⚡️College Physics III – Thermodynamics, Electricity, and Magnetism Unit 8 – Capacitance in Electrical Systems

Capacitance is a fundamental concept in electrical systems, measuring a capacitor's ability to store electric charge. This unit explores the structure, function, and types of capacitors, as well as their role in circuits and energy storage applications. Capacitors consist of two conducting plates separated by a dielectric material. They store energy in electric fields, act as filters in circuits, and find use in various applications. Understanding capacitance calculations, circuit behavior, and real-world uses is crucial for electrical engineering and physics students.

Study Guides for Unit 8

8.1

Capacitors and Capacitance

4 min read

8.2

Capacitors in Series and in Parallel

3 min read

8.3

Energy Stored in a Capacitor

3 min read

8.4

Capacitor with a Dielectric

3 min read

8.5

Molecular Model of a Dielectric

4 min read

Key Concepts and Definitions

Capacitance measures a capacitor's ability to store electric charge, denoted by the symbol $C$ and measured in farads ( $F$ )
Electric field intensity $E$ represents the force per unit charge experienced by a test charge in an electric field, measured in newtons per coulomb ( $N/C$ ) or volts per meter ( $V/m$ )
Electric potential difference $\Delta V$ is the work done per unit charge to move a positive test charge from one point to another in an electric field, measured in volts ( $V$ )
Dielectric constant $\kappa$ (also known as relative permittivity) compares the permittivity of a material to that of vacuum, influencing the capacitance of a capacitor
Dielectric strength refers to the maximum electric field a dielectric material can withstand before breakdown occurs, measured in volts per meter ( $V/m$ )
Parallel plate capacitor consists of two parallel conducting plates separated by a dielectric material or vacuum, with capacitance given by $C = \frac{\kappa \varepsilon_0 A}{d}$
Capacitive reactance $X_C$ represents the opposition to the flow of alternating current (AC) in a capacitor, measured in ohms ( $\Omega$ ) and calculated as $X_C = \frac{1}{2\pi fC}$

Capacitors: Structure and Function

Capacitors store electric charge and energy in an electric field between two conducting plates
Consist of two conducting plates separated by an insulating material called a dielectric
Plates accumulate equal and opposite charges when connected to a voltage source, creating an electric field between them
Capacitance depends on the area of the plates, the distance between them, and the dielectric constant of the insulating material
Act as open circuits to direct current (DC) and allow alternating current (AC) to pass through, making them useful for filtering and signal processing
Prevent sudden changes in voltage across their terminals, providing a smoothing effect in power supplies
Used in various applications such as energy storage, signal filtering, and voltage regulation

Types of Capacitors

Ceramic capacitors use ceramic dielectric materials, offer high dielectric constants, and are suitable for high-frequency applications
Electrolytic capacitors (aluminum and tantalum) provide high capacitance values in a compact size but are polarized and have lower voltage ratings
- Aluminum electrolytic capacitors are commonly used in power supplies and filtering applications
- Tantalum capacitors offer higher capacitance density and better temperature stability compared to aluminum electrolytic capacitors
Film capacitors (polyester, polypropylene, and polystyrene) have low losses and are suitable for high-frequency and high-voltage applications
Mica capacitors offer high stability, low losses, and high voltage ratings, making them suitable for high-frequency and high-voltage applications
Variable capacitors (air or vacuum dielectric) allow for adjustable capacitance, used in radio and television tuning circuits
Supercapacitors (also known as ultracapacitors) store large amounts of energy and have high power density, used in energy storage and power backup systems

Capacitance Calculations

Capacitance $C$ is the ratio of the charge $Q$ stored on each plate to the potential difference $\Delta V$ between the plates, given by $C = \frac{Q}{\Delta V}$
For a parallel plate capacitor, capacitance is calculated using the formula $C = \frac{\kappa \varepsilon_0 A}{d}$ , where $\kappa$ is the dielectric constant, $\varepsilon_0$ is the permittivity of free space ( $8.85 \times 10^{-12} F/m$ ), $A$ is the area of the plates, and $d$ is the distance between the plates
Capacitors in series have an equivalent capacitance $C_{eq}$ $C_{e q}$ given by $\frac{1}{C_{eq}} = \frac{1}{C_1} + \frac{1}{C_2} + ... + \frac{1}{C_n}$ $\frac{1}{C _{e q}} = \frac{1}{C _{1}} + \frac{1}{C _{2}} + ... + \frac{1}{C _{n}}$
- Voltage across each capacitor in series is inversely proportional to its capacitance
- Total voltage across the series combination equals the sum of the voltages across individual capacitors
Capacitors in parallel have an equivalent capacitance $C_{eq}$ $C_{e q}$ given by $C_{eq} = C_1 + C_2 + ... + C_n$ $C_{e q} = C_{1} + C_{2} + ... + C_{n}$
- Voltage across each capacitor in parallel is the same
- Charge stored in the parallel combination equals the sum of the charges stored in individual capacitors
Capacitive reactance $X_C$ in an AC circuit is calculated using the formula $X_C = \frac{1}{2\pi fC}$ , where $f$ is the frequency of the AC signal

