The document discusses electric circuits and key concepts related to electricity. It begins with an introduction to electricity and its importance in modern society. The main body is divided into sections covering basic concepts:
1. Current is defined as the flow of electrons through a conductor measured in amperes.
2. Voltage or electric potential difference provides the force that causes electric current and is measured in volts.
3. Resistance opposes the flow of electric current and depends on the material, length, and cross-sectional area of the conductor.
It then gives an example problem calculating the resistance of a copper wire of a given length and gauge.
life style of great scientist Michael Faraday .....!
Michael Faraday, who came from a very poor family, became one of the greatest scientists in history. His achievement was remarkable in a time when science was the preserve of people born into privileged families. The unit of electrical capacitance is named the farad in his honor, with the symbol F.
The faraday is a dimensionless unit of electric charge quantity, equal to approximately 6.02 x 10 23 electric charge carriers. This is equivalent to one mole , also known as Avogadro's constant .
Education and Early Life
Michael Faraday was born on September 22, 1791 in London, England, UK. He was the third child of James and Margaret Faraday. His father was a blacksmith who had poor health. Before marriage, his mother had been a servant. The family lived in a degree of poverty.
Michael Faraday attended a local school until he was 13, where he received a basic education. To earn money for the family he started working as a delivery boy for a bookshop. He worked hard and impressed his employer. After a year, he was promoted to become an apprentice bookbinder
Michael Faraday’s Scientific Achievements and Discoveries:
It would be easy fill a book with details of all of Faraday’s discoveries – in both chemistry and physics. It is not an accident that Albert Einstein used to keep photos of three scientists in his office: Isaac Newton, James Clerk Maxwell and Michael Faraday.
Funnily enough, although in Faraday’s lifetime people had started to use the word physicist, Faraday disliked the word and always described himself as a philosopher. 1821: Discovery of Electromagnetic Rotation
This is a glimpse of what would eventually develop into the electric motor, based on Hans Christian Oersted’s discovery that a wire carrying electric current has magnetic properties.
1823: Gas Liquefaction and Refrigeration
In 1802 John Dalton had stated his belief that all gases could be liquified by the use of low temperatures and/or high pressures. Faraday provided hard evidence for Dalton’s belief by applying pressure to liquefy chlorine gas and ammonia gas for the first time.
1825: Discovery of Benzene
Historically, benzene is one of the most important substances in chemistry, both in a practical sense – i.e. making new materials; and in a theoretical sense – i.e. understanding chemical bonding. Michael Faraday discovered benzene in the oily residue left behind from producing gas for lighting in London.
1831: Discovery of Electromagnetic Induction
Faraday discovered that a varying magnetic field causes electricity to flow in an electric circuit.
1834: Faraday’s Laws of Electrolysis
This is the science of understanding what happens at the interface of an electrode with an ionic substance. Electrochemistry is the science that has produced the Li ion batteries and metal hydride batteries capable of powering modern mobile technology. Faraday’s laws are vital to our understanding of electrode reactions.
life style of great scientist Michael Faraday .....!
Michael Faraday, who came from a very poor family, became one of the greatest scientists in history. His achievement was remarkable in a time when science was the preserve of people born into privileged families. The unit of electrical capacitance is named the farad in his honor, with the symbol F.
The faraday is a dimensionless unit of electric charge quantity, equal to approximately 6.02 x 10 23 electric charge carriers. This is equivalent to one mole , also known as Avogadro's constant .
Education and Early Life
Michael Faraday was born on September 22, 1791 in London, England, UK. He was the third child of James and Margaret Faraday. His father was a blacksmith who had poor health. Before marriage, his mother had been a servant. The family lived in a degree of poverty.
Michael Faraday attended a local school until he was 13, where he received a basic education. To earn money for the family he started working as a delivery boy for a bookshop. He worked hard and impressed his employer. After a year, he was promoted to become an apprentice bookbinder
Michael Faraday’s Scientific Achievements and Discoveries:
It would be easy fill a book with details of all of Faraday’s discoveries – in both chemistry and physics. It is not an accident that Albert Einstein used to keep photos of three scientists in his office: Isaac Newton, James Clerk Maxwell and Michael Faraday.
Funnily enough, although in Faraday’s lifetime people had started to use the word physicist, Faraday disliked the word and always described himself as a philosopher. 1821: Discovery of Electromagnetic Rotation
This is a glimpse of what would eventually develop into the electric motor, based on Hans Christian Oersted’s discovery that a wire carrying electric current has magnetic properties.
1823: Gas Liquefaction and Refrigeration
In 1802 John Dalton had stated his belief that all gases could be liquified by the use of low temperatures and/or high pressures. Faraday provided hard evidence for Dalton’s belief by applying pressure to liquefy chlorine gas and ammonia gas for the first time.
1825: Discovery of Benzene
Historically, benzene is one of the most important substances in chemistry, both in a practical sense – i.e. making new materials; and in a theoretical sense – i.e. understanding chemical bonding. Michael Faraday discovered benzene in the oily residue left behind from producing gas for lighting in London.
