Name: CAPACITOR - CAPACITANCIA
Uploaded: 2020-08-25T22:00:19.000Z
Duration: 30 min 44 s

CAPACITOR - CAPACITANCIA

Understanding Capacitors and Capacitance

Introduction to Capacitors

The lesson aims to explain capacitors (also known as condensers) and capacitance, which refers to the electrical capacity of a component.

Notes for this class will be available in the video description for free download and sharing among friends or students.

Basic Structure of a Capacitor

A capacitor consists of two conductive plates separated by a distance, initially electrically neutral with positive and negative charges distributed across their surfaces.

When connected to a voltage source via conductors, closing the circuit allows electrons from one plate to move towards the other, creating positive and negative charges on each plate.

Electric Field and Capacitance

The movement of charges generates an electric field directed from the positive plate to the negative plate. This setup enables charge storage.

Capacitance is defined as a component's ability to collect and store energy in the form of electric charge, calculated as the ratio between electric charge (Coulombs) and voltage (Volts).

Representation of Capacitors

The configuration can be represented with parallel lines indicating two plates; capacitors are often depicted in circuits using specific symbols.

Various designs exist for capacitors; examples include those found in electronic devices like routers.

Units of Measurement

In SI units, capacitance is measured in Farads (F), derived from Coulombs per Volt.

Commonly used subunits include microfarads (10^-6 F), nanofarads (10^-9 F), and picofarads (10^-12 F).

Practical Example: Calculating Charge

A practical problem involves installing a 1000 microfarad capacitor into a prototype board powered by two 3V batteries.

To find out how much charge this capacitor can store, use the formula: Charge = Capacitance × Voltage.

Solving for Charge Stored

Understanding Electric Flux

Understanding Electric Capacitance and Its Relationships

Key Concepts of Electric Permittivity

The concept of electric permittivity (ε₀) is introduced, representing the ability of materials (like air or dielectrics) to allow electric field flow and charge movement.

The relationship between electric flux, charge on plates, and potential difference (voltage) is established: voltage equals the product of electric field strength and distance between plates.

Capacitance Relationships

Capacitance can be expressed as a function of permittivity, area, and distance: C = εA/d . This indicates that capacitance increases with higher permittivity or larger plate area but decreases with greater distance.

A dielectric material can enhance capacitance by increasing permittivity. Conversely, increasing the distance between plates reduces capacitance.

Problem Solving with Capacitors

A practical problem involving a parallel plate capacitor is presented: it has an area of 3 times 10^-4 m^2 , a separation of 2 times 10^-3 m , and is connected to a 3V battery. The task involves calculating capacitance, charge on the positive plate, and the magnitude of the electric field.

Calculating Capacitance

The discussion emphasizes selecting appropriate relationships for calculations. Although voltage is known, charge isn't directly available; thus, using permittivity in vacuum (8.85 x 10^-12 C^2/(N·m^2)) along with area and distance allows for capacitance calculation.

Final Calculations

After performing calculations using given values for area and distance, the resulting capacitance is found to be approximately 1.33 × 10^-12 F.

To find charge ( Q_positive ), multiply calculated capacitance by voltage: Q = C × V = 1.33 × 10^-12 F × 3 V ≈ 4 × 10^-12 C, which translates to picoCoulombs.

Determining Electric Field Magnitude

The magnitude of the electric field ( E ) is derived from voltage divided by distance: E = V/d = 3V / (2 × 10^-3 m), yielding an electric field strength of approximately 1500 V/m.

Additional Notes