Science

Physics 11

Physics 11

Course Description

Physics is a laboratory science course that deals with the different types of motion, the laws governing them and the graphs or calculations used to interpret the components of motion. The students analyze the relationship between work and energy and the different characteristics associated with the formation and movement of waves. Students acquire knowledge about momentum, thermodynamics, and properties of waves. In addition, they evaluate the basic principles involved in electricity and magnetism and also the various nuclear processes and thereby calculate the age of a required specimen.

What you’ll learn
  • Physical World
  • Units and Measurement
  • Motion in a Straight Line
  • Motion in a Plane
  • Laws of Motion
  • Work Energy and Power
  • Rotational Motion
  • Gravitation
  • Mechanical Properties of Solids
  • Mechanical properties of Fluids
  • Thermal Properties of Matter
  • Thermodynamics
  • Kinetic Theory
  • Oscillations
  • Waves
1.1: Introduction  

00:54

2.1: Learning Objective  

00:23

3.1: Physics  

00:34

4.1: Scope and Excitement of Physics  

00:57

5.1: Physics, Technology and Society  

01:49

6.1: Fundamental Forces in Nature  

02:26

7.1: Nature of Physical Laws  

00:49

8.1: Summary  

01:03

1.1: Introduction  

00:34

2.1: Learning Objectives  

00:24

3.1: Units and Measurements  

00:54

4.1: The International System of Units  

00:33

5.1: Measurement of Length  

04:28

6.1: Measurement of Mass  

00:26

7.1: Measurement of Time  

01:22

8.1: Accuracy, Precision of instruments and Errors in measurement  

00:38

9.1: Systematic Errors  

01:07

10.1: Least Count Error  

00:32

11.1: Absolute Error, Relative Error and Percentage Error  

00:44

12.1: Combination of Errors  

00:50

13.1: Significant Figures  

01:10

14.1: Dimensions of Physical Quantity  

00:15

15.1: Dimensional Formula and Equations  

00:29

16.1: Dimensional Analysis  

00:28

17.1: Summary  

01:07

1.1: Introduction  

00:28

2.1: Learning Objectives  

00:21

3.1: Frame of Reference  

00:45

4.1: Rest and Motion are Relative  

00:26

5.1: Distance  

00:50

6.1: Displacement  

01:11

7.1: Position time graph  

00:32

8.1: Average velocity and average speed  

01:03

9.1: Instantaneous velocity and speed  

00:22

10.1: Acceleration  

01:09

11.1: Kinematic Equations for Uniformly Accelerated Motion  

02:47

12.1: Motion in Free Fall  

01:05

13.1: Relative velocity  

00:29

14.1: Summary  

00:46

1.1: Introduction  

00:49

2.1: Learning Objectives  

00:30

3.1: Scalars and Vectors  

01:22

4.1: Position and Displacement Vectors  

01:06

5.1: Equality of Vectors  

00:32

6.1: Multiplication of a Vector  

00:24

7.1: Addition and Subtraction of Vectors  

01:04

8.1: Properties of Vector Addition  

01:25

9.1: Resolution of Vectors  

03:37

10.1: Addition of Vectors by Analytical Method  

02:15

11.1: Motion in a Plane  

01:17

12.1: Motion in a Plane with Constant Acceleration  

00:58

13.1: Relative Velocity in Two Dimensions  

00:31

14.1: Projectile Motion  

01:14

15.1: Uniform Circular Motion  

00:42

16.1: Summary  

01:04

1.1: Introduction  

00:45

2.1: Learning Objectives  

00:25

3.1: Aristotle’s Fallacy  

00:42

4.1: The Law of Inertia  

03:03

5.1: Newton’s First Law of Motion  

01:09

6.1: Newton’s Second Law of Motion  

02:03

7.1: Impulse  

01:05

8.1: Newton’s Third Law of Motion  

01:06

9.1: Conservation of Momentum  

01:29

10.1: Equilibrium of a Particle  

00:57

11.1: Common Forces in Mechanics  

02:32

12.1: Circular Motion  

03:04

13.1: Summary  

01:24

1.1: Introduction  

00:45

2.1: Learning Objectives  

00:34

3.1: Commutative and Distributive Law for Dot Product  

02:52

4.1: Work  

01:46

5.1: Kinetic Energy  

00:31

6.1: Work done by a Variable Force  

00:43

7.1: Work-Energy Theorem  

01:26

8.1: Potential Energy  

01:17

9.1: The Conservation of Mechanical Energy  

01:36

10.1: Potential Energy of a Spring  

01:40

11.1: Various Forms of Energy  

03:04

12.1: The Principle of Conservation of Energy  

00:51

13.1: Power  

01:06

14.1: Collisions  

03:32

15.1: Summary  

00:57

1.1: Introduction  

00:39

2.1: Learning Objectives  

00:36

3.1: Rotational and Translational Motion  

00:58

4.1: Centre of Mass  

01:27

5.1: Motion of centre of Mass  

04:07

6.1: Linear Momentum of a System of Particles  

01:19

7.1: Vector Product of Two Vectors  

00:55

8.1: Angular Velocity and its Relation with Linear Velocity  

01:32

9.1: Torque and Angular Momentum  

03:43

10.1: Equilibrium of a Rigid Body  

01:03

11.1: Moment of Inertia  

01:36

12.1: Theorems of Perpendicular and Parallel axis  

02:47

13.1: Work Done by a Torque  

02:00

