Gauss’s law in differential form: the divergence of the electric field at a point equals what multiple of the local volume charge density?
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A1/(4π ε0) times the volume charge density
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B1/ε0 times the volume charge density at that point
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Cε0 times the volume charge density at that point
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Dthe volume charge density at that point
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Ezero everywhere in space
Answer
Correct Answer: 1/ε0 times the volume charge density at that point
Explanation
Introduction / Context:Gauss’s law is one of Maxwell’s equations and comes in integral and differential forms. The differential form links the divergence of the electric field to the local charge density, providing a point-wise relationship in space that is crucial in field theory and electrostatics.
Given Data / Assumptions:
- We are in linear, homogeneous, isotropic medium with vacuum permittivity ε0 (or in free space).
- We are asked for the mathematical proportionality between ∇·E and ρv.
- Standard SI units are used.
Concept / Approach:
Gauss’s law (differential form) states: ∇·E = ρv/ε0. This is directly derived from the integral form ∮ E·dA = Q_enclosed/ε0 by applying the divergence theorem. It applies pointwise to relate local field divergence to the local charge density.
Step-by-Step Solution:
Write Gauss’s law (differential): ∇·E = ρv / ε0.Therefore, the multiplier relating divergence of E to ρv is 1/ε0.Hence the correct statement is: '1/ε0 times the volume charge density'.Verification / Alternative check:
In materials, D = εE and Gauss’s law may be written ∇·D = ρv (free). In free space where D = ε0 E, dividing both sides by ε0 again yields ∇·E = ρv/ε0.
Why Other Options Are Wrong:
- 1/(4π ε0): appears in Coulomb’s law, not in Gauss’s law differential form.
- ε0 times ρv: inverted proportionality.
- 'the volume charge density' without the 1/ε0 factor is incomplete.
- 'zero everywhere': only true in charge-free regions (ρv = 0), not in general.
Common Pitfalls:
- Confusing the roles of E, D, and ε0.
- Mixing constants from Coulomb’s law with those from Maxwell’s equations in SI form.
Final Answer:
1/ε0 times the volume charge density at that point