Potential difference and electric fields

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Homework Help Overview

The problem involves calculating the potential difference between two points on the x-axis in the context of an electric field defined by E_x = (5 kN/C) x^3. The original poster attempts to apply the relationship between electric field and potential difference but encounters difficulties with the calculations.

Discussion Character

  • Exploratory, Assumption checking, Mathematical reasoning

Approaches and Questions Raised

  • Some participants question whether the formula V = -Ed is applicable due to the non-uniform nature of the electric field. Others suggest using the integral form of the potential difference. There are attempts to compute the integral of the electric field and discussions about unit conversions.

Discussion Status

Participants are exploring different interpretations of the problem and the appropriate methods to use. There is recognition of potential errors in calculations and unit conversions, but no consensus has been reached on the correct approach or solution.

Contextual Notes

There is a discussion about the assumptions regarding the uniformity of the electric field and the implications of using different equations for potential difference. Participants also note the importance of correctly converting units between kN/C and kV.

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Homework Statement


An electric field is given by E_x = (5 kN/C) x^3. Find the potential difference between the points on the x-axis at x= 1 m and x = 5 m. Answer in units of kV.

Homework Equations


V = -Ed

The Attempt at a Solution


V1 = -5*10^6 N/C * 1 = -5*10^6 volts
V2 = -5*10^6 * 5 = -25*10^6 volts = -2.5*10^7 volts

V2 - V1 = -25*10^6 -(-5*10^6) = -20*10^6 = -2.0*10^4 kV

I also tried cubing x and got -6.2e+5 but that is also wrong.
 
Last edited:
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V=-Ed only when E is uniform/constant along the length of d...is that the case here?

If not, you will need to use the more general equation:

V_b-V_a=-\int_a^b\vec{E}\cdot\vec{dl}
 
I would think that the x^3 would mean that E is not uniform/constant...

-5*10^6 times the integral of x^3 from 5 m to 1 m... which is the same as -5*10^6*[(1/4)x^4] from 5 m to 1 m... which is equal to -7.8*10^5.

Is that it?
 
Where is the 10^6 coming from?
 
I meant 10^4 since it's in kN/C, so the answer would be -7.8*10^3 kN?
 
Last edited:
That apparently isn't the answer... what did I do wrong?
 
1\,\mathrm{kN} = 10^3\,\mathrm{N}
and
1\,\mathrm{kV} = 10^3\,\mathrm{V}

Could it be that?
 
Oh wow... yet another stupid mistake. Thanks so much everyone!
 

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