A Simple, Simple Pendulum Simulator

Pendulum Controls & Energies

Length

Gravity

Amplitude

Damping

Show Angle Show Forces Show Trails

Energy (J)

Kinetic

0

Potential

0

Total

0

Legend — Vectors shown:
Tension, Weight, Restoring.

$$\textbf{Equation of Motion}$$

$$\frac{\mathrm{d^2} \theta}{\mathrm{d} t^2} + \frac{b}{{m}{L^2 }}\frac{\mathrm{d}\theta}{\mathrm{d} t} + \frac{g}{L}\sin\theta = 0$$

Tip: Adjust sliders to see effects. Equation governs motion.

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Invariance of Maxwell Equations Under Parity Transformation [NOT IN THE SYLLABUS. EXPLANETORY NOTE FOR PARITY VIOLATION IN BETA DECAY]

Maxwell’s Equations and Parity Invariance

One of the most beautiful features of Maxwell’s equations is their symmetry. In this post, we will prove that Maxwell’s equations are invariant under a parity transformation (spatial inversion).

1. What is a Parity Transformation?

A parity transformation (spatial inversion) is defined by:

\[ \hat{\mathbf{P}} \;\longmapsto\; \mathbf{r}' = -\mathbf{r}, \qquad t' = t \]

Transformation rules:

• Polar vector \( \mathbf{V} \): \(\mathbf{V}'(\mathbf r',t) = -\mathbf{V}(\mathbf r,t)\)
• Axial vector \( \mathbf{W} \): \(\mathbf{W}'(\mathbf r',t) = +\mathbf{W}(\mathbf r,t)\)
• Scalar \( \rho \): \(\rho'(\mathbf r',t) = \rho(\mathbf r,t)\)

Gradient operator: \[ \nabla' = \frac{\partial}{\partial \mathbf r'} = -\nabla \]

In Maxwell’s theory:

• \( \mathbf{E}, \mathbf{J} \) are polar vectors
• \( \mathbf{B} \) is an axial vector
• \( \rho \) is a scalar

2. Maxwell’s Equations in SI Units

\[ \begin{aligned} &(1) \quad \nabla \cdot \mathbf{E} = \frac{\rho}{\varepsilon_0}, \\[6pt] &(2) \quad \nabla \cdot \mathbf{B} = 0, \\[6pt] &(3) \quad \nabla \times \mathbf{E} = - \frac{\partial \mathbf{B}}{\partial t}, \\[6pt] &(4) \quad \nabla \times \mathbf{B} = \mu_0 \mathbf{J} + \mu_0 \varepsilon_0 \frac{\partial \mathbf{E}}{\partial t} \end{aligned} \]

3. Applying Parity

(1) Gauss’s Law for \( \mathbf{E} \)

\[ \nabla' \cdot \mathbf{E}' = (-\nabla) \cdot (-\mathbf{E}) = \nabla \cdot \mathbf{E} \] \[ \rho'/\varepsilon_0 = \rho/\varepsilon_0 \] ✅ Invariant.

(2) Gauss’s Law for \( \mathbf{B} \)

\[ \nabla' \cdot \mathbf{B}' = (-\nabla) \cdot (+\mathbf{B}) = -\nabla \cdot \mathbf{B} \] Since RHS = 0, equation is unchanged. ✅ Invariant.

(3) Faraday’s Law

\[ \nabla' \times \mathbf{E}' = (-\nabla) \times (-\mathbf{E}) = \nabla \times \mathbf{E} \] \[ -\frac{\partial \mathbf{B}'}{\partial t} = -\frac{\partial \mathbf{B}}{\partial t} \] ✅ Invariant.

(4) Ampère–Maxwell Law

\[ \nabla' \times \mathbf{B}' = (-\nabla) \times (+\mathbf{B}) = -(\nabla \times \mathbf{B}) \] \[ \mu_0 \mathbf{J}' + \mu_0 \varepsilon_0 \frac{\partial \mathbf{E}'}{\partial t} = \mu_0 (-\mathbf{J}) + \mu_0 \varepsilon_0 \frac{\partial (-\mathbf{E})}{\partial t} \] \[ = -\left(\mu_0 \mathbf{J} + \mu_0 \varepsilon_0 \frac{\partial \mathbf{E}}{\partial t}\right) \] Both sides gain the same minus sign. ✅ Invariant.

4. Continuity Equation

\[ \frac{\partial \rho'}{\partial t} + \nabla' \cdot \mathbf{J}' = \frac{\partial \rho}{\partial t} + (-\nabla) \cdot (-\mathbf{J})\] \[ = \frac{\partial \rho}{\partial t} + \nabla \cdot \mathbf{J} = 0 \]

5. Conclusion

By treating \( \mathbf{E} \) as a polar vector, \( \mathbf{B} \) as an axial vector, and assigning the correct transformation rules to sources, we find that all four Maxwell equations remain unchanged under parity transformation.

