Quantum Simulation

Context

The development of quantum computing across several technologies and platforms has reached the point of having an advantage over classical computers for an artificial problem, a point known as ‘quantum advantage’. As a next step along the development of this technology, it is now important to discuss ‘practical quantum advantage’, the point at which quantum devices will solve problems of practical interest that are not tractable for traditional supercomputers. Many of the most promising short-term applications of quantum computers fall under the umbrella of quantum simulation: modelling the quantum properties of microscopic particles that are directly relevant to modern materials science, high-energy physics and quantum chemistry. This would impact several important real-world applications, such as developing materials for batteries, industrial catalysis or nitrogen fixing. Much as aerodynamics can be studied either through simulations on a digital computer or in a wind tunnel, quantum simulation can be performed not only on future fault-tolerant digital quantum computers but also already today through special-purpose analogue quantum simulators. Here we overview the state of the art and future perspectives for quantum simulation, arguing that a first practical quantum advantage already exists in the case of specialized applications of analogue devices, and that fully digital devices open a full range of applications but require further development of fault-tolerant hardware. Hybrid digital–analogue devices that exist today already promise substantial flexibility in near-term applications.^[1]

Professor Andrew Daley, of Strathclyde's Department of Physics, lead author of the paper, says that "there has been a great deal of exciting progress in analog and digital quantum simulation in recent years, and quantum simulation is one of the most promising fields of quantum information processing. It is already quite mature, both in terms of algorithm development, and in the availability of significantly advanced analog quantum simulation experiments internationally." ^[2]

Hardware Solutions

Physicists are working with so-called analog quantum simulators—machines that can’t act like a general-purpose computer, but rather are designed to explore specific problems in quantum physics. A classical computer would have to run for thousands of years to compute the quantum equations of motion for just 100 atoms. A quantum simulator could do it in less than a second.^[3][4]

Software Solutions

https://news.cision.com/chalmers/r/open-source-software-to-speed-up-quantum-research,c3790042

References

1. ↑ Andrew J. Daley +6, Practical quantum advantage in quantum simulation Nature (2022) 607 , pages 667–676
2. ↑ University of Strathclyde, A roadmap for the future of quantum simulation (2022-07-29) https://phys.org/news/2022-07-roadmap-future-quantum-simulation.html
3. ↑ Peter Byrne, Analog Simulators Could Be Shortcut to Universal Quantum Computers Quanta Magazine (2015-05-06) https://www.scientificamerican.com/article/analog-simulators-could-be-shortcut-to-universal-quantum-computers/
4. ↑ The Center for Quantum Information and Control (CQuIC) https://cquic.unm.edu/research/research-groups/deutsch-research-group/index.html