The next steps involved engineering design to develop a commercial prototype, and optimization of supporting systems. The most challenging practical problem was designing an electrode that could withstand the high temperatures. This was solved by making the electrode entirely liquid, an arcing molten metallic silver electrode with a continuous feed, into which the catalyst was mixed, which enabled a continuous plasma reaction. The reaction took place in a small containment vessel, with the two feeder systems, one for the liquid silver, the other for moving the atomic oxygen and hydrogen in and hydrinos out. The plasma is maintained at 4000C and generated very high energy photonic radiation in the Extreme Ultra Violet frequency range (EUV), producing excess heat and molecular signatures confirming Hydrino profiles. Supporting systems were engineered for hydrolysis of the water, for induction pumping the silver, for heat transfer systems, and for electrical offtake.

Mitek 20 20 Engineering Cracker

6/14/19 is the most recent update in a Business Presentation pdf. However, the material merely refined prior messaging, with some updates of prototyping and engineering solutions of SunCell system components, some new validation experiments conducted by independent scientists, and another review of 17 out of the 29 methods for verification of the Hydrino explanation. However, there were no further updates from ColumbiaTech, Spectrolab or Masimo, TMI Climate Solutions, or any other development partner about component status or overall system fabrication design status. 2ff7e9595c