Moonshot Goal 6
Realization of a fault-tolerant universal quantum computer that will revolutionize economy, industry, and security by 2050.
Target of Moonshot Goal
- Achievement of the large-scale integration required for fault-tolerant universal quantum computers by around 2050.
- Development of a certain scale of NISQ computer and demonstration of the effectiveness of quantum error correction by 2030.
Reference
R&D Projects
PD: KITAGAWA Masahiro (Director, Center for Quantum Information and Quantum Biology, The University of Osaka)
| PM | R&D Project |
|---|---|
| KOASHI Masato
The University of Tokyo |
Research and Development of Theory and Software for Fault-tolerant Quantum Computers |
| KOSAKA Hideo
Yokohama National University |
Development of Quantum Interfaces for Building Quantum Computer Networks |
| TAKAHASHI Hiroki
Okinawa Institute of Science and Technology Graduate University |
Fault-tolerant Quantum Computing with Photonically Interconnected Ion Traps |
| FURUSAWA Akira
The University of Tokyo |
Development of Large-scale Fault-tolerant Universal Optical Quantum Computers |
| MIZUNO Hiroyuki
Hitachi, Ltd. |
Large-scale Silicon Quantum Computer |
| YAMAMOTO Takashi
The University of Osaka |
Quantum Cyberspace with Networked Quantum Computer |
| YAMAMOTO Tsuyoshi
NEC Corporation |
Development of Integration Technologies for Superconducting Quantum Circuits |
| AOKI Takao
Waseda University |
Large-scale quantum hardware based on nanofiber cavity QED |
| OHMORI Kenji
National Institutes of Natural Sciences |
Large-scale and high-coherence fault-tolerant quantum computer with dynamical atom arrays |
| KOBAYASHI Kazutoshi
Kyoto Institute of Technology |
Development of a Scalable, Highly Integrated Quantum Error Correction System |
| TARUCHA Seigo
RIKEN |
Development of scalable Silicon quantum computer technology |
| NAGAYAMA Shota
Keio University |
Scalable and Robust Integrated Quantum Communication System |
