Topics
Electric Charges and Fields
- Electric Charge
- Conductors and Insulators
- Basic Properties of Electric Charge
- Coulomb’s Law
- Forces between Multiple Charges
- Electric Field
- Electric Field Due to a System of Charges
- Physical Significance of Electric Field
- Electric Field Lines
- Electric Flux
- Electric Dipole
- Dipole in a Uniform External Field
- Continuous Charge Distribution
- Gauss’s Law
- Application of Gauss' Law
Electrostatics
Electrostatic Potential and Capacitance
- Electric Potential and Potential Energy
- Electrostatic Potential
- Electric Potential Due to a Point Charge
- Potential Due to an Electric Dipole
- Potential due to a System of Charges
- Equipotential Surfaces
- Relation Between Electric Field and Electrostatic Potential
- Potential Energy of a System of Charges
- Potential Energy of a Single Charge
- Potential Energy of a System of Two Charges in an External Field
- Potential Energy of a Dipole in an External Field
- Electrostatics of Conductors
- Dielectrics and Polarisation
- Capacitors and Capacitance
- The Parallel Plate Capacitor
- Effect of Dielectric on Capacitance
- Combination of Capacitors
- Energy Stored in a Charged Capacitor
- Overview: Electric Potential
- Overview: Capacitors and Dielectrics
Current Electricity
Current Electricity
- Electric Current
- Electric Currents in Conductors
- Ohm's Law
- Drift of Electrons and the Origin of Resistivity
- Mobility of Electrons
- Limitations of Ohm’s Law
- Resistivity of Various Materials
- Temperature Dependence of Resistivity
- Electrical Energy and Power in Conductors
- Cells, EMF, and Internal Resistance
- Cells in Series and in Parallel
- Kirchhoff’s Laws
- Wheatstone Bridge
- Overview: Electric Resistance and Ohm's Law
- Overview: DC Circuits and Measurements
Magnetic Effects of Current and Magnetism
Moving Charges and Magnetism
- Electromagnetism
- Magnetic force
- Motion in a Magnetic Field
- Biot-Savart Law
- Magnetic Field on the Axis of a Circular Current-Carrying Loop
- Ampere’s Circuital Law
- Solenoid
- Force Between Two Parallel Currents (Ampere’s Law)
- Torque on a Rectangular Current Loop in a Uniform Magnetic Field
- Circular Current Loop as a Magnetic Dipole
- Moving Coil Galvanometer
- Overview: Moving Charges and Magnetic Field
- Overview: Torque on a Current-Loop : Moving-Coil Galvanometer
Electromagnetic Induction and Alternating Currents
Magnetism and Matter
- Concept of Magnetism
- The Bar Magnet
- Magnetic Field Lines
- Bar Magnet as an Equivalent Solenoid
- The Dipole in a Uniform Magnetic Field
- The Electrostatic Analog
- Magnetism and Gauss’s Law
- Magnetisation and Magnetic Intensity
- Magnetic Properties of Materials
- Overview: Magnetism and Mater
Electromagnetic Waves
Optics
Electromagnetic Induction
Dual Nature of Radiation and Matter
Alternating Current
- AC Voltage Applied to a Resistor
- Representation of AC Current and Voltage by Rotating Vectors - Phasors
- AC Voltage Applied to an Inductor
- AC Voltage Applied to a Capacitor
- AC Voltage Applied to a Series LCR Circuit
- Phasor-diagram Solution
- Resonance
- Power in AC Circuit
- Transformers
- Overview: AC Circuits
Atoms and Nuclei
Electromagnetic Waves
- Concept of Electromagnetic Waves
- Displacement Current
- Sources of Electromagnetic Waves
- Nature of Electromagnetic Waves
- Electromagnetic Spectrum
- Overview of Electromagnetic Waves
Electronic Devices
Ray Optics and Optical Instruments
- Ray Optics Or Geometrical Optics
- Reflection of Light by Spherical Mirrors
- Sign Convention for Reflection by Spherical Mirrors
- Focal Length of Spherical Mirrors
- Mirror Equation of Spherical Mirrors
- Refraction of Light
