Quantum computers for nuclear physics

Description

We explore the paradigm shift in quantum computing and quantum information science, emphasizing the synergy between hardware advancements and algorithm development. Only now have the recent advances in quantum computing hardware, despite a century of quantum mechanics, unveiled untapped potential, requiring innovative algorithms for full utilization. Project 1 addresses quantum applications in radiative reactions, overcoming challenges in many-fermion physics due to imaginary time evolution, stochastic methods like Monte Carlo simulations, and the associated sign problem. The methodology introduces the Electromagnetic Transition System and a general two-level system for computing radiative capture reactions. Project 2 utilizes Variational Quantum Eigensolver (VQE) to address the difficulties in adiabatic quantum computations, highlighting Singular Value Decomposition (SVD) in quantum computing. Results demonstrate an accurate ground state wavefunction match with only a 0.016% energy error. These projects advance quantum algorithm design, error mitigation, and SVD integration, showcasing quantum computing’s transformative potential in computational science.

Links & Downloads

1. https://scholarsjunction.msstate.edu/td/5995
2. https://scholarsjunction.msstate.edu/context/td/article/7039/viewcontent/Quantum_Computer_Nuclear_Physics_Yusf.pdf

Tags

Quantum Computing

Quantum Algorithms

Nuclear Theory

Transition Matrix Element

VQE

Relaxation Method

SVD

Error Mitigation

Condensed Matter Physics

Nuclear

Quantum Physics

Additional Fields

Identifer	oai:union.ndltd.org:MSSTATE/oai:scholarsjunction.msstate.edu:td-7039
Date	08 December 2023
Creators	Yusf, Muhammad F
Publisher	Scholars Junction
Source Sets	Mississippi State University
Detected Language	English
Type	text
Format	application/pdf
Source	Theses and Dissertations