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    Current Subject
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    Applied Physics
    GE-169
    Progress0 / 45 topics
    Topics
    1. Electric Force and Its Applications2. Conservation of Charge3. Charge Quantization4. Electric Fields Due to Point Charge and Lines of Force5. Electric Fields: Ring of Charge and Disk of Charge6. A Point Charge in an Electric Field7. Dipole in an Electric Field8. Flux of a Vector Field9. Flux of an Electric Field10. Gauss’ Law and Its Applications11. Spherically Symmetric Charge Distribution12. Charge Isolated Conductor13. Electric Potential Energy14. Electric Potentials and Related Problems15. Calculating Potential from the Field16. Potential Due to Point and Continuous Charge Distribution17. Potential Due to a Dipole18. Equipotential Surfaces19. Calculating the Field from the Potential20. Electric Current and Current Density21. Resistance, Resistivity, and Conductivity22. Ohm's Law and Its Applications23. The Hall Effect24. Magnetic Force on a Current25. The Biot-Savart Law26. Line of Magnetic Field (B)27. Two Parallel Conductors28. Ampere's Law29. Solenoids and Toroids30. Faraday's Experiments and Law of Induction31. Lenz's Law32. Motional EMF33. Induced Electric Fields34. The Basic Equations of Electromagnetism35. Induced Magnetic Fields36. The Displacement Current37. Reflection and Refraction of Light Waves38. Total Internal Reflection39. Two Source Interference40. Double-Slit Interference and Related Problems41. Interference from Thin Films42. Diffraction and Wave Theory43. Single-Slit Diffraction and Related Problems44. Polarization of Electromagnetic Waves45. Polarizing Sheets and Related Problems
    GE-169›Potential Due to Point and Continuous Charge Distribution
    Applied PhysicsTopic 16 of 45

    Potential Due to Point and Continuous Charge Distribution

    11 minread
    1,954words
    Intermediatelevel

    Potential Due to Point and Continuous Charge Distributions

    In electrostatics, the electric potential (or simply potential) is a scalar quantity that describes the potential energy per unit charge at a point in space due to the presence of electric fields. It is closely related to the electric field, as the electric field is the negative gradient of the potential. The electric potential at a point is a measure of the work done by an external force in bringing a positive test charge from infinity to that point without any acceleration.


    1. Electric Potential Due to a Point Charge

    The electric potential VVV due to a point charge QQQ at a distance rrr from the charge is given by:

    V=14πϵ0QrV = \frac{1}{4 \pi \epsilon_0} \frac{Q}{r}V=4πϵ0​1​rQ​

    Where:

    • VVV is the electric potential at a distance rrr from the point charge,
    • QQQ is the magnitude of the point charge,
    • rrr is the distance from the point charge to the point where the potential is being calculated,
    • ϵ0\epsilon_0ϵ0​ is the permittivity of free space (8.85×10−12 C2/N\cdotpm28.85 \times 10^{-12} \, \text{C}^2 / \text{N·m}^28.85×10−12C2/N\cdotpm2).

    Key Points:

    • The potential due to a point charge is a scalar quantity and is radial (it depends only on the distance from the charge, not on direction).
    • The potential is positive for a positive charge and negative for a negative charge.
    • At infinity, the potential is defined to be zero, so the potential at a distance rrr is relative to the potential at infinity.

    Electric Field and Potential:

    • The electric field EEE and electric potential VVV are related through the gradient:
    E⃗=−∇V\vec{E} = - \nabla VE=−∇V

    For a point charge, the electric field is radially outward (or inward for a negative charge), and we can obtain the electric field from the potential:

    E=−dVdr=14πϵ0Qr2E = - \frac{dV}{dr} = \frac{1}{4 \pi \epsilon_0} \frac{Q}{r^2}E=−drdV​=4πϵ0​1​r2Q​

    This matches Coulomb’s law for the electric field due to a point charge.


    2. Electric Potential Due to a Continuous Charge Distribution

    For a continuous charge distribution, the potential at a point in space is the sum of the potentials due to all infinitesimal charge elements that make up the distribution. Depending on the geometry of the charge distribution, we can integrate to find the total potential.

    The general expression for the potential at a point r⃗\vec{r}r due to a continuous charge distribution is:

    V(r⃗)=14πϵ0∫dq∣r⃗−r⃗′∣V(\vec{r}) = \frac{1}{4 \pi \epsilon_0} \int \frac{dq}{|\vec{r} - \vec{r}'|}V(r)=4πϵ0​1​∫∣r−r′∣dq​

    Where:

    • dqdqdq is the infinitesimal charge element,
    • r⃗\vec{r}r is the position where the potential is being calculated,
    • r⃗′\vec{r}'r′ is the position of the charge element dqdqdq,
    • ∣r⃗−r⃗′∣|\vec{r} - \vec{r}'|∣r−r′∣ is the distance between the charge element and the point where the potential is being calculated.

    The specific form of the integral depends on the geometry of the charge distribution.


    3. Electric Potential Due to a Line Charge Distribution

    Consider a uniformly charged infinite line or a line of charge with charge per unit length λ\lambdaλ (charge density) placed along the x-axis. To find the potential at a point PPP located a distance rrr from the line, we use the following approach:

    Solution:

    • The potential due to an infinitesimal charge element dq=λdxdq = \lambda dxdq=λdx at a point located at a distance rrr is:
    dV=14πϵ0dqrdV = \frac{1}{4 \pi \epsilon_0} \frac{dq}{r}dV=4πϵ0​1​rdq​
    • The distance from each charge element to the point PPP is rrr, which is constant for the line charge (if the line is perpendicular to the point).

