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Portrait of Hemant Verma

Hemant Verma

Computational Semiconductor Physics 

National Taiwan University · Academia Sinica · IIT Jodhpur

First-principles simulations and quantum transport for next-generation semiconductor devices — DFT electronic structure, electron–phonon coupling, and NEGF modeling of 2D TMD transistors.

6
Peer-reviewed papers
2
Manuscripts under review
2
Conference presentations
5+
Years of research
Latest

News & Highlights

Recent publications, awards, and conference activity.

2026

Two manuscripts under review/submitted: anisotropic hot-carrier relaxation in TiN thin films (Surfaces and Interfaces; preprint on arXiv) and semiconductor-to-half-metal tuning in BA2PbBr4 (Surfaces and Interfaces).

Oct 2025

Presented poster P-196 at the 26th Asian Workshop on First-Principles Electronic Structure Calculations (ASIAN-26), Tsukuba, Japan.

2025

Received the Best Paper Award from the Center for Theoretical Physics, National Taiwan University.

2025

Two papers published in Nano Energy on perovskite quantum-dot inks and Li+ transport in solid-state battery electrolytes.

Jan 2025

Presented at the Taiwan Physical Society Annual Meeting, National Sun Yat-sen University, Kaohsiung.

What I work on

Research Interests

Bridging atomistic first-principles physics with device-relevant transport behavior.

TCAD-Oriented Device Physics

Linking atomistic, first-principles properties to device-level metrics.

Focus: transport, carrier lifetime, and mobility trends for device modeling

Quantum Transport for Nanoscale FETs

NEGF-based modeling of nanoscale transistor channels and scaling behavior.

Tools: NanoDCAL — I–V characteristics and transmission spectra

2D Semiconductors (TMDs)

Channel physics, band alignment, and transport-limiting mechanisms.

Application: next-generation 2D TMD transistors

Electronic Structure & Electron–Phonon Coupling

DFT electronic structure with EPC-driven scattering rates and lifetimes.

Methods: VASP, Quantum ESPRESSO, JDFTx, Wannier90 + EPW

Open source

Software & Tools

Research software I build and maintain.

SolarXPlot

Solar-cell data analysis & plotting

An open-source tool that lets non-coding experimentalists analyze and visualize solar-cell measurement data without writing code — built for fast, reproducible figures.

Open Source Python Solar Cells Data Viz
Selected work

Publications

Peer-reviewed articles and manuscripts in progress. Filter by year below.

2025

6.

Probing Interfacial Chemistry of Functionalized Ceramic Nanoparticles to Optimize Li+ Pathways in Polymer Electrolytes for Solid-State Lithium Metal Batteries

P. Srivastva, B. Bazri, Y.-T. Hung, Hemant Verma, et al.

Nano Energy 2025, 146, 111559. DOI ↗

5.

High-Efficiency and Ultrastable Solvent-Free Curable Perovskite Quantum Dot Inks for MicroLED and LED Backlighting Applications

L. T. Ngo, Y.-T. Huang, C.-C. Chang, Hemant Verma, et al.

Nano Energy 2025, 142, 111230. DOI ↗

4.

Design and Simulation of Perovskite Solar Cells: A Numerical Approach Towards Device Structure Optimization

C. Guru Santosh, Hemant Verma, S. S. Singh, T. G. Kanakadas, S. B. Lekshmi, A. Mohapatra, M. L. Meena

In National Conference on Climate Resilience and Environmentally Sustainable Technologies 2025, 133–142. Link ↗

2024

3.

Hybrid-Protected Perovskite Quantum Dot Films with Ultra-High Efficiency and Stability for LED Backlighting

Loan Thi Ngo, Wen-Tse Huang, Hemant Verma, Yen-Huei Lin, Ling-Wei Liang, Chia-Te Fang, Jia-Cheng Chang, Wen-Chung Chu, Chaochin Su*, Chao-Cheng Kaun*, and Ru-Shi Liu*

ACS Applied Materials & Interfaces 2024, 16 (48), 66262–66272. DOI ↗

2.

Cascaded-Type Band Alignment of a WBG Perovskite/NBG Perovskite for Heterostructure Solar Cells

Anjali Thakran, Anisha Mohapatra, Hemant Verma, Mario Hofmann, Zeeshan Alam Ansari, Chintam Hanmandlu, Chung Hsin Lu, and Chih Wei Chu*

ACS Applied Energy Materials 2024, 7 (8), 3039–3048. DOI ↗

2021

1.

