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Electricity Class 10 Notes Science Chapter 11

Electricity plays a crucial role in our modern world, powering everything from homes and schools to hospitals and industries. But what exactly is electricity? How does it travel through an electric circuit? And what factors influence the flow of current? In this chapter, we'll explore these questions, uncover the principles behind electric circuits, and delve into the heating effects of electric current and its many practical applications.

Electricity originated from the Greek words “Electrica” and “Elektron”. The greek philosopher Thales was the first to observe the attracting capacity of certain materials when rubbed together. 

Electric Current and Circuit

  • Electricity is one of the most convenient and widely used forms of energy in the world.
  • Conductors are those substances in which electric charge can flow freely. Metals are electric conductors. Copper and aluminium are the two most commonly used metals in electricity.Electricity Class 10 Notes Science Chapter 11
  • Electrical insulators are those materials in which electric charges do not move freely. Rubber, glass and plastic are examples of insulators. Electrical Insulators
    Electrical Insulators
  • Current electricity is the electricity which deals with moving charges.
  • A continuous and closed path of an electric current is called an electric circuit. Electric Circuit
    Electric Circuit
  • Electric current is defined as the rate of flow of electric charge through a cross-section of a conductor. Electricity Class 10 Notes Science Chapter 11

The flow of electric currentThe flow of electric current

  • S.I. unit of electric current is ‘ampere' (A). One-ampere current is equivalent to the flow of 1 coulomb of charge per second through a section of a conductor. Thus, 1 A = 1 C s-1.
  • The direction of the flow of electric current is taken as opposite to the direction of the flow of negatively charged electrons. In other terms, the direction of conventional current is taken as the direction along which positive charges will move if allowed to do so
  • In conductors flow of electric current is due to the flow of electrons. The flow of 6.25 x 1018 electrons per second across a cross-section of a conductor constitutes a current of 1 ampere.

Solved example
A current of 0.75 A flows through a heater for 8 minutes. Calculate the amount of electric charge that passes through the circuit.
Solution:
Given:
Current, I=0.75 AI = 0.75 \, \text{A}I=0.75A
Time, t=8 min = 480s min st = 8 \, \text{min} = 480 
Using the formula:
Q=ItQ = It
Q=0.75 A×480 sQ = 0.75 \, \text{A} \times 480 \, \text{s}Q=0.75A×480s
Q=360 CQ = 360 \, \text{C}Q=360C
So, the electric charge that flows through the circuit is 360 C.

Question for Chapter Notes: Electricity
Try yourself:Which of the given is the SI Unit of Electric Current?
View Solution


Electric Potential & Potential Difference

The flow of electric charge in a circuit is similar to water flow in a pipe

Electricity Class 10 Notes Science Chapter 11

  • The water pipe is analogous to the electric conductor and the amount of water flowing across a section per second corresponds to electric current. 
  • As water flows from higher pressure (level) to lower pressure (level), the electric current flows from higher electric potential to lower electric potential.
  • The potential difference across a conductor is maintained by using a cell or battery.
  • The chemical action within a cell generates the potential difference between its electrodes, due to which current flows through the circuit.
  • Potential difference between two points in an electric circuit carrying current is defined as the work done to move a unit positive charge from one point to another. If Electricity Class 10 Notes Science Chapter 11 be the amount of work done in taking a charge Q from point B to point A, then
    Electricity Class 10 Notes Science Chapter 11
  • The SI unit of electric potential difference is volt (V), whereElectricity Class 10 Notes Science Chapter 11

Solved example
How much work is done in moving a charge of 3 C between two points with a potential difference of 9 V?

Solution:

The charge QQQ flowing between the two points with a potential difference V=9 VV = 9 \, \text{V}V=9V is 3 C. The work WWW done in moving the charge can be calculated using the formula:

W=V×QW = V \times Q
W=9 V×3 CW = 9 \, \text{V} \times 3 \, \text{C}C
W=27 JW = 27 \, \text{J} J

So, 27 J of work is done in moving the charge.

