General Physics Q2 Notes PDF

Summary

This document is a set of notes on electricity, covering topics like electric charge, current, voltage, resistance, and power. The notes are intended for a General Physics course.

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GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

W1: ELECTRICITY

A Electricity

Presence and flow of electric charges
Control the amount of electricity
A1 Electric Charge (q) Semiconductor - between the conductor
and insulator
Superconductors
The electrical nature of matter which is ○ Mostly metals - metalloids
inherent in its atomic structure (carried
by elementary particles)

Two general types:
○ Positive
○ Negative
Coulomb - SI unit of charge

Conductor

Parameters in an Electric Circuit
Any material that allows electric
current to pass through it
Voltage (V)- the difference in potential
energy between two points in the
electric circuit.
Current (C)- the amount of flow of
electric changes
Resistance (R) - a material’s tendency to
resist the flow of electric changes.

Voltage Across a Battery

Insulator The potential difference (electric
potential), or voltage, across the two
ends, or terminals, of a battery ranges
Any material that does not allow from about 1.5V for a small battery to
electric current to pass through it about 12 V for a car battery
○ Like the protective coating on Most batteries are electrochemical
wires cells–or groups of connected cells–that
convert chemical energy into electrical
energy.

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Electromotive force (EMF) is defined as
the electric potential produced by either
electrochemical cell or by changing the
magnetic field.
A generator or a battery is used for the
conversion of energy from form to
another.

Difference between EMF and Voltage

EMF - the electromotive force is the type of
Electric Potential And Potential Difference
energy which forces a unit positive charge to
move from the positive to the negative terminal
Batteries “lift”charges to a higher of the source. It separates the two charges from
potential each other.
There is a Potential Difference because VOLTAGE - the difference in electric potential
each coulomb of charge has a different between two points. The voltage between two
potential energy at either end of the points is equal to the work done per unit of
battery. charge against a static electric field to move a
test charge between two points

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12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Electric Current (I) More precisely, the electric current in
a wire is defined as the net amount of
an electric current is a flow of charged charge that passes through the wire’s
particles or current full cross section or any amount per
A current in a metal is due to the unit time.
movement of electrons
Thus, the current I is defined as:
Current is measured using an ammeter.
An ammeter measures the rate flow of
charge.
The unit of current is the Ampere (A). (1
amp. Of current = 1 coulomb of charge
per second)
Electric current is only present if there is
electric potential between two points

If the charges move around the
circuit in the same direction at all
times, the current is said to be direct
current (DC).
○ E.g. batteries
If the charges move first one way
and then the opposite way, the
current is said to be alternating
current (AC) - changes its direction
each half cycle.
○ E.g. household current

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Resistivity (ρ)

Resistivity is the property of the
conductor due to which it offers
resistance to the flow of current through
it
The better the conductor, the less its
resistance.
SI unit for resistivity is Ohm-meter
(Ω-meter)
Resistance (R)

The resistance of a conductor is a
measure of the opposition it offers to the
flow of electric current; SI unit of
resistance is Ohm(Ω)
A wire or an electrical device that offers
resistance to electrical flow is called a
resistor.
The resistance of a component causes
electrical energy to be converted into
heat
Resistance of a component causes
electrical energy to be converted into
heat
Resistance depend on the conductor’s
○ Length
○ Cross-sectional area
○ Type of material (e.g metals)
○ temperature

Resistors

A resistor is an electrical component
that limits on regulates the flow of
electrical current in an electronic
circuit

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12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

A2 OHM’s LAW

The higher the electric potential
difference or voltage between two points
in a circuit, the more charges can move
between these points.
Current (I) is directly proportional to
voltage (V) and inversely proportional
to resistance ®
This relationship as discovered by George
Ohm
↑V ↓I
↓V ↑I
↑R ↓I

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12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

↓R ↑I
↑R ↑V
↓R ↓V

In summary
Voltage, also called electromotive force, is
a quantitative expression of the potential
difference in charge between two points
in an electrical field.

Any flow of charge such as this is callen
an electric current.

Resistance is the hindrance to the flow of
charge. (Ohm)

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Energy - Power

Power = energy per unit time (Watt)
Energy = power x time
○ E.g. kilowatt-hour (kWh) -
used in electrical energy costs

,

A3 Electric Power (P)

The rate at which electric energy is
converted into another form such as
mechanical energy, heat, or light.
The power consumed by an electric
appliance is equal to the product of the
current flowing through it and the
voltage across it.
P=IV
SI unit: Watt (W)
The product of current (amp) and voltage
(volt)
The product of current (amp) and voltage
(volt)

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Direct Current Circuit

Direct current (DC) is an electric
current that is uni-directional, so the flow
of charge is always in the same direction
(from + to -)
The closed path in which the direct
current flows is called in DC circuit.
It is mostly used in low voltage
applications
The resistor is the main component of
the DC circuit.