- Total Internal Reflection
- Applications of Total Internal Reflection
- Refraction at a Spherical Surfaces
- Refraction by a Lens
- Power of a Lens
- Combined Focal Length of Two Thin Lenses in Contact
- Refraction of Light Through a Prism
- Optical Instruments
- Microscope and it’s types
- Telescope
- Overview of Ray Optics and Optical Instruments
Communication Systems
Wave Optics
- Concept of Wave Optics
- Huygens Principle
- Refraction of a Plane Wave
- Refraction at a Rarer Medium
- Reflection of a Plane Wave by a Plane Surface
- Coherent and Incoherent Addition of Waves
- Interference of Light Waves and Young’s Experiment
- Diffraction of Light
- The Single Slit
- Seeing the Single Slit Diffraction Pattern
- Polarisation of Light
- Overview: Wave Optics
Dual Nature of Radiation and Matter
- Dual Nature of Radiation
- Electron Emission
- Photoelectric Effect - Hertz’s Observations
- Photoelectric Effect - Hallwachs’ and Lenard’s Observations
- Experimental Study of Photoelectric Effect
- Effects of Intensity and Frequency on Photocurrent
- Photoelectric Effect and Wave Theory of Light
- Einstein’s Photoelectric Equation: Energy Quantum of Radiation
- Particle Nature of Light: The Photon
- Wave Nature of Matter
- Overview: Dual Nature of Radiation and Matter
The Special Theory of Relativity
Atoms
Nuclei
- Atomic Masses and Composition of Nucleus
- Size of the Nucleus
- Mass - Energy
- Nuclear Binding Energy
- Nuclear Force
- Radioactivity
- Forms of Energy > Nuclear Energy
- Nuclear Fission
- Nuclear Fusion
- Controlled Thermonuclear Fusion
- Overview: Nuclei
Semiconductor Electronics - Materials, Devices and Simple Circuits
- Concept of Semiconductor Electronics
- Classification of Metals, Conductors and Semiconductors
- Intrinsic Semiconductor
- Extrinsic Semiconductor
- n-type Semiconductor
- p-type Semiconductor
- Diode or p-n Junction
- Semiconductor Diode
- Application of Junction Diode as a Rectifier
- Overview: Semiconductor Electronics
Communication Systems
- Detection of Amplitude Modulated Wave
- Production of Amplitude Modulated Wave
- Basic Terminology Used in Electronic Communication Systems
- Sinusoidal Waves
- Modulation and Its Necessity
- Amplitude Modulation (AM)
- Need for Modulation and Demodulation
- Satellite Communication
- Propagation of EM Waves
- Bandwidth of Transmission Medium
- Bandwidth of Signals
The Special Theory of Relativity
- The Special Theory of Relativity
- The Principle of Relativity
- Maxwell'S Laws
- Kinematical Consequences
- Dynamics at Large Velocity
- Energy and Momentum
- The Ultimate Speed
- Twin Paradox
Estimated time: 10 minutes
CBSE: Class 12
Analogy — Gravitational Parallel
Think of two masses, m1 and m2, placed in an external gravitational field (like Earth's field). To bring them from infinity:
- Each mass gains gravitational PE with the Earth's field → m1gh1 + m2gh2
- They also interact with each other → mutual gravitational PE
Analogously, two charges in an external electric field gain:
- Individual interaction PE with the external field → q1V(r1) + q2V(r2)
- Mutual Coulombic interaction PE → \[\frac{q_1q_2}{4\pi\varepsilon_0r_{12}}\]
CBSE: Class 12
Step-by-Step Derivation
Setup
Two charges, q1 and q2, are to be placed at positions r1 and r2, respectively, in a region where an external electric field E exists, with corresponding external potential V(r).
Step 1 — Bring q1 from infinity to r1
- At this stage, only the external field is present. There is no other charge in the system.
- Work done against the external field to place q1 at r1: W1 = q1 V(r1)
- This work is stored as potential energy of q1 in the external field.
