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10 15 20 25 30 35 40 45 50 55 87 130. Method (Fig. 18 and 19) to build an electronic component like a micro- chips (190), an integrated circuits (160), a transistor, a capacitor, a diode, a triode, etc., where a surface of said electronic component (190) is connected (i.e. glued) with at least a surface of one chemo-nuclear (170, 181), bio-nuclear and/or bio-chemical plasma reactor (162) which is a reactor, as described in claim 1 or 2, and where inside channels (172), chambers (173, 177, 179) in one or more layers (171A, 171B, 171C) - made by mould-injection, by photographic means, by printing technology, by etching chemically, by engraving, by laser or by similar processes — contain and transport liquids (125), gasses and plasma, and currents, where these current(s) may be picked up by one or more terminals (178, 179) to be delivered to at least one electronic (191, 192, 193, 194, 195, 196) part of said electronic component; 131. Electronic component, as described in claim 124, 129, 130, in which initial materials and additional material(s), as described in claim 1 and 14, can be inserted or where produced material(s) been redraw through opening/closure means (174), like gates; 132. Method to build a cooled electronic component like a micro-chips (200), an integrated circuit (160), a transistor, a capacitor, a diode, a triode, etc., where a surface or an inside part of said electronic component (190) is equipped with at least one cooling element (201) powered by at least one chemo-nuclear (170, 181), bio-nuclear and/or bio-chemical plasma reactor (162) which is a reactor, as described in claim 1 or 2; 133. Method to build electronic components like a micro-chip (200), integrated circuit (160), a transistor, a capacitor, a diode, a triode, etc., in which at least one layer of atomic carbon (graphene), created by the method as described in claim 134 (142), having superconductivity or even ballistic conduction properties i.e. at room temperature — created in at least one cavity of at least one chemo-nuclear, bio-nuclear and/or bio-chemical plasma reactor, a reactor, as described in claim 1 or 2; 134. Method to position magnets in or around a reactor, as described in claim 1 and 2, in a specific way that the (provoked) magnetic fields behave as dilution solution (where as in systems like Tokomak they us the magnetic fields to compress the plasma), that with this method the binding of the atoms is loosen up rather than being enforced, this being needed for the initial provocation of a dynamic passive magnetic eanatae reactor; 135. Method to create magnetic fields at the atomic and molecular level — and not electro-magnetic fields as in solid magnets, the atomic and molecular magnetic fields will behave as a dilution in opening up and loosening the atomic and molecular binding forces within the atoms and molecules within it’s field; 136. Method to clean exhaust gasses from combust motors (i.e. cars), heating systems (I.e. central heating), and various industrial processes, (185, 176, 175, 186) part of said electronic component;