Circuit Diagram

  • A circuit diagram is a simplified representation of the components of an electrical circuit using either the images of the distinct parts or standard symbols. 
  • It shows the relative positions of all the elements and their connections to one another. 
  • It is often used to provide a visual representation of the circuit to an electrician. The following figure shows a simple circuit diagram.

Electricity Class 10 Notes Science Chapter 11

Components of Circuit Diagram

Electricity Class 10 Notes Science Chapter 11

Ohm's Law

George Simon Ohm established a relationship between the electric current flowing through a conductor and the potential difference across its ends, due to which current flows.

  • According to Ohm’s law, the temperature remaining constant, the current passing through a conductor is directly proportional to the potential differenceacross its ends, i.e.,

    V ∝ I or V = IR

Electricity Class 10 Notes Science Chapter 11

  • Here, constant R is known as the resistance of the given conductor. For a given conductor its resistance is constant at a given temperature.
  • Electrical resistanceof a conductor may be considered as a measure of the opposition offered by it for the flow of electric charge through it.

    Mathematically, Resistance Electricity Class 10 Notes Science Chapter 11

  • S.I. unit of electrical resistance is ohm(Ω), where 1 Ω = 1V/1A.

Lets do one activity to understand Ohm's law more clearly

Objective:
To study the relationship between the potential difference (V) across a nichrome wire and the current (I) passing through it by varying the number of cells in a circuit.

Materials Needed:

Nichrome wire (length 0.5 m), Ammeter, Voltmeter, Four 1.5 V cells, Connecting wires, Switch, Circuit board

Procedure:

Set Up the Circuit:

  • Connect the nichrome wire (XY) to a circuit that includes an ammeter in series, a voltmeter in parallel with the wire, and one 1.5 V cell as the power source.

Measure and Record Readings:

  • Close the switch and note the current (I) from the ammeter and the potential difference (V) across the nichrome wire from the voltmeter.
  • Record these values in a table.

Increase the Number of Cells:

  • Add another cell to the circuit to increase the voltage. Again, note the values of current (I) and potential difference (V) and record them.
  • Repeat this step by adding a third and then a fourth cell to the circuit, each time noting the ammeter and voltmeter readings.
    Electricity Class 10 Notes Science Chapter 11

Tabulate the Results:

Create a table with the number of cells, corresponding potential difference (V), and current (I) readings.

Electricity Class 10 Notes Science Chapter 11

Electricity Class 10 Notes Science Chapter 11

In this Activity, you will find that approximately the same value for V/I is obtained in each case. Thus the V–I graph is a straight line that passes through the origin of the graph,Thus, V/I is a constant ratio. R is a constant for the given metallic wire at a given temperature and is called its resistance. It is the property of a conductor to resist the flow of charges through it.

Important note:-
It is obvious from the ohm's law equation  that the current through a resistor is inversely proportional to its resistance. If the resistance is doubled the current gets halved.

Question for Chapter Notes: Electricity
Try yourself:The obstruction offered by material of conductor to the passage of electric current is known as:
View Solution

Factors Affecting Resistance of a Conductor

  • At a given temperature resistance of a conductor depends on its:
    (i) Length L
    (ii) Cross-section area A
    (iii) Nature of the material of the conductor. 
  • It is found that R ∝ L and Electricity Class 10 Notes Science Chapter 11

    Mathematically, R = ρL/A

  • Where ρ is a constant known as the resistivity of the material of the conductor, its value depends only on the nature of the material of the conductor and the temperature and is independent of the dimensions (i.e., length and cross-section area) of the conductor.
  • The resistivity of a given material is defined as the resistance offered by a cube of that material of side 1 m when current flows perpendicular to the opposite faces. Its unit is ohm-metre (Ω m).
  • Metals and alloys have low resistivity in the range of 10-8 Ω m to 10-6 Ω m and are good conductors of electricity.
  • Insulators like rubber and glass have a resistivity of the order of 1012 to 1017 Ω m.
  • Resistance, as well as the resistivity of a material, varies with temperature. For metallic conductors resistance as well as resistivity increases with an increase in temperature.
  • Resistivity of pure metals is very very low. On account of this reason, metals like copper and aluminium are used for electrical transmission lines.
  • Resistivity of alloys is greater than that of pure metals. However, alloys do not oxidise easily, and their change in resistivity with the temperature rise is small. Due to these properties, they are used as electrical elements in most electric appliances. Generally, nichrome elements are used in electric iron, heater, radiator, geyser etc.
  • Tungsten filaments are used in electric lamps because the melting point of tungsten is extremely high.
  • A rheostat is a variable resistance device used in electrical circuits. It is used to regulate the current in the circuit without changing the voltage source.A Rheostat
    A Rheostat
  • An ammeter is an instrument that can measure the electric current flowing in an electric circuit directly in amperes and their submultiples.

