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Microcap & Penny Stocks : RDOX Battery Technology -- Ignore unavailable to you. Want to Upgrade?

To: s.smith who wrote (285)	3/12/1998 4:14:00 PM
From: Manx	Read Replies (1) \| Respond to of 1983

I do not know if this is good or bad but it seems that the Clark University received the relevant patent in question (5571600) for an invention by Stuart Licht who now lives in Israel. I am sure that he knows more about the potential (or lack of potential) of this type of product than an average investor. I am wondering, if he is inventing/improving similar things now. See also: technion.ac.il technion.ac.il for email, his research interest, etc; for example, see: "Stuart Licht: Research Interests Electrochemical storage (primary and secondary batteries). Facile and lightweigt electrochemistry is explored to promote energetic high capacity storage resulting in a variety of new batteries including those incorporating a solid sulfur cathode, and aluminum batteries including ferricyanide, permanganate, sulfur, nickel oxide or hydrogen peroxide cathodes. The fundamental electrochemistry of these unusual storage cells is studied in a wide range of media. Photoelectrochemistry (light induced electron transfer at semiconductor/ and dye/ solution interface). Significant applications of photoelectrochemistry can be for the efficient conversion of solar energy to electrical energy and also for the investigation of photoassisted chemical reactions, preparation of semiconductor materials, sensing and for environmental detoxification. Solid state, interfacial and solution phase effects on fundamental photoelectrochemical phenomena are explored. Environmental Analysis. This goal of this research is to provide new analytical methodologies and new environmental sensors. The research explores both the minimum limits of molecular detection, or the opposite, the compositional analysis of super-concentrated electrolytes such as industrial and toxic waste. Sensing techniques and methodologies are developed from a range of fundamental physical chemical properties including electrolyte density, solvent activity, photoelectrochemical behavior, conductance and amperometric and potentiometric characterization. These techniques can be utilized to analyze a variety of materials including mercury, sulfur and cyanide or ultra pure water. Electrochemistry of aqueous and molten electrolytes including the thermodynamics, speciation and chemical and redox kinetics of sulfur, polysulfide and metal sulfide chemistry; aluminate, iron oxide, ferri/ferrocyanide and polyiodide chemistry. "