SBIR-STTR Award

Currently, there is a great interest in generating intense EUV-x-ray beams in military and commercial sectors, because their applications are anticipated to be potentially crucial to maintaining the global leadership of the US military and industry. Specific military applications of such intense EUV-x-ray beams include countering a wide range of WMDs. The chief barrier to realizing these applications is that the generation of EUV-x-ray beams with traditional technologies is highly energy inefficient, costly, bulky and technologically challenging. We propose to demonstrate the feasibility of developing highly energy-efficient super-intense compact EUV-x-ray generators that can overcome the barrier, thus can be mass produced and commercialized. The technological basis of the proposed generators is on the newly discovered quantum state, Metastable Innershell Molecular State (MIMS) in Warm Dense Matter (WDM). WDM is a class of ?stellar? matters with low electron temperatures, which can permit abundant quantum mechanical states, such as MIMS that has excitation energy orders of magnitude larger than that of common chemical quantum states. In addition to technological feasibility demonstration, during Phase I, we plan to perform market studies, to establish their potential customers, and to start contacting private investors for acquiring matching fund for expanding Phase II into Phase III.

Keywords:
Euv, X-Ray, Generators, Wmd, Metastable Innershell Molecular State, Mims, Warm Dense Matter, Wdm

The primary goal of the preceding Phase I program was to demonstrate the feasibility of developing commercially viable products from our technological innovation that enables unprecedentedly high energy efficiency generation of super-intense EUV-x-ray beams via Metastable Innershell Molecular State. We have successfully met the Phase I goal by demonstrating the feasibility, and are now ready for fabricating and testing the Phase II prototype generators that will play vital roles in convincing private investors for equity investment, and in fabricating mass-produced Phase III commercial product generators. Based on the Phase I success, two classes of prototype/premarket products will be built: 1) Explosive Driven EUV-x-ray Generators for generating pulsed high energy (photon pulse energy > 1 kJ) EUV-soft-x-ray beams in partnership with Los Alamos National Lab, and 2) Accelerator Driven EUV-x-ray Generators for generating super-intense (photon flux power > 100 W) CW EUV-soft-x-ray beams. Based on the contact with private investors, with our prototypes in hand during Phase II, we will be able to secure Series A investment via private placement for expediting commercialization and licensing deal. In addition, during Phase II we will design marketable generators for continuing into Phase III, which will enable us to secure Series B investment.