Difference between revisions of "Electric Field Strength"
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Where, | Where, | ||
− | 𝐹 is the [[force]] experienced by a [[Electrical Charge|charge]] 'Q' in the field. | + | *𝐹 is the [[force]] experienced by a [[Electrical Charge|charge]] 'Q' in the field. |
and | and | ||
− | 𝑄 is the [[Electrical Charge|charge]] in that field. | + | *𝑄 is the [[Electrical Charge|charge]] in that field. |
The '''Electric field strength''' around a point [[Electrical Charge|charge]] is given by: | The '''Electric field strength''' around a point [[Electrical Charge|charge]] is given by: | ||
Line 28: | Line 28: | ||
Where: | Where: | ||
− | 𝑘 is the [[Coulomb's Constant|Coulomb's constant]] | + | *𝑘 is the [[Coulomb's Constant|Coulomb's constant]] |
− | 𝑄 is the [[Point Charge|point charge]] causing the field | + | *𝑄 is the [[Point Charge|point charge]] causing the field |
and | and | ||
− | 𝑟 is the distance from that [[Point Charge|point charge]] | + | *𝑟 is the distance from that [[Point Charge|point charge]] |
Since; | Since; |
Revision as of 08:20, 24 May 2024
Key Stage 5
Meaning
Electric field strength is the force per unit charge exerted on a small positive test charge placed at a point in the field.
About Electric Field Strength
- Electric field strength is given by the symbol 𝐸.
- The unit of electric field strength is Newtons per Coulomb (N/C) or volts per metre (V/m).
- The direction of the electric field is the direction of the force that would act on a positive test charge.
- Electric fields can be represented by field lines; the density of these lines indicates the field strength.
Formula
Electric Field Strength is given by the general formula:
- \(𝐸=\frac{𝐹}{𝑄}\)
Where,
and
- 𝑄 is the charge in that field.
The Electric field strength around a point charge is given by:
- \(𝐸=𝑘\frac{𝑄}{𝑟^2}\)
Where:
- 𝑘 is the Coulomb's constant
- 𝑄 is the point charge causing the field
and
- 𝑟 is the distance from that point charge
Since;
- \(𝑘=\frac{1}{4\pi\varepsilon_0}\)
Then:
- \(𝐸=\frac{1}{4\pi\varepsilon_0}\frac{𝑄}{𝑟^2}\)
or
- \(𝐸=\frac{𝑄}{4\pi\varepsilon_0𝑟^2}\)
Where:
- \(\varepsilon_0\)is the permittivity of free space