the force would point parallel to the current, again.)

See below for user comments and alternate solutions! See below for user comments and alternate solutions!
Alternate Solutions
mahdisadjadi
2012-09-27 10:06:49
The answer is definitely B. As you can see, test charge is negative and the official solution points it out. But in the answer this is not considered.
Assume that:
\mathbf{I}=  I\hat{z}
In this situation, direction of magnetic field is in the right hand side along -\hat{x} and is along \hat{x} in the left hand side of wire, so we can write , by Loentz force law(we take q to be positive and enter a minus to indicate negativity of charge):
\mathbf{F}=-q\vec{v}\times\vec{B} = - qB (v_{y}\hat{x}+v_{x}\hat{y})
Force should be parallel to the current, so we take v_{x}=0 and \mathbf{F}= F \hat{z}, where F should be positive.
So, v_{y} is negative and charge is moving away from the wire.


Alternate Solution - Unverified
Comments
fredluis
2019-08-09 04:35:04
They do not specify a theta dependence for the wave function so you can assume it is only a function of phi. Normalize the given function. irrigation repairNEC
joshuaprice153
2019-08-09 02:44:23
I can not thank you sufficiently for the articles on your web-site. I know you place a lot of time and energy into these and hope you know how considerably I enjoy it. I hope I\'ll do the identical thing man or woman at some time. 100% commission Gainesville NEC
kronotsky
2018-10-23 03:44:30
Right hand rule trick: if you put your thumb in the direction of I, and curl your fingers up into a fist, the fingers point along B. We want q \\vec{v} \\times \\vec{B} = \\vec{I}. Cyclic permutations and setting q = -1 gives \\vec{I} \\times \\vec{B} = \\vec{v}.NEC
QuantumCat
2014-09-02 14:01:17
Consider I = I_0{\hat k} so that B = B_0 {\hat \varphi} . Because q goes to -q, consider that - \hat k = \hat{v} \times \hat{\varphi} so \vec{v} \rightarrow v_0 (-\hat{r}) leading to choice ANEC
mahdisadjadi
2012-09-27 10:06:49
The answer is definitely B. As you can see, test charge is negative and the official solution points it out. But in the answer this is not considered.
Assume that:
\mathbf{I}=  I\hat{z}
In this situation, direction of magnetic field is in the right hand side along -\hat{x} and is along \hat{x} in the left hand side of wire, so we can write , by Loentz force law(we take q to be positive and enter a minus to indicate negativity of charge):
\mathbf{F}=-q\vec{v}\times\vec{B} = - qB (v_{y}\hat{x}+v_{x}\hat{y})
Force should be parallel to the current, so we take v_{x}=0 and \mathbf{F}= F \hat{z}, where F should be positive.
So, v_{y} is negative and charge is moving away from the wire.


walczyk
2012-10-13 13:06:27
Uh if Vy is negative then it is moving TOWARD the wire, not away from it. Also the answer is A, if ETS gave the wrong answer you wouldn't be the only one discovering this. This test is very very old.
eris1
2015-10-08 14:48:11
Define the cable as laying on the z-axis at the origin of the y and x axis. Imagine the particle is moving strictly along the y axis, starting at a point p_y>0. With a negative velocity (in the negative y direction), the particle is moving towards the wire and the B-field it encounters is in the positive x-direction. If the particle starts at p_y<0 then the direction of the B-field it encounters is in the negative x direction (canceling the \"-\" from the charge), thus following that the velocity of the particle must be positive (for a positive force), moving again towards the wire.
camarasi
2017-10-25 14:05:56
The x-component of the B-field as you\'ve taken it is negative, so you\'re off by a sign.
Alternate Solution - Unverified
Fily
2011-04-07 04:12:37
This is more simple just z=-?*Phi(The angle).So its ultimately give ?=-rNEC
shafatmubin
2009-10-31 18:12:46
Fleming's left-hand rule (thuMb for motion, First for field, seCond for current) is used to find direction of motion (i.e. force applied) when current and field directions are known.

So the LHR will work here, if one takes into account of the direction of the CURRENT produced by negative charges (i.e. opposite to velocity direction).
NEC
dean
2008-10-09 21:45:23
I may be mistaken, but it seems to me the LHR yields the wrong answer here if used consistently (i.e. twice). Better to stick with the right hand (sorry southpaws) and remember sign.
neon37
2008-11-02 15:41:09
not really you are probably trying to figure out the direction of the magnetic field also with LHR. The direction of the field is always with the RHR. You could find the direction the test charge should go given the direction of the field and current, with LHR. I would also suggest sticking to RHR on the real exam. Might be confusing.
NEC
darox
2006-11-29 06:59:15
actually, it cannot be B. the direction of the particle would be not parallel, but anti-parallel.
zaharakis
2007-01-05 09:31:42
Anti Parallel is still parallel
madfish
2007-11-02 12:11:27
not when you're talking about relative to a current
FortranMan
2008-10-19 13:14:30
I thought anti-parallel is still parallel too, until I looked at options (A) and (B).

This problem is deceptively simple, people. Remember that if the charge is moving towards the wire its velocity vector would be negative, but this negative can be canceled out if you are using a negative test charge, resulting in the positive force direction parallel to the positive current direction. In short, the sign of the charge can affect the vector.
NEC
zaharakis
2006-11-02 14:25:53
The answer could also be B. The question states parallel to the direction of the current. B would produce a force in the opposite direction to the current but this is still parallel.
zaharakis
2007-01-05 09:31:14
Anti parallel is still parallel.
tau1777
2008-10-31 19:30:03
yeah, i did not realize this the first time i took the test. and as i was redoing it today it hit me, this confusing thing about parallel. i feel that they should be more direct but i guess that's just the ETS. i'll have to keep an eye on my common sense of things and try to see it their way, least until test day. bottom line: to the ETS antiparallel and parallel are different.
gt2009
2009-06-22 06:04:21
Anti-parallel and parallel are different.
NEC

Post A Comment!
You are replying to:
They do not specify a theta dependence for the wave function so you can assume it is only a function of phi. Normalize the given function. irrigation repair

Username:
Password:
Click here to register.
This comment is best classified as a: (mouseover)
 
Mouseover the respective type above for an explanation of each type.

Bare Basic LaTeX Rosetta Stone

LaTeX syntax supported through dollar sign wrappers $, ex., $\alpha^2_0$ produces .
type this... to get...
$\int_0^\infty$
$\partial$
$\Rightarrow$
$\ddot{x},\dot{x}$
$\sqrt{z}$
$\langle my \rangle$
$\left( abacadabra \right)_{me}$
$\vec{E}$
$\frac{a}{b}$
 
The Sidebar Chatbox...
Scroll to see it, or resize your browser to ignore it...