This symmetry is one of the many reasons Maxwell’s theory is so elegant: it respects both the structure of space and the distinction between vectors and pseudovectors.

The Camel Principle

A neat mathematical trick told through a timeless folk tale

A classic illustration of “adding and subtracting the same thing” to make an intractable division possible.

Do you know the Camel Principle?

It is a nifty trick we often use in derivations in mathematics and physics. The trick is to add and subtract a term in an expression, usually resulting in a simplification that leads to the solution of the problem at hand.

The Camel Principle got its name from a tale in ancient Arabian folklore. Long ago, there lived a rich merchant in Arabia whose property consisted of an oasis and 17 camels. He had three sons. Unfortunately, he died while his sons were still young, leaving behind a will to be executed. The will was a bit strange.

It stated that the oasis would remain in the common possession of the sons, while the eldest son was to receive half of the 17 camels, the second son one third, and the youngest one ninth. When the sons tried to divide the camels, a great dilemma arose. The camels could not be perfectly divided into a half, a third, and a ninth. The elders they consulted could not resolve the problem either. A greedy relative even suggested killing all the camels for a feast and selling the meat, then dividing the money among the sons, but the brothers loathed the idea.

Finally, a wise man from India came along — and he turned out to be a mathematician as well. When the sons asked him how to solve their dilemma, he thought for a moment and replied, “Seventeen is a prime number, so it can’t be done in the normal way. Let me add and subtract.” Then he brought one of his own camels and added it to the herd. “Dear young chaps,” he said, “behold — we now have 18 camels. The first son gets half of these, which is 9 camels.” He led 9 camels to stand beside the eldest son. Then he called the second son and said, “Now you get one third of the camels.” He gave him 6 camels. Finally, he granted the youngest son 2 camels, which is one ninth of 18. After that, the wise man took back his own camel — the one remaining after the sons had received 9 + 6 + 2 = 17 camels in total.

If you think the wise man cheated by adding his own camel, remember that he only increased the count temporarily—something the boys themselves would readily agree to!

Mathematical takeaway: Sometimes a problem becomes simple if we temporarily add something convenient, solve in that setting, and then subtract it away — changing the form, not the value.

Symbolically:\( x = x + a - a \) and \( 17 =\tfrac{1}{2}(18) + \tfrac{1}{3}(18) + \tfrac{1}{9}(18) \)

problem solvingalgebrafolklorenumber theory

Properties of Alpha, Beta, and Gamma Rays

Property	Alpha Rays	Beta Rays	Gamma Rays
Nature	Helium nuclei (2 protons, 2 neutrons)	High-energy electrons or positrons	High-energy electromagnetic waves (photons)
Charge	+2e (positive)	-e (electrons) or +e (positrons)	Neutral (0)
Mass	~4 u (6.644 × 10⁻²⁷ kg)	~1/1836 u (9.109 × 10⁻³¹ kg)	Massless
Penetration Power	Low (stopped by paper or a few cm of air)	Moderate (stopped by a few mm of aluminum)	High (requires several cm of lead or meters of concrete)
Ionization Ability	High (strong interaction with matter)	Moderate (less than alpha)	Low (minimal interaction)
Speed	~5-10% of speed of light (~1.5-3 × 10⁷ m/s)	Up to 99% of speed of light (~3 × 10⁸ m/s)	Speed of light (3 × 10⁸ m/s)

Fine Structure of Sodium D Lines

Spectrum of Neutral Sodium and the D-Line Doublet

1. Electronic Structure of Sodium

• The neutral sodium atom (Na) has 11 electrons.
• 10 electrons are tightly bound in closed inner shells (core electrons).
• These contribute no net angular momentum to the atom.
• The 11^th (valence) electron determines the optical properties and spectrum.

2. Principal Series and the D-Line

The D-line doublet (5890 Å and 5896 Å) belongs to the principal series, arising from transitions between:

• Upper state: P-orbital (L = 1)
• Lower state: S-orbital (L = 0)

Fine Structure Terms:

P-state (L = 1): Spin-orbit coupling splits it into two fine-structure levels:

• ²P_3/2 (J = 3/2)
• ²P_1/2 (J = 1/2)

S-state (L = 0): Only one term:

• ²S_1/2 (J = 1/2)

3. Allowed Transitions

The D-line doublet consists of two allowed transitions:

• D₁ line (5896 Å): ²P_1/2 → ²S_1/2
• D₂ line (5890 Å): ²P_3/2 → ²S_1/2

Selection Rules:

• ΔL = ±1
• ΔJ = 0, ±1 (but J = 0 → J = 0 is forbidden)

4. Origin of the Doublet

The energy splitting between ²P_3/2 and ²P_1/2 is due to spin-orbit coupling. This fine-structure splitting explains the two closely spaced D-line wavelengths.

