Non-uniform electric field and a dipole

In summary: If the dipole vector \vec p is parallel to the x-axis and points to the + x direction, then \vec E = (E) \vec x \vec F_- = - ( \vec E ) (Q) \vec F_+ = ( \vec E ) (Q) \vec F_- = - (E) \vec x (Q)In summary, the net force on the dipole is zero.
  • #1
orthovector
115
0

Homework Statement


a dipole, [tex] \vec p [/tex], is in a non uniform field, [tex] \vec E = (E) \vec i [/tex] where [tex] \vec E [/tex] points along the x axis. What is the net force on the dipole if [tex] \vec E [/tex] depends only on x?

Homework Equations



[tex]| \vec{p} \times \vec{E}| = | \vec p | | \vec E | sin \theta [/tex]

The Attempt at a Solution



i think if the charges are separated by dx, [tex] \vec p = (Q) (dx) (\vec i) [/tex]

then, i get a bit confused... what thinking step shall I take next?
 
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  • #2
orthovector said:

Homework Equations



[tex]| \vec{p} \times \vec{E}| = | \vec p | | \vec E | sin \theta [/tex]

This equation gives the torque on a physical dipole (about its center) in a uniform field, or the torque on a pure (ideal) dipole about its center, not the force on a dipole in a non-uniform field. Look in your textbook to find the equation for force on a dipole (physical or ideal) in a non-uniform field.


i think if the charges are separated by dx, [tex] \vec p = (Q) (dx) (\vec i) [/tex]

You seem to be treating the dipole as a physical dipole...are you told whether it is a physical dipole or pure dipole?
 
  • #3
gabbagabbahey said:
This equation gives the torque on a physical dipole (about its center) in a uniform field, or the torque on a pure (ideal) dipole about its center, not the force on a dipole in a non-uniform field. Look in your textbook to find the equation for force on a dipole (physical or ideal) in a non-uniform field.You seem to be treating the dipole as a physical dipole...are you told whether it is a physical dipole or pure dipole?

yes, I didn't write down the equation for the force.

[tex] Q \vec E = \vec F [/tex]
pure dipole.
 
  • #4
orthovector said:
yes, I didn't write down the equation for the force.

[tex] Q \vec E = \vec F [/tex]
pure dipole.

No, that's the force on a monopole (point charge) in any electric field...read your textbook!:wink:
 
  • #5
gabbagabbahey said:
No, that's the force on a monopole (point charge) in any electric field...read your textbook!:wink:
oh come on, you're treating me like some scrub. I know the equation... positive force plus negative force in which the Electric field from the dipole decreases by 1/r cubed for far distances...

I've done a lot of thinking on this problem..

GeeZ!

[tex] \vec F = \vec F_+ + \vec F_- = (Q \vec E_+ - Q \vec E_- ) \cdot \vec i [/tex]

what thinking step shall I take next?
 
  • #6
orthovector said:
oh come on, you're treating me like some scrub. I know the equation... positive force plus negative force in which the Electric field from the dipole decreases by 1/r cubed for far distances...

I've done a lot of thinking on this problem..

GeeZ!

[tex] \vec F = \vec F_+ + \vec F_- = (Q \vec E_+ - Q \vec E_- ) \cdot \vec i [/tex]

what thinking step shall I take next?

For a physical dipole, with two charges [itex]\pm Q[/itex] separated by some non-zero distance, then this would be a good start, but you just said that you have a pure dipole, not a physical dipole.

The general equation for the force on a dipole (pure or physical) is derived in almost every introductory level E-M textbook I've come across...is it truly not derived in your textbook?...Which textbook does your course use and what level course is this for?
 
  • #7
gabbagabbahey said:
For a physical dipole, with two charges [itex]\pm Q[/itex] separated by some non-zero distance, then this would be a good start, but you just said that you have a pure dipole, not a physical dipole.

The general equation for the force on a dipole (pure or physical) is derived in almost every introductory level E-M textbook I've come across...is it truly not derived in your textbook?...Which textbook does your course use and what level course is this for?

sorry, it must be a physical dipole. The two charges are separated by a distance dx.
 
  • #8
orthovector said:
sorry, it must be a physical dipole. The two charges are separated by a distance dx.

Okay, and you are told that the charges are [itex]\pm Q[/itex]?

If so, then you can continue on from here:

[tex]\vec{F} = \vec{F_{+}}+\vec{F_{-}} = (Q E_{+} - Q E_{-})\hat{i}[/tex]

Where are the charges located? What does that make [itex]E_{\pm}[/itex]?
 
