スポンサーリンク
Department of Engineering Science, Faculty of Engineering, Kyoto University | 論文
- Enhancement of Effective Excitation Rate Coefficients of lons in Dense Plasma through Doubly Excited States
- Processes of Multiphoton Ionization of Cs_2 in the Wavelength Range 620-670 nm
- Non-Thermal Radiation at Runaway Electron Instability
- Two-Photon Ionization of Cs_2 in the Wavelength Range 5300-6200 A^^゜
- Cyclic Deformation Behavior of Ultra-Fine Grained Copper Produced by Equal Channel Angular Pressing
- Temperature and Strain Rate Dependence of Flow Stress in Severely Deformed Copper by Accumulative Roll Bonding
- Dislocation Bow-Out Model for Yield Stress of Ultra-Fine Grained Materials
- Effects of Grain-Boundary Sliding and Plastic Deformation of Grains on the Formation of Grain-Boundary Cracks in a Double Cylindrical Bicrystal of a Cu-SiO_2 Alloy
- Morphological Evolution of Grain-Boundary SiO_2 in Internally Oxidized Cu-Si Bicrystals
- Elastic States of Inhomogeneous Spheroidal Inclusions
- Electron Affinities of Polystyrene and Poly(2-vinylpyridine) by Low-Energy Electron Inelastie Scattering
- Experimental Study of Conduction Band Structure of Some n-Alkanes and Polyethylene by Means of Low Energy Electron Scattering and Photoelectron Spectroscopy
- Multiphoton Ionization of RbCs in the Wavelength Range 540-620 nm
- Low-Cycle Fatigue of Ultrafine-Grained Aluminum at Low Temperatures
- Effects of Elastic Modulus, Shape and Volume Fraction of an Elastically Inhomogeneous Second Phase on Stress States in a Loaded Composite
- Retardation of Softening of Ultrafine-Grained Copper during Low Temperature Annealing under Uniaxial Tensile Stress
- Morphological and Crystallographic Characteristics of Incoherent Octahedral FCC Co Precipitates in a Cu Matrix
- Appropriateness of the Hencky Equivalent Strain as the Quantity to Represent the Degree of Severe Plastic Deformation
- Surface crack propagation in plate specimens of 1Cr-1Mo-1/4V turbine rotor steel under creep-fatigue condition.
- A New Method of Deriving Fundamental Rate Equations for Ostwald Ripening.