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10 15 20 25 30 35 40 45 50 13 larger degree hazardous for humans, animals and plants. In such cases a concrete covering is a good protection. The totality will then be put underground, and only the wires — which can be graphene type as disclosed below — will come out of the ground and will go to the user system(s). Further we claim the method and the chemo-nuclear, bio-nuclear and/or bio- chemo-nuclear process to decay and recombine in (temperature independent way) specific elements of the periodic table and their isotopes, where - before the start of the processing - at least two different composed initial material(s) are inserted/taken-in by insertion means at different locations (cavities) of a TIPI- reactor, where in one or in each location specific preferred chemical processes will occur which lead to “a number of new atomic and molecular elements of the periodic table and their isotopes which did not existed in the initial state in the environment or which were not present in these quantities”, as described in claim 1 and 2, i.e. in one location the creation of plasma and liquid helium, and in another location the creation of liquid metal, where then - in the next step - portions or the totality of the content of these different cavities can be brought together by transported means for further preferred steps of processing, either in new location(s), either in one of the already used locations, either in all already used locations. (Fig 28). For more complex production processes it may be important to process first a number of basic materials, like atomic hydrogen in liquid state. That can happen in a separate reactor, but can also happen in one of the separated cavities of the reactor, for example using the same nuclear source. A reactor could, for example, have six separate cavities which surround one nuclear source, where the radiation can be less strong in some of these cavities. When designing our reactors we can take such concept in mind. The content of these cavities — after the initial processing — can then be combined as a whole in the head cavity, and be combine again in sequential steps. Another method and the chemo-nuclear process is claimed to create in a TIPI- reactor at least one radioactive isotope, as being part of “a number of new atomic and molecular elements of the periodic table and their isotopes which did not existed in the initial state in the environment or which were not present in these quantities”, as described in claim 1 and 2, like the isotopes: °T, ‘Be, “C, “°K, Vv, 87Rb, Te, 138 a 142Ce@ “4nd, “45nd, 47Sm, 148Sm, 148Sm, 182Gq, 86Dy, 176) u, abe 89T a, 87Re, 18Os, Pt, 2098, 215At AS explained above the programmed creation of radioactive isotopes is part of the methods to generate certain type of self-sustaining processes in our chemo-nuclear, bio-nuclear and bio-chemical nuclear reactors. In claim 17 is explained the way beta-decay of “°K is a trigger to create scintillation, then EUV, leading to ionization, leading to plasma. Thus, if we want to have into a liquid intermediate — short living — “new” nuclear sources which will add additional nuclear radiation in the mixture to process locally supporting nuclear reactions, we need to include in the initial liquid or add to that mixture at the appropriate moment materials which lead in conjunction with the original nuclear sources to reactions which transform atoms and/or molecules to Annee enna anthen inn tanan Further we claim the method to process in a first stage a pure atomic metal (matter) by exposure an alkali metal containing molecule (i.e. K) to a radioactive source in a acid environment, in a second step collect (i.e. filter) said pure atomic matter, and then in a third stage add said pure atomic metal to a liquid with other become radioactive isotopes.