Thin-film research group's research is wide-band gap semiconductors, such as diamond and nitrides, and oxide superconductors, based on the superior crystal growth technologies.
Silicon and compound semiconductor industries continue to function as electronic materials, such as carbon nanotubes and graphene focused on low-dimensional nano-materials.
Membrane proteins such as nuclear and biological molecules of the body-friendly, brain and interface with potential new device concepts Nanobio-device advocated the realization of the research assignments.
The research target is to realize ultra-low power and high functional devices, high-sensitivity devices, and high-precision devices by utilizing nanometer-scale structures.
Micro/nanomechanical devices enable the pursuit of new physical phenomenon that can only be observed in these dynamical systems to probe the fundamental nature of the world as well enabling the development of nanoscience and nanotechnology.
For realizing a new generation of optical devices that will bring about a revolution in optical information/transmission technology, we propose new device operating principles to overcome current limits.
We are conducting a unified research of fabrication, theoretical analysis, and evaluation for photonic crystals, with aiming to overcome various limitations in the today's photonics technologies and to realize breakthroughs in photonic information processing.
We theoretically and experimentally study quantum mechanical properties of photons, electrons and atoms.
Our group theoretically investigates fundamental principles of quantum physics and quantum information processing and how they can be applied to the development of quantum-enabled technologies.
We aim to realize novel /quantum systems from Josephson junction based superconducting circuits that are founded on new physical principles and fabricated using cutting edge technologies. The aim of this work is to both study and harness the opportunities arising from quantum phenomena for new fundamental science and applications that cannot be satisfied by existing technologies.
We study various quantum effects that electrons in the solid state exhibit. We establish a new field of “quantum correlated electronics,” aiming at applications for highly sensitive sensing technology and quantum computers.
We are conducting a unified research of fabrication, theoretical analysis, and evaluation for photonic crystals, with aiming to overcome various limitations in the today's photonics technologies and to realize breakthroughs in photonic information processing.
The center for theoretical quantum physics (TQP) was established in July 2017 to bring like-minded researchers from across NTT together to pursue cutting edge research in this area.
Membrane proteins such as nuclear and biological molecules of the body-friendly, brain and interface with potential new device concepts Nanobio-device advocated the realization of the research assignments.