14.1: Angular Momentum in Rotation About a Fixed Axis  

00:50

15.1: Rolling Motion  

01:22

16.1: Summary  

01:12

1.1: Introduction  

00:54

2.1: Learning Objectives  

00:35

3.1: Definition  

00:14

4.1: Kepler’s Laws  

01:25

5.1: Newton’s Law of Gravitation  

01:13

6.1: Vector form of Newton’s Law of Gravitation  

01:10

7.1: The Gravitational Constant  

01:24

8.1: Acceleration due to Gravity of the Earth  

00:54

9.1: The Gravitational_Constant  

04:55

10.1: Gravitational Potential Energy  

02:05

11.1: Escape Velocity  

00:56

12.1: Earth Satellites  

00:34

13.1: Energy of an Orbiting Satellite  

01:37

14.1: Geostationary and Polar Satellites  

00:52

15.1: Weightlessness  

00:55

16.1: Summary  

01:35

1.1: Introduction  

00:38

2.1: Learning Objectives  

00:27

3.1: Elasticity and Plasticity  

00:35

4.1: Elastic Behaviour of Solids  

00:29

5.1: Stress  

01:15

6.1: Strain  

00:52

7.1: Hooke’s Law  

00:21

8.1: Stress-Strain Curve  

01:28

9.1: Elastic Moduli  

01:25

10.1: Poisson’s Ratio  

00:31

11.1: Applications of Elastic Behaviour of Materials  

01:04

12.1: Summary  

01:11

1.1: Introduction  

00:51

2.1: Learning Objectives  

00:35

3.1: Fluids  

00:34

4.1: Pressure  

04:38

5.1: Hydraulic Lift  

02:24

6.1: Hydrostatic and Atmospheric Pressure  

02:15

7.1: Flow of Fluids  

00:50

8.1: Equation of Continuity  

00:57

9.1: Bernoulli’s Principle  

00:47

10.1: Torricelli’s Law  

03:48

11.1: Viscosity  

01:09

12.1: Stoke’s Law  

01:01

13.1: Reynold’s Number  

00:35

14.1: Surface Tension  

00:40

15.1: Surface Energy and Angle of Contact  

01:11

16.1: Phenomena based on Surface Tension  

00:17

17.1: Summary  

01:29

1.1: Introduction  

00:37

2.1: Learning Objectives  

00:27

3.1: Temperature and Heat  

01:12

4.1: Measurement Of Temperature  

01:10

5.1: Ideal gas equation and Absolute Temperature  

01:35

6.1: Thermal Expansion  

03:52

7.1: Vector Product of Two Vectors  

01:09

8.1: Calorimetry  

01:03

9.1: Change of State  

02:18

10.1: Heat Transfer  

01:43

11.1: Newton’s Law Of Cooling  

12.1: Summary  

01:07

1.1: Introduction  

00:31

2.1: Learning Objectives  

00:40

3.1: Definition  

00:19

4.1: Thermal Equilibrium  

01:17

5.1: Zeroth Law of Thermodynamics  

00:16

6.1: Heat, Internal Energy and Work  

00:58

7.1: First Law of Thermodynamics  

01:19

8.1: Specific Heat Capacity  

00:55

9.1: Thermodynamic State Variables and Equation of State  

01:05

10.1: Thermodynamic Processes  

03:05

11.1: Heat Engines  

00:53

12.1: Refrigerator and Heat Pump  

00:37

13.1: Second Law of Thermodynamics  

00:38

14.1: Reversible and Irreversible Processes  

00:47

15.1: Carnot Engine  

01:44

16.1: Summary  

01:29

1.1: Introduction  

00:31

2.1: Learning Objectives  

00:42

3.1: Molecular Nature of Matter  

00:38

4.1: Behaviour of Gases  

01:38

5.1: Boyle’s Law  

00:35

6.1: Charle’s Law  

00:45

7.1: Kinetic Theory of an Ideal Gas  

00:49

8.1: Pressure of an Ideal Gas  

01:22

9.1: Kinetic Interpretation of Temperature  

00:38

10.1: Maxwell Distribution Function  

01:27

11.1: Law of Equipartition of Energy  

01:03

12.1: Specific Heat Capacity  

01:56

13.1: Specific Heat Capacity of Solids  

00:50

14.1: Specific Heat Capacity of Water  

00:21

15.1: Mean Free Path  

01:30

16.1: Summary  

01:02

1.1: Introduction  

00:51

2.1: Learning Objectives  

00:36

3.1: Periodic and Oscillatory Motions  

01:02

4.1: Period, Frequency and Displacement  

01:27

5.1: Simple Harmonic Motion  

01:09

6.1: Simple Harmonic Motion and Uniform Circular Motion  

00:32

7.1: Oscillations  

01:23

8.1: Force Law for Simple Harmonic Motion  

00:59

9.1: Energy in Simple Harmonic Motion  

01:43

10.1: Oscillations due to a Spring  

01:09

11.1: Simple Pendulum  

01:38

12.1: Damped Simple Harmonic Motion  

01:09

13.1: Forced Oscillations  

00:42

14.1: Resonance  

01:15

15.1: Summary  

00:52

1.1: Introduction  

00:35

2.1: Learning Objectives  

00:34

3.1: Definition  

00:16

4.1: Transverse and Longitudinal Waves  

01:04

5.1: Displacement Relation in a Progressive Motion  

00:41

6.1: Amplitude and Phase  

00:39

7.1: Wavelength  

00:30

8.1: Period, Angular Frequency and Frequency  

00:58

9.1: Speed of a Traveling wave  

01:43

10.1: Principle of Superposition of Waves  

01:19

11.1: Reflection of Waves  

00:50

12.1: Stationary Waves  

00:53

13.1: Beats  

00:57

14.1: Doppler’s Effect  

02:27

15.1: Summary  

01:08

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This course includes
  • Units 15
  • Lessons 218
  • Expiry Date Full lifetime access
  • Language English
  • Last Updated Nov 08 2022

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