Do Donkeys Know Physics?

Stern and Gerlach Experiment - Lecture Notes For Atomic Physics

Consolidated Question Bank - Atomic and Nuclear Physics 23BPH5C2 2025

UNIT - I
PART A - 2 MARK QUESTIONS

1. Mention any two drawbacks of Bohr's atom model.
2. What is meant by spatial quantization?
3. Differentiate between LS and JJ coupling.

4. State Pauli's exclusion principle.

5. Define Bohr Magneton and State its formula.

6. What is the outcome of Stern-Gerlach experiment?

7. Write any two selections rules.

PART B - 5 MARK QUESTIONS

1. Explain the Vector atom model and list the associated quantum numbers.
2. Describe the Stern-Gerlach experiment and its significance.
3. Derive the expression for magnetic dipole moment due to orbital and spin motion of the electron.

4. State and explain the selection rules and intensity rule for atomic transitions.

PART C - 10 MARK QUESTIONS

1. Explain the Vector Atom Model in detail. Discuss the quantum numbers associated with it and their significance.
2. Describe the Stern–Gerlach experiment.
3. Discuss in detail L–S coupling and J–J coupling schemes. 

UNIT - II

PART A - 2 MARK QUESTIONS

1. What is meant by excitation potential?

2. Define ionization potential.

3. What are spectral terms? Give an example.

4. Write the notation for the term symbol of the ground state of sodium.

5. What is Zeeman effect?

6. State Larmor’s theorem.

7. Differentiate between normal and anomalous Zeeman effect.

8.What is Paschen–Back effect?

9.What is the Stark effect?

PART B - 5 MARK QUESTIONS

1. Distinguish between excitation potential and ionization potential.
2. Describe Davis and Goucher’s method for the measurement of excitation and ionization potentials.

3. Explain spectral terms and term symbols with suitable examples.

4. Describe the fine structure of sodium D-lines.

5. Write a note on the Paschen–Back effect.

PART C - 10 MARK QUESTIONS

1. Describe the Zeeman effect. State Larmor's theorem and explain the quantum mechanical explanation of the normal Zeeman effect.
2. Discuss the anomalous Zeeman effect and explain how it differs from the normal Zeeman effect.
3. What is the Stark effect? Explain its origin and give the quantum mechanical view.

UNIT - III

PART A - 2 MARK QUESTIONS

1. State Geiger-Nuttal law.

2. List any two properties of alpha particles.

3. Define nuclear isomerism.

4. What is meant by internal conversion?

5. Write note on non-conservation of parity in weak interactions.

6. What are the characteristics of beta rays?

7. State any two properties of gamma rays.

PART B - 5 MARK QUESTIONS

1. State and Explain Geiger-Nuttal law.

2. Write short notes on the properties of alpha, beta, and gamma rays.

3. Explain Gamow's theory of alpha decay.

4. Describe the beta-ray spectrum and explain how it led to the prediction of the neutrino.

5. Write note on internal conversion.

6. Explain nuclear isomerism with an example.

PART C - 10 MARK QUESTIONS

1. Explain the properties of alpha, beta, and gamma rays. How are they distinguished experimentally?

2. Describe Geiger–Nuttall law. Discuss Gamow’s theory of alpha decay and explain how it accounts for the law.

3. Discuss the beta ray spectrum. Explain the neutrino theory of beta decay and how it resolves the conservation issues.

4. What is nuclear isomerism? Explain internal conversion and discuss the violation of parity in weak interactions.

UNIT - IV

PART A - 2 MARK QUESTIONS

1. State any two conservation laws applicable to nuclear reactions.

2. What is meant by Q-value of a nuclear reaction?

3. Define threshold energy.

4. What is scattering cross section?.

5. What is artificial radioactivity? Give an example.

6. Mention any two applications of radio isotopes.

7. Differentiate between thermal neutrons and fast neutrons.

PART B - 5 MARK QUESTIONS

1. State and explain the conservation laws involved in a nuclear reaction.

2. Derive the Q-value equation for a nuclear reaction. What does a positive or negative Q value indicates?

3. Define threshold energy. Derive an expression of an endoergic nuclear reaction.

4. What is artificial radioactivity? Explain with a suitable reaction. 

5. Compare the liquid drop model and shell model of the nucleus.

PART C - 10 MARK QUESTIONS

1. Derive the Q-value equation for a nuclear reaction explain its significance.

2. Explain the concept of threshold energy. Derive the expression for threshold energy in an endoergic reaction.

3. Discuss the liquid drop model of the nucleus. Explain how it accounts for nuclear binding energy and fission.

4. Explain the shell model of the nucleus. How does it account for magic numbers and nuclear properties?.

UNIT - V
PART A - 2 MARK QUESTIONS

1. What are elementary particles? Give two examples.
2. Name the four fundamental interactions in nature.
3. What is isospin?

