Quantum Computing for Subatomic Physics: State of the Art, Challenges, and Prospects
|Event Date:||December 13, 2018|
|Speaker Affiliation:||Oak Ridge National Lab|
|School or Program:||Electrical and Computer Engineering
Oak Ridge National Lab
Simulations of complex many-body quantum phenomena present a formidable computational challenge. Quantum computing holds promise to drastically improve our simulations capabilities for many-body systems across all scientific domains. We discuss recent progress and challenges in quantum simulations of light nuclei (the deuteron 2H, the triton 3H, 3He, and the alpha particle 4He ) and a prototypical quantum field theory---the Schwinger model---on a multitude of quantum hardware ranging from superconducting circuits to photonics. Our results illustrate the potential of quantum computers to augment classical computations in bridging the scales from quarks to nuclei.
Pavel Lougovski is a researcher in the Quantum Information Science group at Oak Ridge National Lab. His work focuses on various aspects of quantum algorithm development for scientific computing with particular emphasis on algorithms for noisy intermediate-scale quantum hardware. He did his PhD at Max Planck Institute for Quantum Optics (Garching, Germany).