1831: Discovery of Electromagnetic Induction
Faraday discovered that a varying magnetic field causes electricity to flow in an electric circuit.
1834: Faraday’s Laws of Electrolysis
This is the science of understanding what happens at the interface of an electrode with an ionic substance. Electrochemistry is the science that has produced the Li ion batteries and metal hydride batteries capable of powering modern mobile technology. Faraday’s laws are vital to our understanding of electrode reactions.
Model Attribute Check Company Auto PropertyCeline George
In Odoo, the multi-company feature allows you to manage multiple companies within a single Odoo database instance. Each company can have its own configurations while still sharing common resources such as products, customers, and suppliers.
Read| The latest issue of The Challenger is here! We are thrilled to announce that our school paper has qualified for the NATIONAL SCHOOLS PRESS CONFERENCE (NSPC) 2024. Thank you for your unwavering support and trust. Dive into the stories that made us stand out!
How to Make a Field invisible in Odoo 17Celine George
It is possible to hide or invisible some fields in odoo. Commonly using “invisible” attribute in the field definition to invisible the fields. This slide will show how to make a field invisible in odoo 17.
Francesca Gottschalk - How can education support child empowerment.pptxEduSkills OECD
Francesca Gottschalk from the OECD’s Centre for Educational Research and Innovation presents at the Ask an Expert Webinar: How can education support child empowerment?
Synthetic Fiber Construction in lab .pptxPavel ( NSTU)
Synthetic fiber production is a fascinating and complex field that blends chemistry, engineering, and environmental science. By understanding these aspects, students can gain a comprehensive view of synthetic fiber production, its impact on society and the environment, and the potential for future innovations. Synthetic fibers play a crucial role in modern society, impacting various aspects of daily life, industry, and the environment. ynthetic fibers are integral to modern life, offering a range of benefits from cost-effectiveness and versatility to innovative applications and performance characteristics. While they pose environmental challenges, ongoing research and development aim to create more sustainable and eco-friendly alternatives. Understanding the importance of synthetic fibers helps in appreciating their role in the economy, industry, and daily life, while also emphasizing the need for sustainable practices and innovation.
Macroeconomics- Movie Location
This will be used as part of your Personal Professional Portfolio once graded.
Objective:
Prepare a presentation or a paper using research, basic comparative analysis, data organization and application of economic information. You will make an informed assessment of an economic climate outside of the United States to accomplish an entertainment industry objective.
2. 1. INTRODUCTION
Electricity has an important place in
modern society. It is a controllable and
convenient form of energy for a variety
of uses in homes, schools, hospitals,
industries and so on.
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
▪ What constitutes electricity?
▪ How does it flow in an electric
circuit?
▪ What are the factors that
control or regulate the current
through an electric circuit?
3. NOTE TAKING
In this section we will talk about the
main magnitudes of electricity.
During the explanations, identify the
following information and complete
it on the table.
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
Definition
Hydraulic
analogy
Symbol and
Units
Current
Voltage
Resistance
4. 2. CURRENT
You are familiar with air current and water current.
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
Similarly, if electrons flow through a
conductor (for example a metallic wire),
we say that there is an electric current
in the conductor.
Units: Electric current is expressed by -the amount of charge flowing
through a particular area in unit time-. The unit is called ampere (A), named
after the French scientist, Andre-Marie Ampere (1775–1836).
In river current, there is a flow of water
molecules.
Symbol: current is represented with an “I” (intensity)
5. 3. VOLTAGE (Potential Difference)
What makes the water molecules (electrons) to
flow in a river (copper wire)?
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
Charges do not flow in a copper wire by
themselves, just as water in a perfectly horizontal
tube does not flow.
For flow of charges in a conducting metallic wire, the
electrons move only if there is a difference of electric
pressure –potential difference – along the conductor.
If one end of the tube is connected to a tank of water
kept at a higher level, such that there is a pressure
difference between the two ends of the tube, water
flows out of the other end of the tube.
Potential
difference
Potential
difference
Units: It is measured in volts, named after the Italian
physicist Alessandro Volta who invented the first
chemical battery.
Symbol: Voltage is represented in equations by the letter "V".
6. 4. RESISTANCE
Resistance, as the name suggests, always tries
to stop the current from flowing. In the case of
the flow of water through pipes, the resistance
would be the frictional effects between water
and the pipe surfaces as well as the resistance
offered by obstacles that are present in its path
(like the constriction of a water pipe or a hose). It
is this resistance that hinders the water flow and
reduces both its flow rate and its drift speed.
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
Units: The SI unit for resistance is ohm, represented by the Greek letter Ω.
Symbol: Resistance is represented in equations by the letter “R".
In electricity, resistance is the property of a conductor to resist the flow of
charges. The circuit with the higher resistance will allow less charge to flow,
meaning the circuit with higher resistance has less current flowing through
it.
7. 4. FACTORS ON WHICH THE RESISTANCE OF A CONDUCTOR DEPENDS
The resistance of the conductor depends on its length, on its cross-sectional
area, and on the nature of its material as follow:
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
Length: The longer the wire, the
more resistance that there will be.
