Science

Physics 12

Physics 12

Course Description

Physics improves our quality of life by providing the basic understanding of the processes, forces, and structures of nature. In this course, students will learn about electric charges and fields, electricity, moving charges and magnets, magnetism and matter, electromagnetic induction, electromagnetic waves, and alternating current. They also acquire knowledge about ray optics, optical instruments, wave optics, dual nature of radiation and matter, atoms, nuclei, nuclear fission, nuclear fusion, and semiconductor.

What you’ll learn
  • Electric charges and fields
  • Electrostatic potential and capacitance
  • Current Electricity
  • Moving charges and Magnetics
  • Magnetism and Matter
  • Electromagnetic Induction
  • Alternating Current
  • Electromagnetic Waves
  • Ray Optics and Optical Instruments
  • Wave Optics
  • Dual nature of radiation and matter
  • Atoms
  • Nuclei
  • Semiconductor
  • Communication System
1.1: Introduction  

00:30


2.1: Learning Objectives  

00:29


3.1: Electric Charge  

03:04


4.1: Conductors and Insulators  

01:34


5.1: Charging By Induction  

01:39


6.1: Properties of Electric Charges  

02:37


7.1: Coulomb’s Law  

03:06


8.1: Electric Field  

04:32


9.1: Electric Flux  

01:14


10.1: Electric Dipole  

04:28


11.1: Continuous Charge Distribution  

01:20


12.1: Gauss Law  

06:59


13.1: Summary  

01:08


1.1: Introduction  

00:49


2.1: Learning Objectives  

00:29


3.1: Electric potential  

05:05


4.1: Equipotential surfaces  

02:06


5.1: Potential energy  

04:37


6.1: Electrostatics of Conductors  

02:34


7.1: Dielectrics _ Polarisation  

03:16


8.1: Capacitors  

01:36


9.1: Parallel plate capacitor  

03:54


10.1: Combination of Capacitors  

03:44


11.1: Van De Graaff Generator  

02:28


12.1: Summary  

01:08


1.1: Introduction  

00:21


2.1: Learning Objectives  

00:38


3.1: Electric Current  

01:49


4.1: Electric currents in Conductors  

02:59


5.1: Ohm_s law  

01:45


6.1: Resistance  


7.1: Resistors combination  

01:48


8.1: Cell, EMF and Internal resistance  

01:59


9.1: Cells combination  

02:23


10.1: Kirchoff’s laws  

02:25


11.1: Measuring instruments  

05:04


12.1: Summary - Current Electricity  

01:35


1.1: Introduction  

00:46


2.1: Learning Objectives  

01:00


3.1: Magnetic Force  

04:38


4.1: Motion in combined Electric and Magnetic fields  

03:15


5.1: Biot Savart Law  

02:27


6.1: B along axis of a circular current carrying coil  

01:58


7.1: Ampere_s Circuital Law  

01:24


8.1: Solenoid _ Toroid  

03:26


9.1: Force bw 2 parallel current carrying rods  

01:29


10.1: Torque  

01:58


11.1: Circular current loop Magnetic dipole  

00:03


12.1: Revolving electron Magnetic dipole moment  

01:42


13.1: Moving Coil Galvanometer  

02:27


14.1: Summary  

01:36


1.1: Introduction  

00:52


2.1: Learning Objectives  

00:31


3.1: Bar Magnet  

05:06


4.1: Magnetism and Gauss’s Law  

00:40


5.1: The Earth’s Magnetism  

02:19


6.1: Magnetisation and Magnetic Intensity  

03:11


7.1: Magnetic properties of materials  

06:27


8.1: Permanent Magnets and Electromagnets  

01:06


9.1: Summary - Magnetism and Matter  

00:42


1.1: Introduction  

00:24


2.1: Learning Objectives  

00:29


3.1: Experiments of Faraday and Henry  

02:06


4.1: Magnetic Flux  

00:59


5.1: Faraday’s Law of Induction  

01:02


6.1: Lenz’s Law and Conservation of Energy  

01:17


7.1: Motional Electromotive Force  

01:37


8.1: EDDY CURRENTS  

01:29


9.1: Inductance  

00:53


10.1: Mutual Inductance  

01:13


11.1: AC Generator  

01:06


12.1: Summary  

01:07