4. Define the strangeness quantum number.

5. What are quarks? Name any two types.

6. What is meant by latitude effect in cosmic rays?

7. Differentiate between primary and secondary cosmic rays.

PART B - 5 MARK QUESTIONS

1. Classify the elementary particles based on their interaction types.
2. Explain the concept of isospin and strangeness with suitable examples.
3. State the conservation laws obeyed in particle interactions.

4. Write a short note on quark model.

5. Describe the latitude and longitude effects of cosmic rays.

PART C - 10 MARK QUESTIONS

1. Classify the elementary particles. Explain their interaction and properties with suitable example.
2. Discuss the quantum numbers of elementary particles. Explain the significance of isospin and strangeness.
3. Explain the quark model of elementary particles. How do quarks combine to form hadrons?

4. Describe the discovery of cosmic rays. Differentiate between primary and secondary cosmic rays. Explain the latitude and altitude effects.

BB Snapshot of Lecture on Equations of Motion Under Under Uniform Acceleration - 19.06.2025

Syllabus : ATOMIC AND NUCLEAR PHYSICS - V SEMESTER - COURSE CODE : 23BPH5C2

UNIT - I VECTOR ATOM MODEL

Introduction to atom model – vector atom model – electron spin –spatial quantisation– quantum numbers associated with vector atom model – L-S and J-J coupling – Pauli's exclusion principle – magnetic dipole moment due to orbital motion and spin motion of the electron – Bohr magnetron – Stern-Gerlach experiment – selection rules – intensity rule.

UNIT - II ATOMIC SPECTRA

Origin of atomic spectra – excitation and ionization potentials – Davis and Goucher's method – spectral terms and notations – fine structure of sodium D-lines – Zeeman effect –Larmor's theorem – quantum mechanical explanation of normal Zeeman effect – anomalous Zeeman effect (qualitative explanation) –Paschen-Back effect – Stark effect

UNIT - III RADIOACTIVITY

Discovery of radioactivity – natural radio activity – properties of alpha rays, beta rays and gamma rays – Geiger-Nuttal law – alpha particle spectra –Gammow's theory of alpha decay (qualitative study) –beta ray spectra – neutrino theory of beta decay – nuclear isomerism – internal conversion – nonconservation of parity in weak interactions.

UNIT - IV NUCLEAR REACTIONS

Conservation laws of nuclear reaction – Q-value equation for a nuclear reaction – threshold energy – scattering cross section – artificial radio activity – application of radio isotopes – classification of neutrons – models of nuclear structure – liquid drop model – shell model.

UNIT - V ELEMENTARY PARTICLES

Classification of elementary particles – fundamental interactions – elementary particle quantum numbers –isospin and strangeness quantum number – Conservation laws and symmetry – quarks – quark model (elementary ideas only) – discovery of cosmic rays – primary and secondary cosmic rays – latitude effect– altitude effect.

UNIT - VI PROFESSIONAL COMPONENTS

Expert Lectures - Seminars - Webinars - Industry Inputs - Social Accountability - Patriotism

TEXT AND REFERENCE BOOKS

Text Books
1. R. Murugesan, Modern Physics, S. Chand and Co. (All units) (Units IandII-Problems)
2. Brijlaland N. Subrahmanyam, Atomic and Nuclear Physics, S. Chand and Co. (All units)
3.J. B. Rajam, Modern Physics, S. Chand and Co.
4.SehgalandChopra, Modern Physics, Sultan Chand, New Delhi
5.Arthur Beiser– Concept of Modern Physics, McGraw Hill Publication, 6th Edition.
Reference Books
1. Perspective of Modern Physics, Arthur Beiser, McGraw Hill.
2. Modern Physics, S. Ramamoorthy, National Publishing and Co.
3. Laser and Non-Linear Optics by B.B.Laud, Wiley Easter Ltd.,New York,1985.
4.Tayal, D.C.2000 – Nuclear Physics, Edition, Himalaya Publishing House, Mumbai.
5.Irving Kaplan (1962) Nuclear Physics, Second Edition, Oxford and IBH Publish and Co, New Delhi.
6.J.B. Rajam– Atomic Physics, S. Chand Publication, 7th Edition.
7.Roy and Nigam, – Nuclear Physics (1967) First edition, Wiley Eastern Limited, New Delhi.

WEB RESOURCES

1. Hyper Physics Site
2. Making Physics Fun
3. Types of Decay Khan Academy
4. Nuclei Khan Academy