After all, if resistance occurs as the
result of collisions between charge
carriers and the atoms of the wire,
then there is likely to be more
collisions in a longer wire. More
collisions mean more resistance.
𝑅 ∝ 𝑙
Cross-sectional area:
Water will flow through with lower
amount of resistance in a wider pipe.
In the same manner, the wider the
wire, the less resistance that there
will be to the flow of electric charge.
Resistance and area are inversely
proportional.
𝑅 ∝
1
𝐴
Combining both equations we get that:
𝑅 ∝
𝑙
𝐴
𝑜𝑟, 𝑅 ∝ 𝜌
𝑙
𝐴
where ρ (rho) is a constant of proportionality and is called the electrical
resistivity of the material of the conductor.
8. 4. FACTORS ON WHICH THE RESISTANCE OF A CONDUCTOR DEPENDS
The resistance of the conductor depends on its length, on its cross-sectional
area, and on the nature of its material as follow:
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
INTRODUCTION TO ELECTRICITY
Resistivity of the material:
The resistivity (Ω m) is a
characteristic property of the
material. The metals and alloys
have very low resistivity in the
range of 10–8 Ω m to 10–6 Ω m.
They are good conductors of
electricity. Insulators like rubber
and glass have resistivity of the
order of 1012 to 1017 Ω m.
Alloys do not oxidise (burn)
readily at high temperatures. For
this reason, they are commonly
used in electrical heating
devices, like electric iron,
toasters etc. Copper and
aluminium are generally used for
electrical transmission lines.
9. SAMPLE PROBLEM : Determine the resistance
of a 20-mile length of 12-gauge copper wire.
Given:
1 mi = 1609 meters
Diameter of 12-gauge wire = 0.2117 cm.
INTRODUCTION TO ELECTRICITY
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
STEP 1: Identify data:
Lenght → 𝑙 = 20 mi ( 1 mile = 1609 meters)
Diameter → ∅ = 0.2117 cm
Resistivity → 𝜌 = 1.62 ∙ 10−8
Ω ∙ 𝑚
Resistance → R?
10. SAMPLE PROBLEM : Determine the resistance
of a 20-mile length of 12-gauge copper wire.
Given:
1 mi = 1609 meters
Diameter of 12-gauge wire = 0.2117 cm.
INTRODUCTION TO ELECTRICITY
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
STEP 1: Identify data
𝑙 = 20 mi
∅ = 0.2117 cm
𝜌 = 1.62 ∙ 10−8
Ω ∙ 𝑚
R?
STEP 2: Define Steps
1. 𝐹𝑖𝑛𝑑 𝑡ℎ𝑒 𝑟𝑎𝑑𝑖𝑢𝑠 of the wire → 𝒓 =
𝒅
𝟐
2. 𝐹𝑖𝑛𝑑 𝑡ℎ𝑒 𝑐𝑟𝑜𝑠𝑠 sectional area of the wire →
𝑨 = 𝝅𝒓 𝟐
2. Find resistance → 𝑹 =
𝝆 ∙ 𝒍
𝑨
11. INTRODUCTION TO ELECTRICITY
SECTION 1
Basic Concepts
1. Introduction
2. Current
3. Voltage
4. Resistance
5. Ohm’s Law
6. Power and Energy
𝑙 = 20 mi
∅ = 0.2117 cm
𝜌 = 1.62 ∙ 10−8
Ω ∙ 𝑚
R?
1. 𝐹𝑖𝑛𝑑 𝑡ℎ𝑒 𝑐𝑟𝑜𝑠𝑠 sectional area of the wire
𝐴 = 𝜋𝑟2
2. Find resistance 𝑅 =
𝜌 ∙ 𝑙
𝐴
STEP 3: Mathematical Procedure
1. Find the radius of the wire
1.1 First we have to pass centimeters to meters:
Factor 1m = 100 cm ⟶ 0.2117 𝑐𝑚 ∙
1𝑚
100 𝑐𝑚
= 0,002117 m = 2.117 ∙ 10−3
𝑚
1.2 With the diameter, we find the radius:
𝑑 = 2𝑟 ⟶ 𝑟 =
𝑑
2
=
2.117 ∙ 10−3 𝑚
2
= 1.089 ∙ 10−3
𝑚
2. We find the area:
𝐴 = 𝜋𝑟2
= 𝜋 ∙ (1.089 ∙ 10−3
𝑚 )2
= 3.520 ∙ 10−6
𝑚2
3. Find resistance
3.1 First we have to pass from miles to meters:
Factor 1 mi = 1609 m ⟶ 20 𝑚𝑖 ∙
1609 𝑚
1 𝑚𝑖
= 32180 m = 3.218 ∙ 104
𝑚
3.2 First we have to pass from miles to meters:
𝑅 =
𝜌 ∙ 𝑙
𝐴
=
1.62 ∙ 10−8 Ω∙𝑚 ∙ (3.218 ∙ 104 𝑚 )
(3.520 ∙ 10−6 𝑚2)
= 148,10 𝜴