1.1: Introduction  

00:43


2.1: Learning Objectives  

00:35


3.1: AC voltage applied to a resistor  

02:58


4.1: Phasors  

00:48


5.1: AC voltage applied to an inductor  

02:33


6.1: Magnetisation _ demagnetization  

01:40


7.1: Circuit with capacitor only  

02:26


8.1: Charging _ Discharging  

01:23


9.1: AC voltage applied to a series LCR circuit  

03:33


10.1: Resonance  

04:47


11.1: L.C. Oscillations  

02:49


12.1: Transformers  

02:11


13.1: Summary  

00:58


1.1: Introduction  

01:09


2.1: Learning Objectives  

00:22


3.1: Displacement current  

03:38


4.1: Electromagnetic Waves  

01:13


5.1: Properties of Electromagnetic Waves  

02:22


6.1: Electromagnetic Spectrum  

04:50


7.1: Summary  

01:59


1.1: Introduction  

01:25


2.1: Learning Objectives  

00:37


3.1: Farsightedness  

00:54


4.1: Nearsightedness  

00:38


5.1: Total Internal Reflection  

01:02


6.1: Simple Microscope  

00:42


7.1: Summary  

02:19


1.1: Introduction  

00:36


2.1: Learning Objectives  

00:30


3.1: Huygen’s Principle  

01:17


4.1: Plane waves Refraction and reflection  

02:11


5.1: The Doppler effect  

02:31


6.1: Coherent And Incoherent Addition of Waves  

02:40


7.1: Young’s Double slit experiment  

05:17


8.1: Diffraction of Light  

01:18


9.1: Diffraction-Important Points  

02:45


10.1: Polarization of light  

03:34


11.1: Summary  

01:16


1.1: Introduction  

01:12


2.1: Learning Objectives  

00:40


3.1: Electron emission  

03:13


4.1: Photoelectric Effect  

04:22


5.1: Einstein’s Photoelectric Equation  

01:35


6.1: Dual Nature  

02:32


7.1: de Broglie wave  

01:56


8.1: Davisson and Germer Experiment  

01:23


9.1: Summary  

01:15


1.1: Introduction  

00:32


2.1: Learning Objectives  

00:25


3.1: Rutherford’s Nuclear model  

03:28


4.1: Electron orbits  

01:53


5.1: Atomic spectra  

02:18


6.1: Bohr’s Model of the Hydrogen Atom  

03:01


7.1: Energy levels  

02:00


8.1: de-Broglie’s explanation  

01:56


9.1: Summary  

01:08


1.1: Introduction  

00:40


2.1: Learning Objectives  

00:33


3.1: Composition of nucleus  

04:01


4.1: Mass Energy  

04:28


5.1: Radioactivity  

03:03


6.1: Nuclear change  

02:02


7.1: Nuclear Fission  

03:33


8.1: Nuclear Fusion  

01:22


9.1: Summary  

01:09


1.1: Introduction  

00:35


2.1: Learning Objectives  

01:01


3.1: Classification of solids  

01:36


4.1: Band theory of Solids  

01:45


5.1: Intrinsic Semiconductors  

02:02


6.1: Extrinsic Semiconductors  


7.1: p-n junction  

01:55


8.1: p-n junction diode  

02:28


9.1: p-n diode as Rectifier  

01:42


10.1: Zener diode  

01:04


11.1: Optoelectronic devices  

03:38


12.1: Junction Transistor  

03:06


13.1: Transistor characteristics  

02:14


14.1: Transistor Device  

03:28


15.1: Transistor Amplifier (CE configuration)  

01:35


16.1: Feedback and Oscillator  

03:05


17.1: Digital electronics _ logic gates  

02:44


18.1: Integrated Circuits  

01:26


19.1: Summary  

02:35


1.1: Introduction  

00:32


2.1: Learning Objectives  

00:39


3.1: Elements of a communication system  

01:44


4.1: Terminology used  

03:06


5.1: Bandwidth  

02:16


6.1: Propagation of EM Waves  

03:29


7.1: Necessity of Modulation  

03:06


8.1: Amplitude modulation  

01:08


9.1: Production of AM waves  

02:11


10.1: Detection of AM waves  

00:40


11.1: Internet  

02:51


12.1: Summary  

02:18


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This course includes
  • Units 15
  • Lessons 168
  • Expiry Date Full lifetime access
  • Language English
  • Last Updated Nov 08 2022

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