2024-2025_総合研究院パンフレット(英文)
29/36

Future Development GoalsFig. 1  Heart of the dilution refrigerator for superconducting qubits’ evaluation. Established: April, 2020Our research division aims at optimization of the operation condition for superconducting, optical and spin qubits.This division will contribute to the practical realization of the quantum computer thirty years later.ObjectivesMultiple wideband signal lines can be seen. tsai@rs.tus.ac.jpTokyo University of Science Tokyo University of Science Tokyo University of Science Tokyo University of Science Tokyo University of Science Tokyo University of Science Tokyo University of Science The University of TokyoShibaura Institute of TechnologyThe University of TokyoRikenNECNTTJSTFig. 2  2-bit quantum logic gate. Two transmon-type qubits (cross-shaped structures) are connected by a superconducting resonator.29AffiliationNameBackgroundOurtargetsMoonshotResearch&DevelopmentProgramCollaborationwiththeUniversityofTokyoMembersThe research of quantum computer has been very active during the recent years. One of the reasons of the rapid progress is the improvement in coherence time of the qubit due to the advancement of nanotechnology. However, the current status of the quantum circuit is not yet attained its full implementation. We must accelerate the pace of research and development toward the truly fault-tolerant quantum computer.Jaw-Shen TsaiKaoru SanakaMark Paul SadgroveFumiki Yoshihara (June 2022 - )Noboru WatanabeSatoshi IriyamaYoichiro HashizumeHideaki TakayanagiShohei WatabeYasuhiko Arakawa Seigo TaruchaTsuyoshi YamamotoShiro SaitoJun’ichi Sone(April 2023 - )(Tokyo University of Science, Tsai Laboratory)DirectorProfessor,Research Institute for Science and TechnologyPh.D. In recent years, demonstrations of quantum supremacy by Google and later the University of Science and Technology of China, the establishment of IBM’s commercial quantum computer, and the D-Wave System’s large quantum annealing machines, quantum information processing has made remarkable progress. All of the above systems are based on superconducting qubits, but quantum computing systems based on other systems such as ions, cold atoms, semiconductors, and light are also being actively researched around the world. Our division mainly investigate the superconducting qubit. Qubit cause errors like ordinary classical semiconductor circuits. Malfunction of the qubit also would come from the breakdown of the quantum superposition state. Such phenomenon is called decoherence. The fault-tolerant quantum computer would be realized by employing a quantum error correction procedure, and it would deliver truly practical applications. The division plans to carry out research of several kinds of fault-tolerant quantum circuits with superconducting qubits. It is expected that the fault-tolerant quantum computer would appear by 2050, and we would try to contribute to its realization. In this division, we have succeeded in developing a novel qubit called a superconducting bosonic qubit and have shown that it is a scalable quantum information processing platform. In the future, we are planning a demonstration experiment of quantum error correction using these qubits. Integrability and operability are the advantages of superconducting qubits, and it’s disadvantage, the short coherence time, have been significantly improved in recent years. Beside the superconducting qubit, qubits based on other physical systems, like photon, ion, cold atom and electron spin in quantum dot have been investigated. In our division, optical qubit is also being investigated, along with the superconducting qubit. The research subject “Developing bosonic code using superconducting resonator” was adopted to the government moonshot research & development program in 2020. The program leader is Dr. Tsai and Drs. Yoshihara, Takayanagi, Watabe and Hashizume join this program. This program continues until 2025(https://ms-iscqc.jp). Other research activity of the division is the collaborated one with the University of Tokyo. The partner organizations are the Institute for Nano Quantum Information Electronics(http://www.nanoquine.iis.u-tokyo.ac.jp/)and Quantum Innovation Co-creation Center. The research subject is quantum optics utilizing single photon. Drs. Sanaka, Sadgove, join this activity.Tsai Jaw-ShenNanotechnology and its applications to quantum information and electronicsDivision of Nano-quantum Information Science and Technology

元のページ  ../index.html#29

このブックを見る