Materials Science and Engineering/Equations/Physics

Coulomb's Law

  $F = k \frac{Q_{1} Q_{2}}{r^{2}}$ 
  $F = \frac{1}{4 π ϵ_{0}} \frac{Q_{1} Q_{2}}{r^{2}}$

The Electric Field

  $𝐄 = \frac{𝐅}{q}$

  $d E = \frac{1}{4 π ϵ_{0}} \frac{d Q}{r^{2}}$

Superposition Principle

  $𝐄 = 𝐄_{1} + 𝐄_{2} + \dots$

Electric Flux

  $Φ_{E} = \int 𝐄 \cdot d 𝐀$

Gauss's Law

  $\oint \cdot d 𝐀 = \frac{Q_{e n c l}}{ϵ_{0}}$

Electrical Potential

  $V_{a} = \frac{U_{a}}{q}$

Relation between Electric Potential and Electric Field

  $U_{b} - U_{a} = \int_{a}^{b} 𝐅 \cdot d 𝐥$

  $V_{b a} = V_{b} - V_{a} = - \int_{a}^{b} 𝐄 \cdot d 𝐥$

Electrical Potential Due to Point Charges

  $E = \frac{1}{4 π ϵ} \frac{Q}{r^{2}}$

  $V = \frac{a}{4 π ϵ_{0}} \frac{Q}{r}$

Potential Due to Charge Distributions

  $V = \frac{1}{4 π ϵ_{0}} \int \frac{d q}{r}$

E Determined from V

  $C = \frac{Q}{V_{b a}} = ϵ_{0} \frac{A}{d}$

Electrical Energy Storage

  $W = \int_{0}^{Q} V d q = \frac{1}{C} \int_{0}^{Q} q d q = \frac{Q^{2}}{C}$

  $U = \frac{1}{2} C V^{2} = \frac{1}{2} (\frac{ϵ_{0} A}{d}) (E^{2} d^{2})$ 
  $U = \frac{1}{2} ϵ_{0} E^{2} A d$ 
  $u = energy density = \frac{1}{2} ϵ_{0} E^{2}$

Dielectrics

  $C = K C_{0}$ 
  $C = K ϵ_{0} \frac{A}{d}$ 
  $ϵ = K ϵ_{0}$ 
  $C = ϵ \frac{A}{d}$

  $u = \frac{1}{2} K ϵ_{0} E^{2} = \frac{1}{2} ϵ E^{2}$

  $Q = K Q_{0}$

  $V = \frac{V_{0}}{K}$

  $E_{0} = \frac{V_{0}}{d}$

  $E = E_{D} = \frac{V}{d} = \frac{V_{0}}{K d}$

  $E_{D} = \frac{E_{0}}{K}$

  $E_{D} = E_{0} - E_{i n d}$ 

  $E_{D} = \frac{E_{0}}{K}$

  $E_{i n d} = E_{0} (1 - \frac{1}{K})$

  $E_{0} = \frac{σ}{ϵ_{0}}$

  $σ = \frac{Q}{A}$

  $E_{i n d} = \frac{σ_{i n d}}{ϵ_{0}}$

  $E_{i n d} = E_{0} (1 - \frac{1}{K})$

  $σ_{i n d} = σ (1 - \frac{1}{K})$

  $Q_{i n d} = Q (1 - \frac{1}{K})$

Electric Current

  $I = \frac{d Q}{d t}$

Ohm's Law

  $R = \frac{V}{I}$

Resistivity

  $R = ρ \frac{l}{A}$

  $σ = \frac{1}{ρ}$

Electric Power

  $P = \frac{d U}{d t} = \frac{d q}{d t} V$

  $P = I V$

Current Density and Drift Velocity

  $I = \int 𝐣 \cdot d 𝐀$

  $Δ Q = (no. of charges, N) \times (charge per particle)$

  $Δ Q = (n V) (- e)$

  $Δ Q = - (n A v_{d} Δ t) (e)$

  $I = \frac{Δ Q}{Δ t} = - n e A v_{d}$

  $𝐣 = - n e 𝐯_{d}$

  $𝐣 = \sum_{i} n_{i} q_{i} 𝐯_{d i}$ 
  $I = \sum_{i} n_{i} q_{i} v_{d i} A$

  $𝐣 = σ 𝐄 = \frac{1}{ρ} 𝐄$

Force on Electric Current in a Magnetic Field

  $𝐅 = I 𝐥 \times 𝐁$

  $d 𝐅 = I d 𝐥 \times 𝐁$

Force on Moving Charge in Magnetic Field

  $𝐅 = q 𝐯 \times 𝐁$

Hall Effect

Electric field due to the separation of charge is the Hall field, $𝐄_{H}$

In equilibrium, the force from the electric field is balanced by the magnetic force $e v_{d} B$

  $e E_{H} = e v_{d} B$

Magnetic Field Due to Straight Wire

  $B = \frac{μ_{0}}{2 π} \frac{I}{r}$

Force between Two Parallel Wires

  $B_{1} = \frac{μ_{0}}{2 π} \frac{I_{1}}{d}$

Ampere's Law

  $\oint 𝐁 \cdot d 𝐥 = μ_{0} I_{e n c l}$

Biot-Savart Law

  $d 𝐁 = \frac{μ_{0} I}{4 π} \frac{d 𝐥 \times \hat{𝐫}}{r^{2}}$

Magnetic Fields in Magnetic Materials

  $B = μ n I$

Paramagnetism

Relative permeability:

  $K_{m} = \frac{μ}{μ_{0}}$

Magnetic susceptibility:

  $X_{m} = K_{m} - 1$

Magnetization vector, M:

  $𝐌 = \frac{μ}{V}$

Curie's law:

  $M = C \frac{B}{T}$

Faraday's Law of Induction

  $E = - \frac{d Φ_{B}}{d t}$ 
  $\oint 𝐄 \cdot d 𝐥 = - \frac{d Φ_{B}}{d t}$

Ampere's Law

  $\oint 𝐁 \cdot d 𝐥 = μ_{0} I_{e n c l} + μ_{0} ϵ_{0} \frac{d Φ_{E}}{d t}$

Gauss's Law of Magnetism

  $Φ_{B} = 𝐁 \cdot d 𝐀$ 
  $Φ_{B} = \oint 𝐁 \cdot d 𝐀$ 
  $\oint 𝐄 \cdot d 𝐀 = \frac{Q}{ϵ_{0}}$

Maxwell's Equations

  $\oint 𝐄 \cdot d 𝐀 = \frac{Q}{ϵ_{0}}$ 
  $\oint 𝐁 \cdot d 𝐀 = 0$ 
  $\oint 𝐄 \cdot d 𝐥 = - \frac{d Φ_{B}}{d t}$ 
  $\oint 𝐁 \cdot d 𝐈 = μ_{0} I + μ_{0} ϵ_{0} \frac{d Φ_{E}}{d t}$

Relation between Wavelength and Frequency

  $λ = \frac{c}{f}$

Relation between Frequency and ω

 $ω = 2 π f$

Poynting Vector

  $𝐒 = \frac{1}{μ_{0}} (𝐄 \times 𝐁)$

Index of Refraction

  $n = \frac{c}{ν}$

Reflection: Snell's Law

  $n_{1} \sin θ_{1} = n_{2} \sin θ_{2}$

Rayleigh Criterion

  $θ = \frac{1.22 λ}{D}$

Empirical Formula Proposed by Max Planck

  $I (λ, T) = \frac{2 π h c^{2} λ^{- 5}}{e^{h c / λ k T} - 1}$

Energy Emitted in Packets or Quanta

  $E = h f$

Wave Nature of Matter

  $λ = \frac{h}{p}$

Heisenberg Uncertainty Principle

  $(Δ x) (Δ p_{x}) \geq \frac{h}{2 π}$

One-Dimensional Time-Independent Schrödinger Equation

  $- \frac{ℏ^{2}}{2 m} \frac{d^{2} Ψ (x)}{d x^{2}} + U (x) Ψ (x) = E Ψ (x)$

Time-Dependent Schrödinger Equation

  $- \frac{ℏ^{2}}{2 m} \frac{\partial^{2} Ψ (x, t)}{\partial x^{2}} + U (x) Ψ (x, t) = i ℏ \frac{\partial Ψ (x, t)}{\partial t}$

  $Ψ (x, t) = ψ (x) e^{- i (\frac{E}{ℏ}) t}$

Solution to Schrödinger Equation - Free Particle

  $ψ = A \sin k x + B \cos k x$

  $k = \sqrt{\frac{2 m E}{ℏ^{2}}}$

Solution to Schrödinger Equation - Infinitely Deep Square Well

  $Ψ_{n} = \sqrt{\frac{2}{L}} \sin (\frac{n π}{L} x)$

Template:CourseCat

Materials Science and Engineering/Equations/Physics

Coulomb's Law

The Electric Field

Superposition Principle

Electric Flux

Gauss's Law

Electrical Potential

Relation between Electric Potential and Electric Field

Electrical Potential Due to Point Charges

Potential Due to Charge Distributions

E Determined from V

Electrical Energy Storage

Dielectrics

Electric Current

Ohm's Law

Resistivity

Electric Power

Current Density and Drift Velocity

Force on Electric Current in a Magnetic Field

Force on Moving Charge in Magnetic Field

Hall Effect

Magnetic Field Due to Straight Wire

Force between Two Parallel Wires

Ampere's Law

Biot-Savart Law

Magnetic Fields in Magnetic Materials

Paramagnetism

Faraday's Law of Induction

Ampere's Law

Gauss's Law of Magnetism

Maxwell's Equations

Relation between Wavelength and Frequency

Relation between Frequency and ω

Poynting Vector

Index of Refraction

Reflection: Snell's Law

Rayleigh Criterion

Empirical Formula Proposed by Max Planck

Energy Emitted in Packets or Quanta

Wave Nature of Matter

Heisenberg Uncertainty Principle

One-Dimensional Time-Independent Schrödinger Equation

Time-Dependent Schrödinger Equation

Solution to Schrödinger Equation - Free Particle

Solution to Schrödinger Equation - Infinitely Deep Square Well

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