AmmeterAmmeter

  • A voltmeter is an instrument used to measure the potential difference across two given points in an electrical circuit directly in volts.

VoltmeterVoltmeter

Solved example
The resistance of a metal wire of length 1.5 m is 30 Ω at 25°C. If the diameter of the wire is 0.4 mm, what will be the resistivity of the metal at that temperature? 

Solution:

Given:

Resistance R=30ΩR = 30 \, \Omega

Diameter d=0.4mm mm=4×10−4m

Length l=1.5m

To find the resistivity ρ\rhoρ of the metal, use the formula:

ρ=RA/l= Rπd2/4l

Substituting the given values:

ρ=2.51×10−6Ωm

The resistivity of the metal at 25°C is2.51×10−6Ωm

Another Solved example

A wire made of a specific material has a length lll and a cross-sectional area AAA, with a resistance of 6 Ω. What would be the resistance of another wire made of the same material but with a length of l/3l/3l/3 and a cross-sectional area of 3A3A3A?

Solution:
Electricity Class 10 Notes Science Chapter 11For first wire

Electricity Class 10 Notes Science Chapter 11

For second wire

R2 = 1/9 ρl/A
R2= 1/9 R
R2= 1Ω

The resistance of the new wire is 1Ω.

Resistance of System of Resistors

In an electric circuit resistances may be connected in:
(i) Series
(ii) Parallel ArrangementElectricity Class 10 Notes Science Chapter 11

In the series grouping of resistances:
(i) The current flowing through all the resistances is the same.
(ii) The total voltage across the combination is equal to the sum of the voltage drops across the individual resistors.
(iii) The total resistance of the combination is equal to the sum of the individual resistances.

(iv)If R1, R2, R3,... be the individual resistors joined in series then the equivalent resistor Rs is given by Rs = R1 + R2 + R3 + ... 

In the parallel grouping of resistances:
(i) The voltage across each resistor is the same and equal to the voltage across the whole combination.
(ii) The currents in various resistors are inversely proportional to the resistances, and the total current is the sum of the currents flowing through different resistances, and (Hi) the sum of the reciprocals of the separate resistances is equal to the reciprocal of equivalent resistance. If R1, R2, R3,... be the individual resistors joined in parallel then the equivalent resistance Rp is given as :


In household electric circuits, a series circuit is not followed. It is because if one component of the series circuit fails, the entire circuit is broken and none of the components works. Moreover, the same current flows through all the components irrespective of their operating needs.

  • parallel circuit divides the current into various components (appliances), and each component can draw current as per its appropriate operation. Separate on/off switches can be put with each component in the parallel circuit. Moreover, the total resistance in parallel circuit arrangement decreases and hence a stronger current can be drawn from a voltage source. Due to these reasons, all appliances are connected in parallel in our household electric circuit.

Solved example

An electric lamp of resistance 20Ω and a conductor of resistance 4Ω are connected to a 6V battery as shown in the circuit. Calculate:(a) The total resistance of the circuit

(b) The current through the circuit

(c)The potential difference across the (i) Electric lamp and (ii) Conductor, and

(d) Power of the lamp.

Electricity Class 10 Notes Science Chapter 11Answer:

Given, Resistance of electric lamp, R = 20 ohm 

Resistance of conductor, R = 4 ohm

Potential difference, V = 6 V

(a) Since R and R are connected in series,

Total resistance, R = R + R 2

                                           = 20 + 4

                                           = 24 ohm

Therefore, total resistance of the circuit is 24 ohm.