    For a finite line of charge with total charge QQQ and length LLL, the potential at a point PPP located at a perpendicular distance rrr from the line is:

    V=14πϵ0∫−L/2L/2λdxx2+r2V = \frac{1}{4 \pi \epsilon_0} \int_{-L/2}^{L/2} \frac{\lambda dx}{\sqrt{x^2 + r^2}}V=4πϵ0​1​∫−L/2L/2​x2+r2​λdx​

    This integral can be evaluated to give the potential for a finite line of charge.

    For an infinite line of charge (with L→∞L \to \inftyL→∞), the potential at a point at a distance rrr from the line is:

    V(r)=λ2πϵ0ln⁡(1r)V(r) = \frac{\lambda}{2 \pi \epsilon_0} \ln \left( \frac{1}{r} \right)V(r)=2πϵ0​λ​ln(r1​)

    This shows that the potential due to an infinite line of charge grows logarithmically with distance from the line.


    4. Electric Potential Due to a Surface Charge Distribution

    Consider a uniformly charged disk with surface charge density σ\sigmaσ and radius RRR. To find the potential at a point along the axis of the disk (say, at a distance zzz from the center), we treat the disk as a collection of infinitesimal charge elements and integrate over the entire surface.

    Solution:

    • An infinitesimal charge element dq=σdA=σr dr dθdq = \sigma dA = \sigma r \, dr \, d\thetadq=σdA=σrdrdθ is located at a distance rrr from the center of the disk.
    • The potential due to dqdqdq at a point on the axis of the disk (distance zzz from the center) is:
    dV=14πϵ0dqr2+z2dV = \frac{1}{4 \pi \epsilon_0} \frac{dq}{\sqrt{r^2 + z^2}}dV=4πϵ0​1​r2+z2​dq​
    • The total potential VVV is obtained by integrating over the entire surface of the disk:
    V(z)=14πϵ0∫02π∫0Rσr dr dθr2+z2V(z) = \frac{1}{4 \pi \epsilon_0} \int_0^{2\pi} \int_0^R \frac{\sigma r \, dr \, d\theta}{\sqrt{r^2 + z^2}}V(z)=4πϵ0​1​∫02π​∫0R​r2+z2​σrdrdθ​

    The solution to this integral gives the electric potential at a point on the axis of the disk. After evaluating the integral:

    V(z)=σ2ϵ0(R2+z2−z)V(z) = \frac{\sigma}{2 \epsilon_0} \left( \sqrt{R^2 + z^2} - z \right)V(z)=2ϵ0​σ​(R2+z2​−z)

    This expression gives the potential at a point along the axis of a uniformly charged disk.


    5. Electric Potential Due to a Spherically Symmetric Charge Distribution

    For a spherically symmetric charge distribution, such as a uniformly charged sphere, the potential at a point outside the distribution can be derived by considering the charge as if it were concentrated at the center of the sphere.

    Solution:

    • For a uniformly charged sphere with total charge QQQ and radius RRR, the electric potential at a point outside the sphere (at a distance rrr from the center) is:
    V(r)=14πϵ0QrV(r) = \frac{1}{4 \pi \epsilon_0} \frac{Q}{r}V(r)=4πϵ0​1​rQ​

    This is the same as the potential due to a point charge, because from a distance rrr (where r>Rr > Rr>R), the sphere behaves like a point charge.

    • For points inside the sphere (at a distance rrr where r<Rr < Rr<R), the potential at a point inside the sphere is:
    V(r)=14πϵ0(QR−Q2R3r2)V(r) = \frac{1}{4 \pi \epsilon_0} \left( \frac{Q}{R} - \frac{Q}{2R^3} r^2 \right)V(r)=4πϵ0​1​(RQ​−2R3Q​r2)

    This expression arises from the fact that the electric potential inside a uniformly charged sphere depends on the distance from the center.


    6. Summary of Potential for Different Charge Distributions

    • Point Charge: The potential due to a point charge QQQ at a distance rrr is V(r)=14πϵ0QrV(r) = \frac{1}{4 \pi \epsilon_0} \frac{Q}{r}V(r)=4πϵ0​1​rQ​.
    • Line Charge: For a line charge with linear charge density λ\lambdaλ, the potential at a distance rrr from the line is V(r)=λ2πϵ0ln⁡(1r)V(r) = \frac{\lambda}{2 \pi \epsilon_0} \ln \left( \frac{1}{r} \right)V(r)=2πϵ0​λ​ln(r1​) for an infinite line of charge.
    • Surface Charge: For a uniformly charged disk, the potential at a point on its axis is V(z)=σ2ϵ0(R2+z2−z)V(z) = \frac{\sigma}{2 \epsilon_0} \left( \sqrt{R^2 + z^2} - z \right)V(z)=2ϵ0​σ​(R2+z2​−z), where σ\sigmaσ is the surface charge density.
    • Spherical Symmetry: For a spherically symmetric charge distribution, the potential outside the sphere is V(r)=14πϵ0QrV(r) = \frac{1}{4 \pi \epsilon_0} \frac{Q}{r}V(r)=4πϵ0​1​rQ​ (same as a point charge), and inside the sphere, it follows a quadratic dependence on rrr.

    The electric potential plays a crucial role in understanding the behavior of

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    Calculating Potential from the Field
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    Potential Due to a Dipole

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      Est. reading time11 min
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      DifficultyIntermediate