W2: Electric Circuits

B Electric Circuits

Any path along which current and
electron can flow
Unbroken path of material that carries
electricity
It consists of an energy source and an
energy consuming device which are
connected by conducting wires through
which electric charges move

Within a battery, a chemical reaction
occurs that transfers electrons and
charges from one terminal to another
terminal.
The maximum potential difference
across the terminals is provided and
maintained by the electromotive force
(EMF).

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12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Voltage Rise = Voltage Drop
Series Circuits
Voltage Rise - supplied by battery
Encounter resistors = Voltage Drop
Series: two or more loads are linked Voltage Rise = Total of each Voltage Drop
across a single loop of wire SERIES CIRCUIT (PROBLEM SOLVING)
○ The current is the same at all
points in a series circuit
○ Total resistance to current in this
circuit is the sum of the individual
resistances along the path.

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12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Parallel Circuits

Parallel: different loads are situated on
different wire loops
Junctions
○ Components connected in
parallel with each other all have
the same voltage
○ Each path operates
independently of the other paths
○ Total current in this circuit
equals the sum of the currents
in its parallel branches
○ As the number of parallel
branches is increased,
resistance of the circuits is
decreased.
Parallel circuits are prone to overloading

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

PRACTICE EXERCISE:

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Grounding a negatively charged
electroscope involves the transfer of
electrons from the electroscope to “the
ground”
Grounding a positively-charged
electroscope involves the transfer of
electrons from “the ground” to the
electroscope.
GROUND - grounding to the earth, to pass
through the electric current, that can prevent
electric shock

C Some Medical Application of Electric Physiological Effects of Electric Current
Current
Depends on the resistance of one’s body
(depending on its condition: wet/dry)
The severity of electrical injury depends
on the magnitude of the current and the
parts of the body through which the
moving charges pass.
Mild tingling sensation: 0.001 A
Muscle spasms (“can’t let go”): 0.01-0.02
A
Fatal (heart fibrillation) 0.2 A

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

W3: WORK ENERGY AND POWER

D WORK

Is done when there is motion (scalar
quantity)
Result of a force acting upon an object to
case a displacement of the object
○ Force
○ Displacement
○ Cause
In order for a force to qualify as having
done work on an object, there must be a
displacement and the force must be the
cause of that displacement.
Determine whether or not they represent
work:

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Types of Work

Work against inertia
○ Applying force to cause change in
motion (e.g. throwing/kicking a
ball)
○ W = Fd= mgh

Work against gravity
○ Involves height
○ W= mgh
Work in going up and going down will
always be equal no matter how slow or
how quick the person moved.

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 GENERAL PHYSICS
12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

○ Work = Energy
Both are scalar quantities; same unit
(Joules)
Types:
○ Kinetic energy
○ Potential energy

Potential Energy

The energy of objects at rest; stored
energy
○ Gravitational potential energy
○ Elastic potential energy

Elastic Potential Energy

Energy stored in elastic materials as the
result of stretching or compressing
○ E.g rubber bands, bungee chords,
trampolines, springs, arrow drawn
into a bow

E ENERGY

Ability to do work; expressed in Joules
No energy, no work is done
Property of a body or system of bodies
by which work can be done or
performed
The energy possessed by a body is
equal to the total work it can do

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Gravitational Potential Energy

GPE of an object equals its weight ties its
height above the ground
GPE is stored as the result of the
gravitational attraction of the Earth for
the object
GPE= mgh
GPE is directly proportional to both mass
and height.

Kinetic Energy

The energy of objects in motion
○ Once the object at rest starts
moving, the PE it has will then be
converted to KE

SAMPLE PROBLEMS

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12HA-12 1st 1SEMESTER, Q2 – Ma’am Lalaine Prado – ‘24-’25

Work-Energy Theorem

Work = Energy
The theorem states that the net change
in KE of a particle (system) is a equivalent
to the sum of work done by all types of
external forces

The kinetic energy of an object increases
as a result of the amount of work. Work
done on an object transfers energy to the
object.

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The longer the time, the lesser the power
F POWER
extended
↑t↓p
The rate at which work is done ↓ t↑ p
The rate at which energy is expended
Power is the amount of work done
divided by the time it takes to do it.
Power is the energy
expended/transformed divided by the
time it takes to do it.
Power is the energy
expended/transformed divided by the
time it takes to expend it.
SI uniform power = Watt (W)

1 horsepower = 550 ft-lb of
work/second = 746 watts or 0.746
kilowatt
Power is the rate at which energy is transferred
or the rate at which work is done.

Work and Power

Work has nothing to do with the amount
of time the force acts to cause the
displacement
○ E.g A person going up and down
the stairs
For power, time is inversely proportional.
Therefore, the shorter the time the work
is done, the higher the power extended.

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TABLE TITLE

KEY TERM Definition Example

KEY TERM Definition Example

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