The document discusses key concepts about electricity including:
- Electric current is the flow of charged particles in a circuit. It is measured in amperes.
- Voltage is the electric potential difference between two points in a circuit. It drives the electric current and is measured in volts.
- Resistance opposes the flow of current and is measured in ohms. It varies based on the material's properties.
- Ohm's law states the relationship between current, voltage, and resistance in a circuit. Increased resistance decreases current.
3. CIRCUIT
Is any arrangement of materials
that provides a path for electrons
to flow.
It consists of a source of electrical
energy, connecting wires and a
load.
4.
5. ELECTRIC
CURRENT
-> is the movement of charged particles in a
specific direction.
-> is a measure of the number of electrical
charges passing through a cross section of a
conductor in a given time.
I =
𝑞
𝑡
Where: I = current
q = electrical Charge
t = time
7. CONVENTIONAL CURRENT OR SIMPLY
CURRENT
-> is the movement of charges from the
positive side of the battery to the negative
side.
ELECTRON CURRENT
-> is the direction of the flow of electrons is
from the negative terminal to the positive
terminal.
**The direction of current does not affect what
the current does.
8. ELECTRIC
CURRENT
The unit, ampere (A), is named after
Andre-Marie Ampere, a French physicist
who made important contributions to the
theory of electricity and magnetism.
1 ampere means that there is 1 coulomb of
charge passing through a cross section of a
wire every 1 second.
ammeter measures electric current or
measures how much charges flow in a
certain cross section at a given time, it has
to be connected in series.
9. Shows how the ammeter is connected in a circuit.
The positive terminal of an ammeter is connected
to the positive terminal of the energy source (e.g.
battery) while the negative terminal is connected to
the negative terminal of the energy source.
13. VOLTAGE (V)
-> is the potential difference between two points in an
electric field.
-> is the work done on the charges as it passes through a
load is measured as the voltage across the load.
V=
Where: V = voltage
W = Work
q = charge
*A voltmeter measures voltage.
*The unit of voltage is volt (V), named after Alessandro Volta
who invented the voltaic pile, the forerunner of what we now
call the dry cell.
𝑊
𝑞
14.
15. VOLTAGE (V)
The voltmeter must be connected parallel or
across the load. The positive terminal of a
voltmeter is connected to the positive terminal of
the bulb while the negative terminal is connected
to the negative terminal of the bulb.
16. Calculating Current and Voltage
Samples:
1. A charge of 825 coulombs was passed
through a wire in 1 minute. What was the
average electric current during that
interval?
2. Calculate the Voltage if 300 Joules of
work is used to move a charge of 150 C?
18. RESISTANCE
• As the term implies, the resistance of the
material opposes the flow of charges.
-> is the opposition of a material offers to
current.
-> it can also be measured and they are
expressed in units called Ohms (Ω), named
after the German physicist Georg Simon
Ohm.
19. OHM’S LAW
States that “Current is directly proportional
to the Voltage and inversely proportional to
the resistance.”
I =
𝑉
𝑅
Where: I = Current
V = Voltage
R = Resistance
21. Factors Affect Resistance
1. A lower resistance would mean that there
is less opposition in the flow of charges
and therefore bigger current.
2. Different materials have different
amounts of resistance.
– Conductors definitely have very little resistance
and therefore allow more charges to pass through.
– Insulators are materials that have very high
resistance and therefore flow of charges would be
difficult.
22. Factors Affect Resistance
3. The length and thickness of the conducting
wire are factors that affect resistance
encountered by current. The longer the wire the
greater will be its resistance and the greater the
cross sectional area (a measure of the thickness
of the wire), the lower will be its resistance.
4. The resistance of an object also changes when
the object becomes wet.
Ex. Dry human skin for instance has a resistance
of 100,000 Ω but when it gets wet its resistance is
reduced to 1,000 Ω .
23. QUANTITY SYMBOL EQUATION/S SI UNIT OTHER UNIT/S
UNIT NAMED
AFTER
DEVICE USED
TO MEASURE
CURRENT I
I =
𝑞
𝑡
I =
𝑉
𝑅
Ampere
(A)
C/s
(Coulomb per
Second)
V/Ω
(Volt per ohm)
Andre-
Marie
Ampere
Ammeter
VOLTAGE V
V = IR
V =
𝑾
𝒒
Volt
(V)
J/C
(Joule per
Coulomb)
Alessandr
o Volta
Voltmeter
RESISTANCE R R =
𝑽
𝑰
Ohm
(Ω)
V/A
(Volt per Ampere)
Georg
Simon
Ohm
Ohm
meter
27. TYPES OF CONNECTION
SERIES CONNECTION
-> is the loads are connected to form a
single pathway for electric charges to
pass.
PARALLEL CONNECTION
-> is the loads are connected to form
branches, each of which provides a
28.
29.
30. Why do wires heat up when
there is too much current?
31. HEATING EFFECT OF
CURRENT
1. Overloading of the circuit
ex. plugging a lot of appliances in a
common outlet like an extension cord.
2. Short circuits - happen when wires with
defective rubber insulation touch each
other so the current does not pass to the
supposed path it should take.
32. Why do wires heat up when
there is too much current?
In the wires, the electrons that flow in a
closed circuit collide with the atoms of the
conducting wire. As the collisions take place
the kinetic energy of the metal atoms
increases. The increased kinetic energy of
the atoms is dissipated as heat.
33. Remember:
The higher the current passing through
the wire, the more collisions between the
electrons and the atoms of the wire take
place. In the end the wire will become
hot.