
Leading the World in Quantum Materials Research
The Quantum Materials Center / ASPIRE project aims to establish a world-leading research hub for quantum materials science. Our research focuses on emergent quantum phenomena, topological states, strongly correlated systems, moiré superlattices, and advanced spectroscopic techniques including NanoARPES. Through international collaboration and interdisciplinary approaches, we seek to pioneer next-generation quantum technologies and fundamental discoveries.
Title: 4f-driven surface effects in lanthanide-based materials: Reorientation of 4f moments, 2D ferromagnetism, Kondo and Rashba effects
Place: AIMR 2F Seminar room, Tohoku University
Title: Self-Intercalated Covalent 2D magnets and heterostructures
Place: AIMR 2F Seminar room, Tohoku University
Title: Time-Reversal Symmetric Majorana Modes in 2D Weyl Heterostructures and Machida–Shibata Lattices
Place: AIMR 5F Combination room, Tohoku University
Title: In-situ ARPES and STM investigation of LiTi2O4(111) thin films
Place: AIMR 2F Seminar room, Tohoku University
Title: Real-space evidence for 2D - XY magnetism in atomically thin Fe5GeTe2
Place: AIMR 2F Seminar room, Tohoku University
Title: Accelerating advances in science and technology using artificial intelligence
Place: AIMR 2F Seminar room, Tohoku University
Official website for the Quantum Materials Center / ASPIRE project is now online.
Tohoku University
Advanced Spectroscopy
Tohoku University
NanoMaterials
Tohoku University
Aarhus University
STM and Transport
Tohoku University
Spintronics
University of Washington
Tohoku University
Global Coordinator
Tohoku University
Condensed Matter Theory
Tohoku University
Condensed Matter Theory
Tohoku University
Quantum Devices
Tohoku University
Development of ARPES system
Tohoku University
MBE growth
Tohoku University
Operando ARPES
Tohoku University
Low temperature STM
Tohoku University
Quantum Transport
Tohoku University
Imaging of 2D materials
Tohoku University
Secretary
University of Washington
2D Materials
University of Washington
Condensed Matter Theory
University of Washington
Condensed Matter Theory
Pennsylvania State University
Material growth and Characterization
Pennsylvania State University
Condensed Matter Theory
Advanced spectroscopic measurements of electronic structures.
Topological edge states and correlated quantum systems.
Emergent magnetic phenomena, spin textures, and topological magnetism in quantum materials.
Emergent quantum states in moiré superlattices.
Exploring materials platforms for quantum information, quantum coherence, and next-generation quantum computing technologies.
Designing next-generation quantum devices based on emergent properties of quantum materials.
Designing and discovering novel quantum materials through electronic structure calculations, materials informatics, and advanced theoretical approaches.
Quantum many-body theory, electronic structure calculations, and quantum simulations.
Applying artificial intelligence and data-driven methods to accelerate the discovery, characterization, and control of quantum materials.
Address
AIMR, Tohoku University, 2-1-1, Katahira, Aoba-ku, Sendai, Miyagi, Japan
Email