Your search keyword '"Fu-Gao Wei"' showing total 3 results

1. Origin of the Hydrogen Absorbed by Incoherent TiC Particles in Iron

Author

Kaneaki Tsuzaki and Fu Gao Wei

Subjects

Computer Science::Computer Science and Game Theory, Materials science, Hydrogen, Mechanical Engineering, Physics::Medical Physics, Analytical chemistry, Thermal desorption, chemistry.chemical_element, Condensed Matter Physics, Mass spectrometry, Atmosphere, chemistry, Mechanics of Materials, General Materials Science, Physics::Atomic Physics, Hydrogen absorption, High-resolution transmission electron microscopy, Water vapor

Abstract

Hydrogen absorption of incoherent TiC particles that were once reported to be strong hydrogen traps in iron at room temperature was investigated by means of thermal desorption spectrometry (TDS). The results indicated that incoherent TiC particles in iron do not trap hydrogen at all at room temperature even they are cathodically charged for a long time. Only at high temperatures and in atmosphere containing hydrogen source, incoherent TiC particles can trap hydrogen. The origin of hydrogen trapped by incoherent TiC particles was justified to be water vapor in the atmosphere during heat treatment.

Published

2005

2. A New Method to Determine the Activation Energy for Hydrogen Desorption from Steels

Author

Fu Gao Wei, Toru Hara, and Kaneaki Tsuzaki

Subjects

Titanium carbide, Materials science, Thermal desorption spectroscopy, Mechanical Engineering, Analytical chemistry, Thermal desorption, Activation energy, Condensed Matter Physics, Mass spectrometry, Kinetic energy, chemistry.chemical_compound, chemistry, Mechanics of Materials, Particle, General Materials Science, Grain boundary

Abstract

A new method has been developed to determine the activation energy for hydrogen desorption from steels by means of thermal desorption spectrometry (TDS). This method directly fits the Kissinger’s reaction kinetic formula dX/dt=A(1-X)exp(-Ed/RT) to experimentally measured thermal desorption spectrum and best fit yields the activation energy (Ed) and the value of constant A. It has been proven that this new method is applicable to precise measurement of the activation energy for hydrogen desorption from incoherent TiC particle, coherent TiC precipitate, grain boundary and dislocation in 0.05C-0.20Ti-2.0Ni and 0.42C-0.30Ti steels.

Published

2005

3. Effect of Inhomogeneity of Carbide Precipitation on Nanohardness Distribution for Martensitic Steels

Author

Takahito Ohmura, Kaneaki Tsuzaki, Fu Gao Wei, and Jin Xu Li

Subjects

Materials science, Precipitation (chemistry), Atomic force microscopy, Cementite, Mechanical Engineering, Metallurgy, Nanoindentation, Condensed Matter Physics, Carbide, chemistry.chemical_compound, chemistry, Mechanics of Materials, Martensite, General Materials Science, Nanometre, Submicron scale

Abstract

Nanoindentation technique was applied to evaluate nanohardness distribution in a submicron scale for two kinds of martensitic steels: Fe-0.4C binary steel and Fe-0.05C-0.22Ti steel with a stoichiometric composition of TiC. AFM images showed that Fe-C steel includes relatively coarse cementite particles with about 100~200 nm in diameter and a couple of hundreds nanometer in average spacing, while high-resolution TEM observation showed that the Fe-C-Ti steel has fine TiC precipitates with 5 nm in diameter and 15 nm for average spacing. Nanoindentation results revealed that the standard deviation was much higher for the Fe-C than that for the Fe-C-Ti. Since the typical indent size was a couple of hundreds nanometer, which was about two orders larger than the size of the TiC and comparable to the cementite size, the small distribution of nanohardness of the Fe-C-Ti was attributed to the homogeneous microstructure in sub-micron scale, while the inhomogeneity of cementite particles in the Fe-C steel leaded to large nanohardness.

Published

2005