Khái niệm cốt lõi
This paper introduces a novel quantum algorithm, V-TEPS, for calculating phase shifts in non-relativistic elastic scattering processes, demonstrating its potential for efficient simulation of scattering phenomena on quantum computers.
Tóm tắt
Bibliographic Information:
Turro, F., Wendt, K. A., Quaglioni, S., Pederiva, F., & Roggero, A. (2024). Evaluation of phase shifts for non-relativistic elastic scattering using quantum computers. arXiv preprint arXiv:2407.04155v2.
Research Objective:
This research paper aims to develop an efficient quantum algorithm for calculating phase shifts in non-relativistic elastic scattering processes, a crucial problem in various fields of physics.
Methodology:
The authors propose a two-step quantum algorithm called Variational Time Evolution Phase Shift (V-TEPS). First, they initialize a quantum system in a truncated plane wave state and evolve it in time using the system's Hamiltonian. Then, they introduce a variational approach by adding a fictitious phase to a detector state and maximizing the overlap probability between the evolved state and the detector state to extract the phase shift. The algorithm is tested using classical simulations with Gaussian and Lennard-Jones potentials in both spatial lattice and momentum basis representations. Finally, the authors implement the algorithm on IBM quantum processors to assess its performance under realistic noise conditions.
Key Findings:
- The V-TEPS algorithm accurately calculates phase shifts for various potentials and momenta, showing good agreement with exact solutions obtained from classical methods.
- The variational approach enhances the algorithm's robustness against noise, making it suitable for near-term quantum devices.
- Implementing the algorithm on IBM quantum processors demonstrates its feasibility and highlights the impact of error mitigation techniques.
Main Conclusions:
The V-TEPS algorithm presents a promising approach for simulating scattering processes on quantum computers. Its efficiency and noise resilience make it a valuable tool for studying quantum systems in nuclear physics, condensed matter physics, and other fields.
Significance:
This research contributes significantly to the development of quantum algorithms for simulating complex physical phenomena. The V-TEPS algorithm offers a practical pathway for leveraging quantum computers to address computationally challenging problems in scattering theory, potentially leading to new insights and discoveries.
Limitations and Future Research:
- The current implementation focuses on single-channel scattering with central potentials. Future work could extend the algorithm to multi-channel scattering and more complex interactions.
- Exploring different quantum state preparation techniques and error mitigation strategies could further improve the algorithm's performance on near-term quantum devices.
- Investigating the algorithm's scalability for larger systems and higher energies will be crucial for addressing more realistic scattering problems.
Thống kê
The paper uses a spatial lattice with 6000 points and a lattice spacing of 0.02 fm for Gaussian potential simulations.
For Lennard-Jones potential simulations, a lattice spacing of 0.02 Å is used.
The momentum basis set simulations utilize up to 512 momenta with a momentum spacing of 0.0084 fm⁻¹ or 0.013 Å⁻¹.
The IBM quantum processor simulations are performed on the "ibm_perth" and "ibm_brisbane" devices.
The quantum circuits for the simulations involve up to 196 CNOT gates in the computational basis and 63 CNOT gates in the eigenbasis of the Hamiltonian.
Trích dẫn
"This work presents a quantum algorithm for a direct evaluation of phase shifts for a generic elastic scattering process, allowing the calculations of angular and total cross section."
"Our method provides an alternative scheme useful in computing phase shifts for elastic scattering in both single and multi-channel cases."
"We found that such variational method makes the TEPS algorithm resistant to some noise sources of quantum processors."