Enhanced Photocatalytic Activity in Strain Engineered Janus WSSe Monolayers

Hemant Verma, Abhijeet J. Kale, Chandra Prakash, Moussab Harb, Ambesh Dixit*

Journal of Electronic Materials 2021, 50, 7230–7239. DOI ↗

Manuscripts Under Review / Submitted

Anisotropic Hot Carrier Relaxation Mediated by Electron–Phonon Scattering in TiN Thin Films

Hemant Verma, T.-Y. Peng, et al.

Under review in Surfaces and Interfaces (2026). Preprint: arXiv:2607.11237 ↗

Electronic and Optical Responses in BA2PbBr4: From Semiconductor to Half-Metal via 3d Transition-Metal Doping

Hemant Verma, S.-C. Huang, C.-C. Kaun*

Under review in Surfaces and Interfaces (2026).

* Corresponding author

Background

Curriculum Vitae

Education, research experience, skills, and recognitions.

Hemant Verma

Hemant Verma

Ph.D. Candidate, Computational Semiconductor Physics

verma.12@alumni.iitj.ac.in

(+886) 908 363 245

  Download CV (PDF)

Professional Summary

Computational semiconductor physicist focused on first-principles simulations and transport physics for TCAD applications, with academic training from IIT Jodhpur (M.Sc. Physics) and National Taiwan University (Ph.D. Physics), Taiwan. Experienced in DFT-based electronic structure, EPC-driven lifetimes, and translating atomistic results into device-relevant parameters (mobility trends, relaxation, band alignment). Skilled in HPC simulations and Python automation. Currently developing NEGF (NanoDCAL) quantum transport workflows for 2D TMD transistor I–V and transmission analysis.

Education

Ph.D. in Physics

National Taiwan University, Taiwan

Taiwan International Graduate Program (TIGP) – Computational Materials Science · CGPA: 3.94/4.3

2021–Present

M.Sc. in Physics

Indian Institute of Technology (IIT) Jodhpur, India

CGPA: 8.19/10

2019–2021

B.Sc. in PCM

University of Rajasthan, India

2016–2019

Research Experience

Ph.D. Researcher – Electronic Structure, EPC & Transport Modeling

Research Center for Applied Sciences (RCAS), Academia Sinica

2021–Present

  • Performed large-scale DFT simulations (VASP, Quantum ESPRESSO, JDFTx) to characterize electronic structure and carrier behavior in TiN and NbN (thin-film and orientation-dependent trends).
  • Computed electron–phonon coupling (Wannier90 + EPW) to extract scattering rates and carrier lifetimes, enabling physics-based interpretation of mobility-limiting mechanisms.
  • Modeled anisotropic carrier transport using Boltzmann transport formalisms; linked crystallographic orientation to transport/relaxation pathways.
  • Built automated Python post-processing pipelines for band/DOS analysis, EPC-derived lifetime statistics, and optical property visualization.
  • Executed production-scale simulations on HPC clusters (Slurm/PBS); optimized convergence strategy (k-point sampling, smearing, cutoff, parallel efficiency).
  • Initiated NEGF-based quantum transport simulations using NanoDCAL for 2D TMD transistor modeling, targeting I–V characteristics and transport trends.

M.Sc. Thesis – Strain-Induced Band Engineering in 2D Semiconductors

Department of Physics, IIT Jodhpur

2019–2021

  • Modeled strain-dependent bandgap and band alignment tuning in Janus WSSe monolayers using DFT.
  • Predicted photocatalytic activity changes by correlating electronic structure modulation with redox potential alignment.

Core Technical Competencies

  • Electronic structure engineering: band structure, DOS, effective mass trends, Fermi-level-dependent behavior
  • Electron–phonon coupling: EPC matrix elements, scattering rates, carrier lifetime extraction
  • Transport modeling: Boltzmann transport formalism, mobility trends, anisotropic transport interpretation
  • Quantum transport (NEGF): transmission spectra, quantum conductance trends, nanoscale transistor I–V workflow
  • Interfaces: work function analysis, band alignment concepts, thin-film orientation dependence
  • Optical response: dielectric function, absorption spectra, electronic transition analysis
  • HPC automation: parallel DFT workflows, convergence optimization, Python post-processing pipelines

Selected Projects

EPC-limited relaxation in TiN/NbN

Quantified temperature-dependent scattering rates and lifetimes; analyzed anisotropy versus crystal orientation for thin-film transport interpretation.

