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Department of Physics, Nagoya University | 論文
- Solitary Waves in One-Dimensional Hydrogen-Bonded Systems
- π-Electronic Contribution to the Conformation of DNA
- Nonlinear Schrodinger Equation on the Molecular Complex in Solution : Towards a Biophysics
- Changes in groundwater level associated with the 2003 Tokachi-oki earthquake
- High Spin Polarization of Conduction Band Electrons in GaAs-GaAsP Strained Layer Superlattice Fabricated as a Spin-Polarized Electron Source
- High Luminescence Polarization of InGaAs-AlGaAs Strained Layer Superlattice Fabricated as a Photocathode of Spin-Polarized Electron Source : Optical Properties of Condensed Matter
- Spin-Dependent Luminescence of Highly Polarized Electrons Generated by Two-Photon Absorption in Semiconductors : Optical Properties of Condensed Matter
- Spin Relaxation of Electrons in Graded Doping Strained GaAs-Layer Photocathode of Polarized Electron Source
- Spin Dependent Luminescence of GaAs Thin Layers under Tensile Strain and Compressive Strain Induced by Interface ess
- Circular Polarization of Photoluminescence Excitation Spectra of Strained GaAs Layer
- Derivation of the Kuramoto-Sivashinsky Equation Using the Renormalization Group Method : Condensed Matter and Statistical Physics
- Production of Monochromatic γ Rays from Thin Crystal of Silicon
- Inelastic Scattering of Nucleons by Nuclei
- Theoretical Study of the Phase Diagram of β'-(BEDT-TTF)_2AuCl_2 at Hydrostatic Pressure(Condensed matter: electronic structure and electrical, magnetic, and optical properties)
- Phase Diagram of β'-(BEDT-TTF)_2ICl_2 under High Pressure Based on the First-Principles Electronic Structure(Condensed Matter : Electronic Structure, Electrical, Magnetic and Optical Properties)
- Phase Diagram of β'-(BEDT-TTF)_2ICl_2 under High Pressure Based on the First-Principles Electronic Structure
- K^+-K^0 Mass Difference
- A Controlled Drift Space in Proportional Wire Chambers for Ionization Loss Measurement
- Preparation of Ultrafine Powder of SiC by a Modified Gas-Evaporation Method
- Sum Rules of the Multiple Giant Resonance States(Nuclear Physics)