Alkaline Fuel Cell Power Corp. announced that it has entered into a formal collaboration agreement with the University of Chemistry and Technology, Prague, one of five Czech universities which ranks within the top 4% of the world?s best universities (2017). This strategic collaboration is an important milestone on AFCP?s path to the future commercialization and distribution of its innovative Generation 3.0 (Gen 3.0) fuel cell system that will operate without generating GHG emissions. UCT Prague Strategic Collaboration: AFCP has secured a formal collaboration agreement with UCT Prague whereby AFCP is able to utilize the university?s facilities in the Company?s ongoing efforts to verify the functionality of electrodes comprised of non-precious materials within its Gen 3.0 systems. As one of the country?s large educational and research institutions in the area of chemical technologies, UCT Prague?s laboratories are equipped with high-level spectral analysis capabilities as well as other specialized equipment that AFCP would be unable to access without such a relationship. Fuel cells offer a proven solution for generating both heat and electricity, but traditionally have required expensive precious metals such as platinum to comprise the key components of the electrode, which becomes cost prohibitive for mass production. AFCP?s Gen 3.0 technology is designed to overcome this limitation and support broad adoption by both residential and commercial customers globally. Put simply, a fuel cell consists of two electrodes - a negative electrode (also called an anode) and a positive electrode (also called a cathode) - which both encase an electrolyte. When a fuel such as hydrogen is fed to the anode, and air is fed to the cathode, a reaction occurs and electrons pass through an external circuit that creates a flow of electricity. The protons migrate through the electrolyte to the cathode, where they combine with oxygen and the electrons, producing clean water and heat.