3d TM-doped 2D Perovskite

Quantified optoelectronic property tuning via 3d transition-metal doping and identified a semiconductor-to-half-metal transition.

Thermal stress & deformation analysis of silicon chips in epoxy encapsulation

Analyzed thermomechanical stress, deformation behavior, and reliability implications in epoxy-encapsulated silicon chip structures.

SolarXPlot – open-source software

Developed an open-source solar cell data analysis and plotting tool for non-coding experts. Project link ↗

NEGF-based transistor modeling in 2D TMDs (NanoDCAL)

Initiated a quantum transport workflow for nanoscale FET channels; analyzed transport signatures for device-relevant performance trends.

Technical Skills

Methods

DFT, GW, Wannier interpolation, electron–phonon coupling, Boltzmann transport, NEGF quantum transport

Software

VASP, Quantum ESPRESSO, JDFTx, EPW, Wannier90, NanoDCAL

Programming

Python (NumPy, Pandas, Matplotlib), Bash, Git

HPC

Slurm/PBS job scripting, parallel computing, convergence optimization

Visualization

VESTA, XCrySDen, Matplotlib

Experimental & characterization background

Licensed/experienced user of XPS, UPS, SEM, AFM, UV-Vis and photoluminescence spectroscopy; thin-film deposition (ALD, PVD, spin/spray/dip/blade coating) and perovskite device fabrication in glovebox environments.

Honors & Awards

Best Paper Award

Center for Theoretical Physics, National Taiwan University

2025

TIGP Fellowship

Taiwan International Graduate Program, Academia Sinica

2021–Present

Rajiv Gandhi Academic Scholarship

Government of India

2023

INSPIRE Scholarship

Top 1% in HSC Board examinations

2016

Conferences, Summer Schools & Workshops

26th Asian Workshop on First-Principles Electronic Structure Calculations (ASIAN-26)

Tsukuba International Congress Center, Japan

Poster P-196: "Orientation-Dependent Hot Carrier Relaxation in TiN Thin Films Facilitated by Electron–Phonon Scattering" · Financial support: NCTS

Oct 2025

Taiwan Physical Society Annual Meeting

National Sun Yat-sen University, Kaohsiung, Taiwan

Poster: "Impact of Crystal Orientation on Hot Carrier Lifetimes in Titanium Nitride" · Financial support: Academia Sinica

Jan 2025

Summer School on First-Principles Computational Materials – Advanced Level

National Tsing Hua University (NTHU), Hsinchu, Taiwan

Financial support: NCTS

2024

22nd Workshop on First-Principles Computational Materials Physics

Tainan, Taiwan

Financial support: NCTS

Aug 2024

Network & Membership

Section Editor

Indonesian Physical Review

2020–2021

In the classroom

Teaching

Courses I teach and the resources I build for students.

Quantum Mechanics I — Fall 2025

Phys8067 · 114-1 · TIGP, Academia Sinica

Course hub for the Fall 2025 offering of introductory graduate quantum mechanics (TIGP) that I supported as teaching assistant — syllabus and weekly topics, homework, lecture notes, reference books, and a student results portal. Kept online as a reference for anyone who wants to revisit the material.

Quantum Mechanics Phys8067 Fall 2025 Teaching Assistant
hemant0723.github.io/Quantum-Mechanics/

Live preview of the Fall 2025 course hub — scroll and click inside, or open it full-screen.

Learn

Tutorials

Notes and walkthroughs on scientific computing tools.

Python Basics

Introduction to Python

Learn the basics of Python programming, including syntax, data types, and control structures.

Python Programming
View Tutorial

To be continued...

MATLAB Basics

Introduction to MATLAB

Get started with MATLAB, covering basic operations, plotting, and scripting.

MATLAB Engineering
View Tutorial

To be continued...

Say hello

Contact

Happy to discuss research, collaborations, or opportunities.

verma.12@alumni.iitj.ac.in

Research Center for Applied Sciences, Academia Sinica, Taipei, Taiwan

(+886) 908 363 245

National Taiwan University (TIGP) · Academia Sinica (RCAS)

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