DD from the 10-QSB in Dec :Has a few extra techs I like : Technology Development Areas:
Nuclear Micro-Batteries
This program is aimed at developing embeddable nuclear micro-batteries that can supply long-lasting power for computer chips, micromotors, remote sensors, implantable medical devices, and other defense and aerospace applications. This technology is also known as nuclear micro power generation or RIMS (radio isotope micro power sources).
Tritiated Water Remediation (TWR)
Our TWR program is aimed at the development of a technology for the remediation of tritium contaminated water. The target markets are U.S. government and the nuclear power industry
Nuclear Material Detection
We have initiated a program to develop specialized sensors to detect, identify and localize special nuclear materials. The target market is homeland security.
Laser Nano-Machining System:
The Laser nano-machining technology focuses on system integration and marketing of a laser machining system capable of machining features in the nanometer range. The target markets are companies requiring manufacture of specialized micro-machined components.
Gamma Laser System-photonuclear transmutation
This technology is focused on the development of a high-intensity gamma laser as the driving element of a photonuclear transmutation reactor. The target market for this technology would be the nuclear waste remediation industry.
The company's plan of operation for the next twelve months is to raise additional money, continue to identify, evaluate, research, screen, and develop innovative nuclear technologies as resources allow. Some of the technologies we evaluate originate through our own efforts and others are acquired from outside researchers and institutions. We have limited cash available for operations. Management favors assigning most of the company resources towards technologies which have the potential for revenue generation in three years or fewer. From time-to-time, in the interest of diversity, the company will evaluate certain non-nuclear technologies that relate to its main areas of interest.
The criteria used in the selection of technologies is based on evaluating the commercial potential of a technological idea and assessing the additional research and development investment required to bring it to a point where it may be commercially exploited within three years(near-term commercialization).
The company mainly assigns resources to technologies that meet our near-term commercialization benchmarks. Selected technologies that do not meet our short-term criteria are allocated resources as determined by management and will be developed as long-term projects. Projects that management believes will take longer than five years to reach the point of commercial readiness are considered long-term projects.
All technologies selected by the company will be developed as compartmentalized projects.
The company intends to generate revenues from joint-ventures, licensing fees, or sales of individual technologies. As one example, license arrangement employing TWR technology to treat stockpiles of nuclear wastewater may consist of partnering with an environmental remediation firm that would acquire a technology license to employ our proprietary process. The licensee would be responsible for equipment manufacturing, end-user marketing, and operation. Revenue for the company would be generated as a function of the revenues generated by the licensee. Other examples would be: revenue realized for others to incorporate, operate, manufacture, or sell our technology. We may also realize revenue from the outright sale of any technologies we are developing.
In February, 2003, the company opened a business development office in Moscow. The Moscow office is staffed by our Director of Russian business development. The Russian office is responsible for identifying licensable technologies and to secure additional research capacity in within the Russian academic and scientific establishment as the need arises. The main goal of the Moscow office is to contract with qualified research facilities assess and additional business opportunities through the Russian scientific and technical infrastructure. ..//..”” http://knobias.10kwizard.com/filing.php?repo=tenk&ipage=2438930&doc=1&total=&back=2&.... Chucka PS DD extra I did yesterday and before: a picture is worth a thousand words. And a journey of a thousand miles begines with one small step: http://www.siliconinvestor.com/ http://www.siliconinvestor.com/stocktalk/msg.gsp?msgid=19728573 Maybe a picture is better than words to explain NSOL NON SHELVED TECH one on the few :Insert NANO LASERIMG from 10-qsb http://focus.hut.fi/annrep/1996/node24.html "" This has led to the need for studying mirrors that are able to reflect neutral particles. Our interests include studies of electromagnetic mirrors for atoms, consisting of largely detuned strong-field evanescent waves on the surface of a dielectric. In particular, we have considered phenomena related to the use of short laser pulses for the reflection of atoms. Theoretical studies of the dynamics of particles reflected by a short-pulse laser field have been carried out, showing the possibility of slowing down particles in a thermal beam through non-specular reflection. Due to the absence of spontaneous emission, such techniques may be useful for the manipulation of multilevel atoms and molecules. In addition to the theoretical simulations, reflection of sodium atoms from a pulsed atom mirror has also been studied experimentally. The experimental setup, shown in Figure 5.1, includes a pulsed dye laser, a single-mode frequency stabilized dye laser for fluorescence probing and a collimated atomic beam. The anti-nodes of a standing wave laser field, formed by the pulsed dye laser, are used as atom mirrors. In this geometry, atoms are deflected from the beam because of the induced dipole forces ""and ESPECIALLY "".. Nano-optics (P. Ryytty, M. Kaivola and C.G. Aminoff)
The use of optical near-fields to study material surfaces is the most recent arrival in the class of scanning probe microscopies. The goal of Scanning Near-field Optical Microscopy (SNOM) is to push the resolution of optical imaging beyond the diffraction limit which dictates the fundamental resolution of classical optical microscopes. In the SNOM this is achieved by confining the optical field to a volume smaller than the wavelength of light and by measuring its interaction with the material surface. In practice this is accomplished by scanning a nanoaperture in close proximity to the sample surface. The topographic and optical properties of the sample can then be determined by measuring the optical intensity tunneled through the aperture. In this way, lateral resolution well beyond the diffraction limit can be achieved.
Compared to other scanning probe techniques the use of optical interaction provides some clear advantages ..//.."" I saw that movie on DVD THE CORE ...far fetched EM ...so is the laser tech and the atom ..just a way to think I guess...may not be related... Chucka ( Old BOOKMARKS never die they just fade away LOLaughts ) and on lasers and scans ...it must ALL BE DONE WITH MIRRORS! Right!