(b) Let the current through the circuit be I.

According to ohm’s law,

V = I*R

I = V / R

 = 6 / 24

 = 0.25 A

Therefore, the current through the circuit is 0.25 A

(c) (i) For electric lamp,

= I*R 1

= 0.25 * 20

= 5 V

Therefore, the potential difference across the electric lamp is 5 V.

(ii) For conductor,

= I*R 2

= 0.25 * 4

= 1 V

Therefore, the potential difference across the conductor is 1 V.

(d)Let the power of the lamp be P.

We know that,

= V*I

= 5 * 0.25

= 1.25 W

Therefore, power of the lamp is 25 W

Question for Chapter Notes: Electricity
Try yourself:In a system of resistors, the total resistance can be calculated using different formulas, depending on how the resistors are connected. Which of the following formulas are correct for calculating the total resistance?
View Solution

Heating Effect of Electric Current

  • If on applying, a potential difference V across the ends of a conductor of resistance R, the current I flows for a time t, then as per Joule’s law of heating the electric energy consumed is given by:
    Electricity Class 10 Notes Science Chapter 11
  • Generally, it is convenient to use the formula W = I2Rt for series-connected circuits because the current I is the same in all resistors. For parallel arrangement, we prefer to use the relation Electricity Class 10 Notes Science Chapter 11 because here V is the same across all branches of the circuit.
  • The dissipated electrical energy reappears as heat. Thus, the heat produced:

Electricity Class 10 Notes Science Chapter 11


Solved example

An electric heater uses 900 W of power when operating at maximum heat and 400 W at minimum heat. The voltage across it is 240 V. What are the current and resistance of the heater in each case?

Solution:

Using the formula P=VIP = VI the current II can be calculated as:

I=PVI = \frac{P}{V}

(a) Maximum Heating:

P= WP = 900 \, \text900W

V=240V

I=900 W240 V=3.75A AI = \frac{900 \, \text{W}}{240 \, \text{V}} = 3.75 \, \text{A}

The resistance RRR is:

R=VI=240 V3.75 A=64ΩR = \frac{V}{I} = \frac{240 \, \text{V}}{3.75 \, \text{A}} = 64 \, \Omega

(b) Minimum Heating:

P=400W WP = 400 \, \text{W}

V=240 VV = 240 \, \text{V}V

I=400 W240 V=1.67A AI = \frac{400 \, \text{W}}{240 \, \text{V}} = 1.67 \, \text{A}
The resistance RR is:R=VI=240 V1.67 A=143.71ΩR = \frac{V}{I} = \frac{240 \, \text{V}}{1.67 \, \text{A}} = 143.71 \, \Omega

So, at maximum heating, the current is 3.75 A and the resistance is 64 Ω. At minimum heating, the current is 1.67 A and the resistance is 143.71 Ω.

Practical Applications of Heating Effect of Electric Current

 1. Electric heating is also used to produce light in electric bulbs. As bulb filament operates at very high temperatures, the filament should be thermally insulated. The bulb is filled with chemically inactive nitrogen and argon gases to prolong the life of the bulb filament.

2. Electric fuse protects an electric circuit or appliance by stopping the flow of any unduly high electric current.

  • A fuse consists of a piece of wire of a metal or an alloy of an appropriate melting point and is placed in series with the circuit. 
  • If a current larger than the specified value flows through the circuit, the temperature of the fuse wire rises beyond its melting point, and the fuse melts. As a result, the circuit breaks.
    Electric Fuse
    Electric Fuse
  • The fuse of appropriate current capacity is used in an electric circuit.


Electric Power

The time rate of doing electric work is called electric power. Thus,

Electricity Class 10 Notes Science Chapter 11

  • SI unit of electric power is watt (W), where 1 watt = 1 volt * 1 ampere = 1 V A
  • A watt-hour and kilowatt-hour are practical units of electric energy. The commercial unit of electric energy is a kilowatt-hour (kW h), where

    1 kW h = 1000 Wh = 3.6 x 106 J.