Capacitors in Circuits

Act as open circuits to DC, preventing the flow of steady-state current
Allow AC to pass through, with the amount of current flow dependent on the capacitance and frequency
Introduce a phase shift between voltage and current in AC circuits, with current leading voltage by 90 degrees
In RC circuits, the time constant $\tau = RC$ $τ = RC$ determines the charging and discharging behavior of the capacitor
- Capacitor charges to 63.2% of its final value in one time constant during the charging process
- Capacitor discharges to 36.8% of its initial value in one time constant during the discharging process
Used in various applications such as filtering, coupling, decoupling, and energy storage
Capacitive filters (low-pass, high-pass, and band-pass) can be designed using capacitors and resistors to control the frequency response of a circuit
Coupling capacitors allow AC signals to pass while blocking DC, used in audio and signal processing circuits

Energy Storage in Capacitors

Energy stored in a capacitor is given by $U = \frac{1}{2}CV^2$ , where $U$ is the energy in joules ( $J$ ), $C$ is the capacitance in farads ( $F$ ), and $V$ is the voltage across the capacitor in volts ( $V$ )
Energy density of a capacitor is the amount of energy stored per unit volume, expressed in joules per cubic meter ( $J/m^3$ )
Capacitors can release stored energy quickly, making them suitable for applications requiring high power density
Supercapacitors have higher energy density compared to conventional capacitors, bridging the gap between capacitors and batteries
Capacitors are used in power supplies, uninterruptible power systems (UPS), and energy harvesting devices to store and release energy as needed
Charging and discharging cycles of capacitors can be used to generate high-voltage pulses in applications such as flash photography and pulsed lasers

Dielectrics and Their Effects

Dielectric materials are insulators placed between the plates of a capacitor to increase its capacitance
Dielectric constant $\kappa$ (relative permittivity) represents the factor by which the capacitance increases when a dielectric is inserted between the plates
Polarization of dielectric molecules in the presence of an electric field contributes to the increased capacitance
Dielectric strength is the maximum electric field a dielectric can withstand before breakdown occurs, an important factor in capacitor design and selection
Dielectric loss (dissipation factor) represents the energy lost as heat in the dielectric material when subjected to an alternating electric field
Common dielectric materials include ceramic, polymer films (polyester, polypropylene, and polystyrene), mica, and electrolytes (in electrolytic capacitors)
Dielectric materials with high dielectric constants (high-k dielectrics) are used in advanced capacitor designs to achieve higher capacitance values in smaller packages

Real-World Applications

Power supply smoothing and filtering: Capacitors are used to reduce ripple and noise in DC power supplies, ensuring a stable output voltage
AC coupling and DC blocking: Coupling capacitors allow AC signals to pass while blocking DC components, used in audio and signal processing circuits
Energy storage and power backup: Capacitors, particularly supercapacitors, are used in uninterruptible power supplies (UPS), energy harvesting systems, and regenerative braking systems in electric vehicles
Tuned circuits and resonance: Capacitors are used in combination with inductors to create tuned circuits for frequency selection and filtering in radio and television systems
Motor starting and power factor correction: Capacitors provide reactive power compensation and improve power factor in AC motor starting and power distribution systems
Touchscreens and sensors: Capacitive sensing is used in touchscreens, proximity sensors, and moisture detectors, relying on the change in capacitance caused by human touch or the presence of objects
Pulsed power applications: Capacitors are used to generate high-voltage, high-current pulses in applications such as flash photography, pulsed lasers, and electromagnetic forming
Electromagnetic interference (EMI) suppression: Capacitors are used in EMI filters to suppress high-frequency noise and interference in electronic systems