Step 2 — Bring q2 from infinity to r2
Now q1 is already at r1. When moving q2 to r2, work is done against two agents:
- Agent A — External field: W2,ext = q2 V(r2)
- Agent B — Field due to q1:
W2,q1 = \[\frac{1}{4\pi\varepsilon_0}\frac{q_1q_2}{r_{12}}\] - Total work done in Step 2 (by superposition of fields):
W2 = q2 V(r2) + \[\frac{q_1q_2}{4\pi\varepsilon_0r_{12}}\]
Step 3 — Add the Work Done in Both Steps
Total potential energy = W1 + W2
U = q1V(r1) + q2V(r2) + \[\frac{q_{1}q_{2}}{4\pi\varepsilon_{0}r_{12}}\]
CBSE: Class 12
The Three Energy Components
| Component | Formula / Interpretation | Physical Meaning |
|---|---|---|
| Interaction of (q1) with the external field | q1 V(r1) | Potential energy of charge (q1) in the external potential |
| Interaction of (q2) with the external field | q2 V(r2) | Potential energy of charge (q2) in the external potential |
| Mutual interaction of the two charges | \[\displaystyle \frac{q_1 q_2}{4\pi \varepsilon_0 r_{12}}\] | Coulomb potential energy between the two charges |
CBSE: Class 12
Compare: With vs. Without External Field
| Situation | Potential Energy Formula |
|---|---|
| Two charges, no external field (isolated system) | \[\displaystyle U=\frac{q_1q_2}{4\pi\varepsilon_0 r_{12}}\] |
| Single charge q in an external field | U = qV(r) |
| Two charges q1, q2 in an external field | U = \[q_1V(r_1)+q_2V(r_2)+\frac{q_1q_2}{4\pi\varepsilon_0 r_{12}}\] |
The formula for two charges in an external field is simply the sum of the single-charge external-field terms, plus the mutual interaction term.
CBSE: Class 12
Sign Conventions
| Condition | Sign of \[\displaystyle \frac{q_1q_2}{4\pi\varepsilon_0 r_{12}}\] | Physical Meaning |
|---|---|---|
| Like charges (q1q2 > 0) | Positive | Repulsive force; positive work is required to bring the charges together. |
| Unlike charges (q1q2 < 0) | Negative | Attractive force; the system releases energy as the charges come together. |
CBSE: Class 12
Example
Given:
- q1 = +7 μC = 7 × 10−6 C, located at (−9 cm, 0, 0)
- q2 = −2 μC = −2 × 10−6 C, located at (+9 cm, 0, 0)
- Separation: r12 = 9 + 9 = 18 cm = 0.18 m
(a) — Electrostatic PE without external field
U = \[\frac{1}{4\pi\varepsilon_0}\cdot\frac{q_1q_2}{r_{12}}=9\times10^9\times\frac{(7\times10^{-6})\times(-2\times10^{-6})}{0.18}\]
U = 9 × 109 × \[\frac{-14\times10^{-12}}{0.18}=\frac{-126\times10^{-3}}{0.18}\]
U = −0.7 J
Since q1q2 < 0, the potential energy is negative (attractive system).
(b) — Work to separate them to infinity
W = Ufinal − Uinitial = 0 − (−0.7) = +0.7 J
A positive amount of work is needed to pull apart unlike charges against the attractive Coulombic force.
(c) — PE with external field E = A/r2, A = 9 × 105 N C−1m2
Find the external potential at each charge location:
Since E = A/r2, integrating: V(r) = A/r
V(r1) = \[\frac{A}{r_1}=\frac{9\times10^5}{0.09}=10^7\mathrm{V}\]
V(r2) = \[\frac{A}{r_2}=\frac{9\times10^5}{0.09}=10^7\mathrm{V}\]
Calculate interaction energies with the external field:
q1V(r1) = (7 × 10−6) × 107 = 70 J
q2V(r2) = (−2 × 10−6) × 107 = −20 J
Apply the full formula [Eq. 2.29]:
U = q1V(r1) + q2V(r2) + \[\frac{q_1q_2}{4\pi\varepsilon_0r_{12}}\]
U = 70 + (−20) + (−0.7)
U = 49.3 J
The mutual interaction energy (−0.7 J) remains unchanged when the external field is switched on.