Question for Chapter Notes: Electricity
Try yourself:Amount of energy delivered by a power of one kilowatt in one hour is called _______
View Solution

Frequently Asked Questions (FAQs)

Q1. What is electricity? 
Ans.
Electricity is a form of energy resulting from the movement of charged particles, such as electrons or ions. It can be generated from various sources, including fossil fuels, nuclear power, and renewable sources like wind and solar.

Q2. How does electricity flow through a circuit? 
Ans. 
Electricity flows through a circuit due to the movement of charged particles, which create an electric current. The current flows from the negative terminal of the power source to the positive terminal, following the path of least resistance through the circuit. This movement of electrons through the circuit creates energy, which can be used to power electrical devices. 

Q3. What are conductors and insulators? 
Ans. 
Conductors are materials that allow electricity to flow through them easily, due to the presence of free electrons. Examples of conductors include metals like copper, aluminium, and gold. Insulators, on the other hand, are materials that do not allow electrons to flow easily. Examples of insulators include rubber, plastic, and glass. 

Q4. What is resistance in an electrical circuit? 
Ans.
Resistance is the opposition that a material offers to the flow of electrical current. It is measured in ohms and can be affected by factors such as the material of the conductor, its length, and its cross-sectional area. A material with high resistance will require more energy to produce a given amount of current, resulting in a lower flow of electricity. 

Q5. What are some common electrical safety hazards? 
Ans. 
Electrical safety hazards can include electric shock, burns, fires, and explosions. Some common causes of these hazards include faulty wiring, damaged electrical cords, and improper use of electrical equipment. To reduce the risk of electrical accidents, it is important to follow safety guidelines and use caution when working with electricity. This can include wearing protective gear, avoiding contact with live wires, and turning off power sources before making repairs or adjustments. 

Q6. Why is resistance more in series combination?
Ans. We know R ∝ L. In a series combination of resistors, the effective length of the conductor increases, so the resistance increases.

Q7. Why is it not advisable to handle high-voltage electrical circuits with wet hands?
Ans. 
The resistance of the dry-skin human body is about 50,000 Ω. When the skin is wet, the resistance gets lowered to about 10,000 Ω. If a person with wet hands touches the electrical circuit, a high current will flow through the body causing a risk to life.

Q.8. How does the use of a fuse wire protect electrical appliances?
Ans. 
If a current larger than a specified value flows in a circuit, the temperature of the fuse wire increases its melting point. The fuse wire melts and the circuit breaks.

The document Electricity Class 10 Notes Science Chapter 11 is a part of the Class 10 Course Science Class 10.
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FAQs on Electricity Class 10 Notes Science Chapter 11

1. What is electric current and how is it measured?
Ans.Electric current is the flow of electric charge in a circuit, typically measured in amperes (A). It represents the rate at which charge is flowing through a conductor. A device called an ammeter is used to measure electric current.
2. What is the difference between electric potential and potential difference?
Ans.Electric potential refers to the amount of electric potential energy per unit charge at a specific point in an electric field, measured in volts (V). Potential difference, on the other hand, is the difference in electric potential between two points in a circuit and is also measured in volts. It is essential for the flow of current in a circuit.
3. How do you read a circuit diagram?
Ans.A circuit diagram uses standardized symbols to represent electrical components and their connections. To read a circuit diagram, you need to familiarize yourself with the symbols for components like resistors, batteries, and switches. The lines represent wires or connections, and by following these connections, you can understand the flow of current in the circuit.
4. What is Ohm's Law and how is it applied?
Ans.Ohm's Law states that the current (I) flowing through a conductor between two points is directly proportional to the voltage (V) across the two points and inversely proportional to the resistance (R) of the conductor. It can be expressed with the formula V = I × R. This law is applied in circuit analysis to calculate the relationship between current, voltage, and resistance.
5. What factors affect the resistance of a conductor?
Ans.The resistance of a conductor is affected by several factors, including its material, length, cross-sectional area, and temperature. Generally, materials with higher resistivity (such as rubber) have higher resistance, while good conductors (like copper) have lower resistance. Additionally, longer conductors have higher resistance, while thicker conductors have lower resistance. Temperature also plays a role, as most conductors exhibit increased resistance with rising temperature.
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