Calculating Electric Fields: Help

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Homework Help Overview

The problem involves calculating the electric field at the midpoint between a fixed electron and proton separated by 925 nm. The context is within electrostatics, specifically focusing on electric fields generated by point charges.

Discussion Character

  • Exploratory, Assumption checking, Conceptual clarification

Approaches and Questions Raised

  • Participants discuss the definition of charge (q) in the context of the problem, with some confusion about whether the charges being equal and opposite affects the calculation. There are attempts to clarify the relationship between the charges and the electric field at the midpoint.

Discussion Status

The discussion is ongoing, with participants exploring different interpretations of the charge and its implications for the electric field. Some guidance has been offered regarding the nature of electric fields from point charges and the concept of superposition.

Contextual Notes

There is a mention of the fundamental unit of charge and the specific values associated with the electron and proton, as well as the distinction between moving and fixed charges. The participants are also considering the implications of the charges being equal and opposite.

Keegs32
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Homework Statement



Question: An electron and a proton are fixed at a separation distance of 925nm. Find the magnitude and direction of the electric field at their midpoint.

Homework Equations



E= Fe/q


The Attempt at a Solution



(8.988 x 10^9) x (q/(9.25 x 10^-7)2)

This is the equation i have to solve for it but I don't know what q is in this situation. Help?
 
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q in this case is the fundamental unit of charge. Both the electron and proton have the same magnitude of charge, but opposite. Since you're dealing with a single electron and proton, q is just 1.60E-19 Coulombs; sign depending on which particle you're examining.
 
But since they have equal and opposite charges, wouldn't that make q=0 which then makes the entire solution 0. Or does it have to do something with their midpoint in this problem?
 
These are non-moving point charges. There are a couple of other relationships that I might try to use to examine this scenario. One is the electric field of a point charge. The other is the forces between two charged particles separated by a distance r.

Try it. :-)
 
Last edited:
Keegs32 said:
But since they have equal and opposite charges, wouldn't that make q=0 which then makes the entire solution 0. Or does it have to do something with their midpoint in this problem?

q would only = 0 if the two particles were coincident. But to hopefully get you pointed in the right direction: the electric field of a dipole is not zero (except in the limit as r-->infinity.) Moreover, electric fields of point charges superimpose, just as forces do. So the pointcharge model--if you consider both the proton and the electron simultaneously--should get you there.
 

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