  • #9
if the dipole vector [tex] \vec p [/tex] is parallel to the x-axis and points to the + x direction, then

[tex] \vec E = (E) \vec x [/tex]
[tex] \vec F_- = - ( \vec E ) (Q) [/tex]
[tex] \vec F_+ = ( \vec E ) (Q) [/tex]
[tex] \vec F_- = - (E) \vec x (Q) [/tex]
[tex] \vec F_+ = (E) \vec x (Q) = (E) (x + dx) (Q) [/tex]

i'm stuck...
 
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  • #10
orthovector said:
if the dipole vector [tex] \vec p [/tex] is parallel to the x-axis and points to the + x direction, then

[tex] \vec E = (E) \vec x [/tex]
[tex] \vec F_- = - ( \vec E ) (Q) [/tex]
[tex] \vec F_+ = ( \vec E ) (Q) [/tex]
[tex] \vec F_- = - (E) \vec x (Q) [/tex]
[tex] \vec F_+ = (E) \vec x (Q) = (E) (x + dx) (Q) [/tex]

i'm stuck...

:eek: What a jumbled mess!...please use \hat{} to represent unit vectors and \vec{} for normal vectors; it will make things less confusing...and be careful with your brackets! ([itex](E) \vec x[/itex] means E times the vector x; while [itex]E(x)\hat{i}[/itex] means E as a function of x, directed along the x-axis--which is what I'm sure you meant to write)

I'm sorry if this sounds rude, but I think you should consider getting a tutor. I think some face to face assistance could really benefit you.

At this point, you seem to have made at least 3 assumptions without justification; (1) the first is that the dipole consists of two point charges [itex]\pm Q[/itex] separated by a distance [itex]dx[/itex], (2) the second is that the dipole points in the x-direction, (3) and the third is that the negative charge is located at [itex]\vec{r}=x\hat{i}[/itex]

From your original problem statement, I see absolutely no reason to make these assumptions:
orthovector said:

Homework Statement


a dipole, [tex] \vec p [/tex], is in a non uniform field, [tex] \vec E = (E) \vec i [/tex] where [tex] \vec E [/tex] points along the x axis. What is the net force on the dipole if [tex] \vec E [/tex] depends only on x?

Is this how the original problem is worded on your assignment sheet/textbook?

Again I ask what level course this is for, and what the course textbook is? (If I have a copy of the same text, I can point to any helpful sections)
 
  • #11
gabbagabbahey said:
:eek: What a jumbled mess!...please use \hat{} to represent unit vectors and \vec{} for normal vectors; it will make things less confusing...and be careful with your brackets! ([itex](E) \vec x[/itex] means E times the vector x; while [itex]E(x)\hat{i}[/itex] means E as a function of x, directed along the x-axis--which is what I'm sure you meant to write)

I'm sorry if this sounds rude, but I think you should consider getting a tutor. I think some face to face assistance could really benefit you.

At this point, you seem to have made at least 3 assumptions without justification; (1) the first is that the dipole consists of two point charges [itex]\pm Q[/itex] separated by a distance [itex]dx[/itex], (2) the second is that the dipole points in the x-direction, (3) and the third is that the negative charge is located at [itex]\vec{r}=x\hat{i}[/itex]

From your original problem statement, I see absolutely no reason to make these assumptions:


Is this how the original problem is worded on your assignment sheet/textbook?

Again I ask what level course this is for, and what the course textbook is? (If I have a copy of the same text, I can point to any helpful sections)

That was the entire problem. the 3 assumptions I made are all valid. (1) 2 point charges separated by a distance d is a useful summary to simplify any dipole system. (2) the dipole vector can be anti parallel, parallel, or orthogonal to the Electric field, but since the electric field is a function of x, the dipole will eventually orient itself in a parallel position to the Electric field, and it will eventually move horizontally due to the difference in forces of the negative charge and the positive charge. (3) this part is already explained.

I'm offended by your remark. It seems like you haven't put any thought into this problem, or maybe you don't understand...and you say I made unjustified claims?
 
  • #12
orthovector said:
That was the entire problem. the 3 assumptions I made are all valid. (1) 2 point charges separated by a distance d is a useful summary to simplify any dipole system.

Yes and no. The limiting process necessary to get results that are consistent with a pure dipole (which is what is typically meant when you are told the you have a dipole [tex]\vec{p}[/tex] and not specifically told whether it is pure or physical) is fairly complicated. You have to take the limit as d-->0 and Q-->infinity while holding the product Qd equal to p. You can do the problem this way if you so choose, but there is a much simpler method.

