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How can the direction of the electric field of a negative point charge be going in towards itself (radially), when the charge itself is generating the electric field? Is it generated at infinity then? Because if it's generated by the charge then it cannot go further in towards itself?

In case of positive charge, it is understandable that the field is being generated at the charge (at it's surface to be precise) and is going outwards radially.

negative point charge

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  • $\begingroup$ The field line diagram does not show how the field propagates. $\endgroup$ Commented Mar 9, 2017 at 23:18

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There is no "going" going on in field-line diagrams. The direction of the field lines indicates, by convention, the direction of the electrostatic force experienced by a positive test charge at that location.

Field lines do not indicate the 'flow' of any physical quantity, and there is nothing being 'generated'; instead, all you have is a force field, and ways to study and analyze it. This extends to the concept of electric flux (i.e. for a given surface $S$, the integral $\iint_S\mathbf E\cdot\mathrm d\mathbf S$): we call it 'flux' by analogy, but there's nothing at all actually 'flowing'; instead, it is just one more tool to understand and analyze the force field and the laws that govern it.

For more on field lines, see Why does the density of electric field lines make sense, if there is a field line through every point?.

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Firstly, the fields lines are by convention inward for a negative charge, and outwards for a positive charge.

Secondly, fields lines don't actually exist; they are just a fictitious entity that give us as physicists a way to visualize the situation.

Lastly, you will need at least 2 charges to be able to 'view' the field lines. Analogous to Newton's law of Gravitation; you need at least 2 masses to observe the effect of the force field on a 'test mass'.

Note that this does not mean that the gravitational field or electric field is already present in the absence of a test mass or charge.

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  • $\begingroup$ The direction of the field lines are not entirely conventional. They are found experimentation. (ie by bringing a positive test charge near a positive source charge, the test charge was found to be repelled, thus indicating the direction of the electric field to be radially outward, similarly it was found to be radially inward for the negative source charge); and yes I know that they are just imaginary lines to help us visualise the electric field, I agree that they do not exist; $\endgroup$
    – Raknos13
    Commented Mar 9, 2017 at 13:44
  • $\begingroup$ and also you do not need two charges to "view field lines" as field lines represent the electric field and electric field is present around the charge even if there is no other charge near it to experience the force caused by it. $\endgroup$
    – Raknos13
    Commented Mar 9, 2017 at 13:47
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    $\begingroup$ @mettled Yes, but how would you distinguish between positive and negative, they are just names $\endgroup$
    – BLAZE
    Commented Mar 9, 2017 at 13:47
  • $\begingroup$ physics.stackexchange.com/questions/177139/… $\endgroup$
    – Raknos13
    Commented Mar 9, 2017 at 13:50
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    $\begingroup$ @mettledmike Your first comment on this thread is incorrect. The direction of the field lines is entirely conventional: if you defined it as the direction of the force felt by a negative test charge then you would get reversed directions on all field lines. $\endgroup$ Commented Mar 9, 2017 at 14:16
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The direction of the electric field always indicates that a positive charge, located at any point in that field, would feel a force in the direction of the field.

In your example, the negative charge is still the source of the field and there is nothing at infinity in your problem; a positive charge placed in the field will be attracted to the negative charge, hence the direction of the field lines towards the negative source charge.

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It's merely a convention. The thing you have there is something called a source charge. To test the effects of a source charge we bring something called the test charge (Note that electric field can be measured only through the force on the test charge, given that we know the explicit charge on the test charge.) A test charge is positive by convention.

It would be handy to familiarise yourself with the definition of electric field. Electric field at a point is the force that a unit positive charge would experience if placed at that point. When we give a visual of this electric field, we actually draw lines of force (a 'line of force' simply tells where the test charge would go if placed at that point; where the test charge goes is dictated by where the arrow points).

PS: 'Lines of force' is a really confusing term. Most books prefer 'field lines' because in the case of magnetism, the field lines don't actually point to where the force takes a charge.

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  • $\begingroup$ @mettledmike Does that clear your confusion? $\endgroup$ Commented Mar 10, 2017 at 5:43
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If electric field is the force on per unit charge +ve or -ve then its direction would be the direction of force.

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