Home  |  Organizers  |  Proceedings Editors  |  Proceedings Contributors  |  Search  | Quick Links World Scientific Corporate Home WorldSciNet WorldSciBooks WorldSciNet Archives About Us Contact Us
Browse by Subject Asian Studies Business and Management Chemistry Computer Science Economics and Finance Engineering Environmental Science General Interest History of Science Life Sciences Materials Science Mathematics Medicine and Healthcare Nanotechnology and Nanoscience Nonlinear Science Physics Popular Science Social Sciences

Title:	MAGNETIC INTERACTION OF HYPOTHETICAL PARTICLES MOVING BENEATH THE ELECTRODE/ELECTROLYTE INTERFACE TO ELUCIDATE EVOLUTION MECHANISM OF VORTEX APPEARED ON Pd SURFACE AFTER LONG-TERM EVOLUTION OF DEUTERIUM IN 0.1M LiOD
DOI No:	10.1142/9789812772985_0043
Source:	CONDENSED MATTER NUCLEAR SCIENCE (pp 411-420)
Author(s):	HIROO NUMATA Tokyo Institute of Technology, 1-12-1 O-okayama, Meguro-ku, Tokyo 152-8552, Japan MASANOBU BAN Tokyo Metropolitan Industrial Technology Research Institute, 3-13-10 Nisigaoka Kita-ku, Tokyo 115-8586, Japan
Abstract:	Long-term electrolysis for well-annealed thick Pd rod (9.0 mm ϕ) in 0.1M LiOD was performed. Microscopic observation of a postelectrolysis Pd surface showed that long-term electrolysis did not result in any cracking but surface voids, two long faults, voids arranged in a straight line and peculiar surface traces: vortex. N-cycle model was developed to explain the cold fusion reaction and the related phenomena resulting in improved reproducibility of cold fusion experiments. An important process in that model is the motion of deuterium from a vessel to other ones, which might occur the observed vortex patterns on a postelectrolysis Pd surface. However, there has been remained unsolved yet a phenomenological explanation for the process of the vortex formation. The lattice gas cellular automata method was utilized for simulating a simple 2D flow with the boundary conditions incorporating the motion of the coincidental flow of the hypothetical particles. The vortex pattern was obtained behind the obstacle, though the axis appeared along the electrode surface. However, by comparing the vortex patterns obtained by the Lattice gas cellular automata method simulation and a postelectrolysis Pd surface the vortex with the leaned axis along the electrode can only be acceptable to describe the motion of the hypothetical particles. The vortex of the massive electron appeared to be modified by Lorenz force during traveling the interface assuming a 2D circular motion.
Full Text:	View full text in PDF format (772KB)
TOC:	Back to Table of Contents
Copyright © 2012 World Scientific Publishing Co. All rights reserved.