Education:
MSc. in Physics, University of Dhaka (2025-PRESENT)
Highlights:
Graduate coursework in Condensed Matter Physics and Quantum Field Theory (QFT), among others.
Dealt with the Anisotropic Eliashberg Superconductivity and non-trivial topological materials
Multiple Peer-reviewed Publications while working towards thesis.
Created a python based CLI-app to aid with pre-/post-processing of results making high-throughput calculations viable.
Topics:
Superconductivity
Topological insulators
Interactions with Photons
Non-crystalline Solids
Introduction to nanomaterials and nano-composites
Topics:
1. Lorentz and Poincare Symmetries
2. Symmetries, Noether’s Theorem and Conservation laws
3. Gauge theory
4. Quantization of Free fields
5. Perturbation Theory and Feynman Diagrams
6. Cross Sections and Decay rates
7. Quantum Electrodynamics
Topics:
1. Scaling, Scale-invariance and self-similarity
2. Stochastic process, random walk and diffusion
3. Stochastic theory of fragmentation
4. Fractal and Multifractal
5. Complex network theory
6. Phase transition, critical phenomena and percolation theory
Topics:
Structure of the atmosphere,
Composition of the atmosphere
Dynamic Meteorology
Different frames and coordinates
Condensation, precipitation and atmospheric electricity
General circulation of the atmosphere
The Tephigram
Topics:
Neutrons
Nuclear Fission
Duffusion of Neutrons
Slowing Down of Neutrons
The Critical Equation
Reactor Kinetics
Nuclear Heat Removal
Thesis Work
Activities:
Ab Initio Modeling: Employed Quantum ESPRESSO (v7.2) to compute the superconducting critical temperatures ($T_c$) and fundamental physical properties of novel materials.
Advanced Formalisms: Investigated the influence of spin-orbit coupling (SOC) and hydrostatic pressure on phonon dispersions and superconducting states using the fully anisotropic Migdal-Eliashberg formalism.
High-Performance Workflows: Utilized the EPW code for dense Wannier-Fourier interpolation of electron-phonon coupling properties.
Research Automation: Developed QE-Kit, an open-source toolset built to optimize Quantum ESPRESSO inputs and workflows, successfully bridging the gap between high-throughput structural discovery and publication-quality data.
Publications: Authored multiple peer-reviewed manuscripts detailing my findings
Thesis typesetting: coalesced comprehensive findings into a customized, production-ready \LaTeX{} master's thesis template.