(2) the dipole vector can be anti parallel, parallel, or orthogonal to the Electric field, but since the electric field is a function of x, the dipole will eventually orient itself in a parallel position to the Electric field, and it will eventually move horizontally due to the difference in forces of the negative charge and the positive charge.
In electrostatics one typically analyzes a charge distribution at a particular snapshot in time. I see no reason to assume that the questioner wants you to analyze the moment in time where p is aligned in the x-direction and has moved some distance away from its origin.

Instead, I would assume that p points in any direction (that way you can derive what the force on the dipole is in the general case, instead of just when it is aligned with the field). I would also assume that the question refers to a pure dipole, and that E=E(x)i.

In such a case, it is easy to show that [tex]\vec{F}(\vec{r})=(\vec{p}\cdot\hat{i})E'(x)\hat{i}[/tex] where [itex]\vec{r}[/itex] is the location of the dipole)
 
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  • #13
At the risk of entering such a contentious thread, I will inform you that the force on a dipole [tex]{\vec p}[/tex] in an electric field [tex]{\vec E}[/tex] is
[tex]{\vec F}=\nabla({\vec p\cdot{\vec E}}).[/tex]
 
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  • #14
clem said:
At the risk of entering such a contentious thread, I will inform you that the force on a dipole [tex]{\vec p}[/tex] in an electric field [tex]{\vec E}[/tex] is
[tex]{\vec F}=\nabla({\vec p\cdot{\vec E}}).[/tex]

For a pure dipole, yes. In the more general case,

[tex]\vec{F}=(\vec{p}\cdot\vec{\nabla})\vec{E}[/tex]

This is the formula that I recommended he look up in his textbook, as it is derived in almost every introductory level EM text I've come across.
 
  • #15
thanks gab,

My introductory physics book does not have this derivation. Instead, it asks me to figure out the derivation. Would you recommend a better physics textbook that has this derivation? REZNICK? GIANCOLI? IDA? SERWAY?? KNIGHT? WHICH ONE?
 
  • #16
orthovector said:
thanks gab,

My introductory physics book does not have this derivation. Instead, it asks me to figure out the derivation. Would you recommend a better physics textbook that has this derivation? REZNICK? GIANCOLI? IDA? SERWAY?? KNIGHT? WHICH ONE?

I don't have those texts handy right now, but I seem to recall seeing the derivation in Serway, and it can certainly be found in intermediate level texts Griffiths' Introduction to Electrodynamics and Jackson's Electrodynamics

However, seeing as it isn't in your text, you must be expected to derive the expression in post #13 by means of a Taylor series expansion and the limiting process I described at the beginning of the post.

Try expanding the E(x+dx) around the point x assuming dx<<x and then substitute that into your expression for the force. (since you don't know what E(x) is, there is no way to dtermine what E'(x), E''(x) etc. are so just write them as E'(x) etc.)
 
  • #17
Thanks gab,

are you a grad student or a practicing engineer?
 
  • #18
I appreciate this thread is inactive but in case someone stumbles upon it...

Books:
Electricity and Magnetism - Duffin
Electricity and Magnetism - Bleaney & Bleaney

Are both good books suitable for first year undergrads, in fact Duffin is probably accessible to most A-level students. Someone above recommended Jackson's Electrodynamics which is more of an advanced reference text really, the books listed above are a better place to start.

Clem posted the force on an idealised dipole being:
[tex]{\vec F}=\nabla({\vec p\cdot{\vec E}}).[/tex]

This is incorrect, gabbagabbahey posted the correct version. If you compare the component [tex]F_x[/tex] for the two answers you'll see they are inconsistent. Vector calculus...
 

1. What is a non-uniform electric field?

A non-uniform electric field is a type of electric field in which the strength and direction of the field varies at different points in space. This can occur when there are varying charges or conducting materials present in the field.

2. How is a non-uniform electric field different from a uniform electric field?

In a uniform electric field, the strength and direction of the field remain constant at all points in space. In a non-uniform electric field, the strength and direction can vary, creating a more complicated and dynamic field.

3. What is a dipole in an electric field?

A dipole is a pair of equal but opposite charges that are separated by a small distance. In an electric field, a dipole can experience a torque, or rotational force, due to the non-uniformity of the field.

4. How does a non-uniform electric field affect a dipole?

A non-uniform electric field will cause a dipole to experience a torque, causing it to rotate. The direction of the torque will depend on the orientation of the dipole with respect to the field.

5. What are some real-world applications of non-uniform electric fields and dipoles?

Non-uniform electric fields and dipoles have many practical applications, including in electronic devices such as capacitors, antennas, and sensors. They are also important in understanding the behavior of molecules and atoms in chemistry and biology.

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