SciPost logo

SciPost Submission Page

Digital quantum simulation of bosonic systems and quantum complementarity

by Victor P. Brasil, Diego S. Starke, Jonas Maziero

This Submission thread is now published as

Submission summary

Authors (as registered SciPost users): Diego S. Starke
Submission information
Preprint Link: scipost_202503_00053v3  (pdf)
Data repository: https://github.com/victorpbrz/simulations-code/tree/main/Digital%20quantum%20simulation%20of%20bosonic%20systems%20and%20quantum%20complementarity
Date accepted: Oct. 14, 2025
Date submitted: Oct. 7, 2025, 9:22 p.m.
Submitted by: Diego S. Starke
Submitted to: SciPost Physics Core
Ontological classification
Academic field: Physics
Specialties:
  • Quantum Physics
Approaches: Theoretical, Experimental, Computational

Abstract

Digital quantum simulation (DQS) has emerged as a powerful approach to investigate complex quantum systems using digital quantum computers. Such systems, like many-particle bosonic systems and intricate optical experimental setups, pose significant challenges for classical simulation methods. In this paper, we utilize a general formalism for the DQS of bosonic systems, which consists of mapping bosonic operators to Pauli operators using the Gray code, in order to simulate interferometric variants of Afshar's experiment---an intricate optical experiment---on IBM's quantum computers. We investigated experiments analogous to Afshar's double-slit experiment performed by Unruh and Pessoa J\'unior, exploring discussions on the apparent violation of Bohr's complementarity principle when considering the entire experimental setup. Based on the aforementioned experiments, we construct a variation of a delayed-choice setup. We also explore another experiment starting with a two-photon initial state. Finally, we analyze these experiments within the framework of an updated quantum complementarity principle, which applies to specific quantum state preparations and remains consistent with the foundational principles of Quantum Mechanics.

Published as SciPost Phys. Core 8, 086 (2025)

Login to report or comment