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MPH 4: Quantum Mechanics-I

Title Name	IGNOU MPH 4 SOLVED ASSIGNMENT
Type	Soft Copy (E-Assignment) .pdf
University	IGNOU
Degree	MASTER DEGREE PROGRAMMES
Course Code	MSCPH
Course Name	Master of Science (Physics)
Subject Code	MPH 4
Subject Name	Quantum Mechanics-I
Year	2026
Session	-
Language	English Medium
Assignment Code	MPH 4/Assignment-1/2026
Product Description	Assignment of MSCPH (Master of Science (Physics)) 2026. Latest MPH 004 2026 Solved Assignment Solutions
Last Date of IGNOU Assignment Submission	Last Date of Submission of IGNOU BEGC-131 (BAG) 2025-26 Assignment is for January 2026 Session: 30th September, 2026 (for December 2025 Term End Exam). Semester Wise January 2025 Session: 30th March, 2026 (for June 2026 Term End Exam). July 2025 Session: 30th September, 2025 (for December 2025 Term End Exam).
Format	Ready-to-Print PDF (.soft copy)

📅 Important Submission Dates

January 2026 Session: 31st March, 2026
July 2026 Session: 30th September, 2026

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MPH 4 2025 - English

Tutor Marked Assignment

QUANTUM MECHANICS-I

Course Code: MPH-004

Assignment Code: MPH-004/TMA/2025

Max. Marks: 100

Note: Attempt all questions. The marks for each question are indicated against it.

PART A

a) Estimate the kinetic energy of the neutrons in a neutron beam that can be used to probe lattice structures with an interatomic spacing of 0.3 nm. The mass of the neutron is 1.675 x 10-²⁷ kg.

b) Calculate the probability current density for the wavefunction: w(x) = f(x)exp[ig(x)].

c) The wavefunction of particle of mass m confined to move in one dimension is ψ(x) = Nx exp(-ax), 0 ≤ x ≤∞. Calculate the normalization constant N and the expectation value of 1/x.

d) Show that [x², px²] = 2ih(xpx +p _xx)

a) Consider a one dimensional potential well with an infinite barrier at x = 0 and a finite potential V for x ≥ L. Solve the Schrödinger equation for a particle of mass m inside the well with an energy E <V. Using the boundary conditions, derive the equation for its eigen energies.

b) Calculate the probability that a simple harmonic oscillator in its ground state will be found beyond the classical turning points.

c) Consider an electron in the state

$psi(overline{r})=Nleft(psi_{100}+2sqrt{2}ipsi_{210}+4psi_{21-1} ight)$

where , are the Hydrogen atom eigenfunctions. Determine the normalization constant N and the expectation values of the energy, L² and L^z.

PART B

3. a) Show that a linear combination of the degenerate eigenvectors of an operator belonging to a particular eigenvalue of the operator is also an eigenvector belonging to the same eigenvalue.

b) The orthonormal bases for a three-dimensional Hilbert space is described by Image ignou-ignouacademy-com-ignou-mph-4-solved-assignment-html-p-solved-19407 . The action of an operator Ô in this space is given by:

$hat{O}vertphi_1 angle=2vertphi_2 angle;quadhat{O}vertphi_2 angle=-3vertphi_3 angle;quadhat{O}vertphi_3 angle=vertphi_1 angle$

Obtain the matrix representation of this operator.

c) A two state system has the orthonormal energy eigenkets IE₁) and IE2) with eigenvalues E_₁ and E₂. If the initial state of the system is given by Image ignou-ignouacademy-com-ignou-mph-4-solved-assignment-html-p-ignou-58985 , determine .

d) Derive the Heisenberg equations of motion for the simple harmonic oscillator.

a) i) Show that the Hamiltonian for a simple harmonic oscillator can be written in terms of the raising and lowering operators as Ĥ =

Image ignou-ignouacademy-com-ignou-mph-4-solved-assignment-html-p-ignou-12111

ii) Obtain the value of * (n|p^-2|n) for the eigenket | n) of t of the simple harmonic oscillator.

b) i) Write down the angular momentum states |j,mj) for j = 2 and the eigenvalue of J² and J_₂ for each of these states.

ii) Determine J+ 2,1) and J_|2,1).

c) The Hamiltonian for an electron at rest in a magnetic field Bo along the z-direction is Image ignou-ignouacademy-com-ignou-mph-4-solved-assignment-html-p-assignment-61522 , where . Given that the initial state of the system is determine the state and at al later time t.

MPH 004 (January 2026 - July 2026) - ENGLISH

Tutor Marked Assignment
QUANTUM MECHANICS-I

Course Code: MPH-004
Assignment Code: MPH-004/TMA/2026
Max. Marks: 100

Note: Attempt all questions. The marks for each question are indicated against it.

