His primary areas of investigation include Condensed matter physics, Superconductivity, Crystal structure, Crystallography and High-temperature superconductivity. His Condensed matter physics research integrates issues from Pyrochlore, Colossal magnetoresistance, Magnetoresistance and Hall effect, Electrical resistivity and conductivity. His work on Meissner effect as part of general Superconductivity study is frequently connected to Inorganic compound, therefore bridging the gap between diverse disciplines of science and establishing a new relationship between them.
Yoshimi Kubo has included themes like Analytical chemistry, Curie temperature and Lattice constant in his Crystal structure study. His work carried out in the field of Crystallography brings together such families of science as X-ray crystallography, Stoichiometry and Oxygen content. His study in High-temperature superconductivity is interdisciplinary in nature, drawing from both Electron mobility and Critical field.
His primary areas of study are Condensed matter physics, Superconductivity, Chemical engineering, Electrode and Analytical chemistry. His Condensed matter physics study combines topics in areas such as Pyrochlore, Hall effect and Colossal magnetoresistance. His Superconductivity research includes themes of Crystallography, Magnetic susceptibility, Mineralogy and Electrical resistivity and conductivity.
His research integrates issues of Electron diffraction and Stoichiometry in his study of Crystallography. His work in Electrode covers topics such as Fuel cells which are related to areas like Waste management. His studies deal with areas such as Oxide, Thin film, Annealing, X-ray crystallography and Transition temperature as well as Analytical chemistry.
Electrolyte, Chemical engineering, Lithium, Electrode and Inorganic chemistry are his primary areas of study. The study incorporates disciplines such as Battery and Ion transporter in addition to Electrolyte. When carried out as part of a general Chemical engineering research project, his work on Dissolution is frequently linked to work in Mechanism, therefore connecting diverse disciplines of study.
His Lithium research includes themes of Optoelectronics, Crystallization, Graphene and Analytical chemistry. His Analytical chemistry research incorporates elements of Secondary ion mass spectrometry, Lattice constant, Lithium–air battery, X-ray crystallography and Lithium battery. His Electrode study incorporates themes from Porosity, Potassium ions, Nanotechnology, Carbon nanotube and Silicon.
Yoshimi Kubo mostly deals with Lithium, Electrolyte, Electrode, Inorganic chemistry and Battery. His studies in Lithium integrate themes in fields like Deposition, Nanotechnology and Dissolution. His Deposition research incorporates themes from Electrochemistry and Analytical chemistry.
Electrochemistry is often connected to Chemical engineering in his work. His work in the fields of Electrode, such as Lithium peroxide, intersects with other areas such as Diffusion. His Battery research is multidisciplinary, relying on both Nuclear engineering, Composite material, Deposition and Current.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Superconductivity at 33 K in CsxRbyC60
K. Tanigaki;T. W. Ebbesen;S. Saito;J. Mizuki.
Crystal structures and ferroelectric properties of SrBi2Ta2O9 and Sr0.8Bi2.2Ta2O9
Y. Shimakawa;Y. Kubo;Y. Nakagawa;T. Kamiyama.
Applied Physics Letters (1999)
Crystal structure and ferroelectric properties of A Bi 2 Ta 2 O 9 ( A = Ca , Sr, and Ba)
Y. Shimakawa;Y. Kubo;Y. Nakagawa;S. Goto.
Physical Review B (2000)
Giant magnetoresistance in Ti 2 Mn 2 O 7 with the pyrochlore structure
Y. Shimakawa;Y. Kubo;T. Manako.
Preparation of fine platinum catalyst supported on single-wall carbon nanohorns for fuel cell application
T. Yoshitake;Y. Shimakawa;S. Kuroshima;H. Kimura.
Physica B-condensed Matter (2002)
Crystal and electronic structures of Bi4−xLaxTi3O12 ferroelectric materials
Y. Shimakawa;Y. Kubo;Y. Tauchi;H. Asano.
Applied Physics Letters (2001)
Superconductivity in sodium-and lithium-containing alkali-metal fullerides
K. Tanigaki;I. Hirosawa;T. W. Ebbesen;J. Mizuki.
Toxicity of single-walled carbon nanohorns
Jin Miyawaki;Masako Yudasaka;Takeshi Azami;Yoshimi Kubo.
ACS Nano (2008)
Magnetic-field penetration depth in TI2Ba2CuO6+δ in the overdoped regime
Y. J. Uemura;A. Keren;L. P. Le;G. M. Luke.
Transport and magnetic properties of Tl 2 Ba 2 CuO 6+δ showing a δ-dependent gradual transition from an 85-K superconductor to a nonsuperconducting metal
Y. Kubo;Y. Shimakawa;T. Manako;H. Igarashi.
Physical Review B (1991)
If you think any of the details on this page are incorrect, let us know.
We appreciate your kind effort to assist us to improve this page, it would be helpful providing us with as much detail as possible in the text box below: