Capacitors

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#UCLA #Y1Q3 #Physics1B

Capacitors

Key Definitions

Capacitor - 2 conductors of equal but opposite separated by a distance (used to store charge in an electric field)

Capacitance - the ratio of electric charge stored to difference in :

$C = \frac{Q}{V} [F]$

Where $Q$ is the charge on the positive conductor and $V$ is the potential difference between conductors

Properties of Conductors

$E = 0$ inside a conductor
$ρ = 0$ inside a conductor
Any net charge lies on the surface of a conductor
A conductor is an equipotential
$E$ is perpendicular to the surface outside the conductor

Properties of Capacitance

Capacitance is purely a geometric quantity determined by size, shape, and separation of the 2 conductors
Units of capacitance are farads, $F$
Charge $Q$ is considered the charge on the positive conductor
Electric potential $V$ is of the positive conductor
Capacitance is always a positive quantity

Geometric Capacitances

Sphere

Capacitance of a conducting sphere of radius $R$ :

$C = \frac{Q}{V} = 4 π ϵ_{0} R = \frac{R}{k_{e}} [F]$

Where $k_{e} \approx 9 \times 10^{9}$

Parallel Plate Capacitor

Capacitance of two conducting plates of area $A$ and separation $d$ :

$C = \frac{ϵ_{0} A}{d} [F]$

Given that

$V = E d = \frac{σ d}{ϵ_{0}} = \frac{Q d}{ϵ_{0} A}$

Capacitors

Energy

The electrical energy stored in a charged capacitor:

$U = \frac{1}{2} Q V = \frac{1}{2} \frac{Q^{2}}{C} = \frac{1}{2} C V^{2}$

Energy stored in the electric field:

$\frac{U}{Vol} = \frac{E^{2}}{2 ϵ_{0}}$

Discharging

Energy stored in capacitors can be released very quickly resulting in higher power

E.g. camera flash, lasers, spark-plugs, defibrillators

In Series

Series connections result in lower capacitance:

$\frac{1}{C_{e q}} = \sum_{i = 1}^{n} \frac{1}{C_{i}}$

In Parallel

Parallel connections increase capacitance:

Capacitors

Table of Contents

Capacitors

Key Definitions

$C = \frac{Q}{V} [F]$

Properties of Conductors

Properties of Capacitance

Geometric Capacitances

Sphere

$C = \frac{Q}{V} = 4 π ϵ_{0} R = \frac{R}{k_{e}} [F]$

Parallel Plate Capacitor

$C = \frac{ϵ_{0} A}{d} [F]$

$V = E d = \frac{σ d}{ϵ_{0}} = \frac{Q d}{ϵ_{0} A}$

Capacitors

Energy

$U = \frac{1}{2} Q V = \frac{1}{2} \frac{Q^{2}}{C} = \frac{1}{2} C V^{2}$

$\frac{U}{Vol} = \frac{E^{2}}{2 ϵ_{0}}$

Discharging

In Series

$\frac{1}{C_{e q}} = \sum_{i = 1}^{n} \frac{1}{C_{i}}$

In Parallel

$C_{e q} = \sum_{i = 1}^{n} C_{i}$

Capacitors

Table of Contents

Capacitors

Key Definitions

C=QV[F]

Properties of Conductors

Properties of Capacitance

Geometric Capacitances

Sphere

C=QV=4πϵ0R=Rke[F]

Parallel Plate Capacitor

C=ϵ0Ad[F]

V=Ed=σdϵ0=Qdϵ0A

Capacitors

Energy

U=12QV=12Q2C=12CV2

UVol=E22ϵ0

Discharging

In Series

1Ceq=∑i=1n1Ci

In Parallel

Ceq=∑i=1nCi

$C = \frac{Q}{V} [F]$

$C = \frac{Q}{V} = 4 π ϵ_{0} R = \frac{R}{k_{e}} [F]$

$C = \frac{ϵ_{0} A}{d} [F]$

$V = E d = \frac{σ d}{ϵ_{0}} = \frac{Q d}{ϵ_{0} A}$

$U = \frac{1}{2} Q V = \frac{1}{2} \frac{Q^{2}}{C} = \frac{1}{2} C V^{2}$

$\frac{U}{Vol} = \frac{E^{2}}{2 ϵ_{0}}$

$\frac{1}{C_{e q}} = \sum_{i = 1}^{n} \frac{1}{C_{i}}$

$C_{e q} = \sum_{i = 1}^{n} C_{i}$