PART A

1. a) Electrons are accelerated through a potential 150 V and incident on a crystal with interatomic spacing $d = 0.20\text{ nm}$ . Calculate the de Broglie wavelength and the first-order Bragg diffraction angle.

b) Estimate the uncertainty in the energy of a photon localized within a distance of $0.1\text{ nm}$ .

c) i) Normalize the wave function:
$$\psi(x,0) = N \left[ \sin\left( \frac{\pi x}{L} \right) + \sin\left( \frac{2\pi x}{L} \right) \right], 0 \le x < L.$ $
ii) Calculate the expectation value of x for a particle in this state.

d) A quantum mechanical particle in one dimension has the wave function:
$$\psi(x) = Nx^n : x > 0 ; n > 1.$ $
Use the Schrödinger equation to determine the corresponding potential V(x).
2. a) A 1.5 mA beam of electrons enters a sharply defined boundary with a velocity $3.0 \times 10^6\text{ ms}^{-1}$ , and then its velocity reduces to $2.0 \times 10^6\text{ ms}^{-1}$ , due to the difference in potential. Calculate the transmitted and reflected currents.
b) Show that for any stationary state of a symmetric potential well: $\langle x^2 \rangle \ne 0$ .

c) Calculate the expectation value of the potential energy for the first excited state of a simple harmonic oscillator.

d) i) Write down the eigenfunctions for the $\psi_{300}$ and $\psi_{310}$ states of the hydrogen atom.
ii) Write the eigenvalues of $\hat{L}^2$ and $\hat{L}_z$ for the states $\psi_{300}$ and $\psi_{310}$ .
iii) Calculate the most probable value of r for the hydrogen atom in the state $\psi_{210}$ .

PART B

3. a) Consider the following state vectors: $|\psi\rangle = \begin{pmatrix} 1 \\ i \\ -1 \end{pmatrix}; |\phi\rangle = \begin{pmatrix} 2 \\ 1-i \\ i \end{pmatrix}$ . Calculate (i) the norm of $|\psi\rangle$ and (ii) the inner product $\langle\psi|\phi\rangle$ .

b) If an operator $\hat{O}$ is Hermitian and an operator $\hat{U}$ is unitary, show that the operator $\hat{U}\hat{O}\hat{U}^{-1}$ is Hermitian.

c) The spectral representation of an operator $\hat{\Omega}$ in a two-dimensional orthonormal basis $|\phi_1\rangle,|\phi_2\rangle$ is
$$\hat{\Omega} = 3|\phi_1\rangle\langle\phi_1| + \sqrt{2}|\phi_1\rangle\langle\phi_2| + \sqrt{2}|\phi_2\rangle\langle\phi_1| + 2|\phi_2\rangle\langle\phi_2|$ $
Determine the matrix elements of $\Omega$ .

d) $|1\rangle$ and $|2\rangle$ are the orthonormal basis states of a two-dimensional Hilbert space. A Hermitian operator $\hat{A}$ in this basis is given by the spectral representation: $\hat{A} = 3|1\rangle\langle1| - 1|2\rangle\langle2|$ . For a normalized state given by
$$|\psi\rangle = \frac{1}{2}|1\rangle + \frac{\sqrt{3}}{2}|2\rangle, \text{ calculate } \langle\hat{A}\rangle \text{ and the root mean square deviation in } \hat{A} .$ $

e) Derive the Heisenberg equations of motion for $\hat{S}_x$ and $\hat{S}_y$ for the Hamiltonian $\hat{H} = \omega\hat{S}_z$ .

4. a) For the simple harmonic oscillator
i) Show that $[\hat{H}, \hat{a}] = -\hbar\omega\hat{a}$ .
ii) Calculate the matrix element $\langle n|\hat{x}|n + 1\rangle$

b) i) Write down the angular momentum states $|j, m_j\rangle$ and calculate the matrix elements of $\hat{J}_x, \hat{J}_y$ and $\hat{J}_z$ for $j = 1/2$ .
ii) For the angular momentum state $|3,1\rangle$ show that $J_+|3,1\rangle = \hbar\sqrt{10}|3,2\rangle$ and $J_-|3,1\rangle = 2\hbar\sqrt{3}|3,0\rangle$ .

c) Show that in the terms of the $|\uparrow\rangle$ and $|\downarrow\rangle$ basis vectors defined by
$\hat{S}_z|\uparrow\rangle = \frac{\hbar}{2}|\uparrow\rangle$ ; $\hat{S}_z|\downarrow\rangle = -\frac{\hbar}{2}|\downarrow\rangle$ , we can write: $\hat{S}_x = \frac{\hbar}{2} \left[ |\uparrow\rangle\langle\downarrow| + |\downarrow\rangle\langle\uparrow| \right]$

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