Physics Notes - Electric Field PDF

Summary

These notes cover fundamental concepts of electric fields, including electric charge, its properties, different types of materials, charging methods, Coulomb's Law, vector resolution, and superposition. The document uses mathematical formulas and diagrams to explain the topics.

Full Transcript

# Chapter Flectric Field

## Introduction

* Electric charge *q*
* +ve Charge Ex: Protons & +ve ions
* -ve charge Ex: electrons & -ve ions
* Charges Can't be Created, it already exists in isolated Systems.

## Properties of electric charges

1. ***Quantized:*** Because charges are exist in integer multiples of electron charge

$q = \pm Ne$
* q = charge
* N = integer
* e = electron charge

* electron charge = -e
* Proton charge = +e

2. ***Conservation:***
* If a reaction involves charged particles.
* The total charge before and after the reaction are the Same.
* No reaction that creates or destroys any electric charge

## Materials

* **conductors:** (rich of electrons)
* like Cu
* Fe
* **Semiconductors:**
* between
* like Si
* Ge
* **Insolators:** (Poor of electrons)

## Charging by:-

1. ***Conduction:***
* Require contact between the object and the charge
* Produce the Same charge

2. ***Induction:***
* Require No contact between the object and the charge
* Produce the opposite charge

## Coulomb's Law

* Measure the Force *F* between 2 point charges
* Point charge: refers to a particle of Zero Size carries an electric charge.

* Coulomb's Law states that: *F12* the electric force between 2 point charges directed along the line joining 2 point charges.

* $F \propto \frac{q_1q_2}{r^2}$
* $F = K_e\frac{|q_1q_2|}{r^2}$ $N$ Newtons.
* $K_e$ Constant:
* $K_e = \frac{1}{4\pi\epsilon_o}$ = $8.99 \times 10^9 \frac{Nm^2}{C^2}$
* $\epsilon_o$ : Permittivity of free space = $8.85 \times 10^{-12} \frac{C^2}{Nm^2}$.

## Resolution

* Components of a vector

* The Vector *A* can be represented by
$A = A_x i + A_y j$

* Where:
* *i*: is a unit vector in *x* direction
* *j*: is a unit vector in *y* direction
* *k*: is a unit vector in *z* direction
* *A_x, A_y*: are the components of the vector in *x, y* respectively.
* $A_x$ = *A* cos θ
* $A_y$ = *A* sin θ
* $A = \sqrt{A_x^2 + A_y^2}$ (magnitude)
* θ = $tan^{-1}\frac{A_y}{A_x}$ (direction)

## Super Position

* Similar charges: repulsion force
* Opposite charges: attraction force

* If there are more than two charges, the net force on the charge is the Vector Sum of all forces on this charge.

* $F = F_1 + F_2 + F_3 .... $

* $\sum Fx = F_1 cos θ + F_2 cos φ$
* $F y = F_1 sin θ + F_2 sin φ$

* magnitude = |F| = $√(F_x ^ 2 + F_y ^ 2 )$
* direction = φ = $tan^{-1}\frac{F_y}{F_x}$.

* Total Force using resolution of vectors

* $F_x = F_1 cos θ + F_2 cos φ$
* $F_y = F_1 sin θ - F_2 sin φ$

* magnitude = $√(F_x ^ 2 + F_y ^ 2 )$
* direction = θ = $tan^{-1} \frac{F_y}{F_x}$

| Prefix | Symbol | Value |
|---|---|---|
| Tera | T | 10¹² |
| Giga | G | 10⁹ |
| Mega | M | 10⁶ |
| Kilo | K | 10³ |
| milli | m | 10⁻³ |
| micro | µ | 10⁻⁶ |
| nano | n | 10⁻⁹ |
| pico | p | 10⁻¹² |