Electric Fields

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Table of Contents

• Electric Fields
  • Key Definitions
  • Electric Field Formula
    • \(\vec{E}\equiv\frac{\vec F_E}{q_1}=k_e\frac{q_2}{r^2}\hat r\)
    • \(\vec F_E=q_1\vec E\)
    • \(\vec F_E=k_e\frac{q_1q_2}{r^2}\hat r=q_1 \left(k_e\frac{q_2}{r^2}\hat r\right)\)
  • Superposition Principle
    • \(\vec E=\sum_{i=1}^n \vec E_i\)
    • \(\vec E=k_e\sum_{i=1}^n \frac{q_i}{r^2}\hat r\)
    • \(\vec E=k_e\int \frac{dq}{r^2}\hat r\)
    • Charge Density
      • \(Q_{net}=\int dq\)
      • \(\lambda=\frac{dq}{dL}\quad\therefore\quad dq=\lambda dL\)
      • \(\sigma=\frac{dq}{dA}\quad\therefore\quad dq=\sigma dA\)
      • \(\rho=\frac{dq}{dV}\quad\therefore\quad dq=\rho dV\)
  • Common Fields
    • Circulars
      • Ring
        • \(\vec E = k_e\frac{\lambda 2\pi Rz}{(z^2+R^2)^{3/2}}\hat z\)
      • Disk
        • \(\vec E=2\pi\sigma k_ez\left (\frac{1}{z}-\frac{1}{\sqrt{z^2+R^2}} \right )\hat z\)
      • Annulus
        • \(\vec E=2\pi\sigma k_ez\left (\frac{1}{\sqrt{r^2+z^2}}-\frac{1}{\sqrt{R^2+z^2}} \right )\hat z\)
    • Infinite Plane
      • Single Plane
        • \(\vec E=\frac{\sigma}{2\epsilon_0}\hat x\)
      • Two Planes
        • \(\vec E = \frac{\sigma}{\epsilon_0}\)
    • Hollow Sphere
      • Inside ($r < R_0$)
        • \(\vec E = 0\)
      • Outside ($r > R$)
        • \(\vec E = k_e\frac{Q}{r^2}\hat r\)
      • In ($R_0>r>R$)
        • \(\vec E = k_e\int \frac{dq}{r^2}\hat r=k_e\int \frac{\rho dV}{r^2}\hat r\)
  • Electric Field Lines
    • Rules

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Electric Fields

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Key Definitions

Field - a physical quantity with a value at every point in space-time

• Scalar Field - scalar assigned to every point (e.g. temperature)
• Vector Field - vector assigned to every point (e.g. air current)

Electric Field - a field created by an which imposes effects on other charges in the field

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Electric Field Formula

\(\vec{E}\equiv\frac{\vec F_E}{q_1}=k_e\frac{q_2}{r^2}\hat r\)

\(\vec F_E=q_1\vec E\)

Where $\vec F_E$ is given by :

\(\vec F_E=k_e\frac{q_1q_2}{r^2}\hat r=q_1 \left(k_e\frac{q_2}{r^2}\hat r\right)\)

E.g.

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Superposition Principle

Electric fields obey the superposition principle (multiple charges/fields can be summed) i.e. Generalized :

\(\vec E=\sum_{i=1}^n \vec E_i\)

Discrete Charge Distribution:

\(\vec E=k_e\sum_{i=1}^n \frac{q_i}{r^2}\hat r\)

Continuous Charge Distribution:

\(\vec E=k_e\int \frac{dq}{r^2}\hat r\)

Charge Density

Electric charges follow the superposition principle s.t. we observe charge densities:

\(Q_{net}=\int dq\)

Linear Charge Density:

\(\lambda=\frac{dq}{dL}\quad\therefore\quad dq=\lambda dL\)

Surface Charge Density:

\(\sigma=\frac{dq}{dA}\quad\therefore\quad dq=\sigma dA\)

Volumetric Charge Density:

\(\rho=\frac{dq}{dV}\quad\therefore\quad dq=\rho dV\)

Thus, you can find the electric field for different objects/surfaces using charge density.

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Common Fields

Circulars

Ring

\(\vec E = k_e\frac{\lambda 2\pi Rz}{(z^2+R^2)^{3/2}}\hat z\)

Disk

\(\vec E=2\pi\sigma k_ez\left (\frac{1}{z}-\frac{1}{\sqrt{z^2+R^2}} \right )\hat z\)

Annulus

\(\vec E=2\pi\sigma k_ez\left (\frac{1}{\sqrt{r^2+z^2}}-\frac{1}{\sqrt{R^2+z^2}} \right )\hat z\)

Infinite Plane

Single Plane

\(\vec E=\frac{\sigma}{2\epsilon_0}\hat x\)

Two Planes

\(\vec E = \frac{\sigma}{\epsilon_0}\)

Hollow Sphere

Inside ($r < R_0$)

\(\vec E = 0\)

Outside ($r > R$)

\(\vec E = k_e\frac{Q}{r^2}\hat r\)

In ($R_0>r>R$)

\(\vec E = k_e\int \frac{dq}{r^2}\hat r=k_e\int \frac{\rho dV}{r^2}\hat r\)

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Electric Field Lines

Rules