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10 15 20 25 30 35 40 45 18 outcome. Thus both reactors have the same basic processing, but when one or more devices or sources in the later are activated then the effects A special method and configuration design (Fig. 23) to create a double magnetic field (233, 234) may be where at least two reactors (230, 231), as described in claim 1, 2, 43 and/or claim 44, are in magnetically interaction distance with each other or are brought together by mechanical and structural means, to create joined or interacting magnetic fields, in example a smaller cylinder entering into a larger hollow cylinder. Such reactor are preferrable equipped with magnets (232). The Method is described here to rotate the core by external means or create conditions to rotate by it’s own through the method 43 through the method to create or assist to enhance or reduce created magnetic field weMhin ha wade hie th AA Now we describe plasma reactors which are more complex. Such plasma reactors (10A) are located in an embodiment (10B) in which a rotational plasmatic state (11) is initiated by a scintillation process of one or more gasses (i.e. hydrogen 17) or other matter states - in such a way that at least three physical phenomena are provoked inside at least one core (fig.1:B) of the reactor, namely: compression, heat and one magnetic field (22A, 22B) - leading in first instance to the production of energy -, and the reactor is equipped with at least: a Co rns Pe |e 2 0 alee nt one solid separation wall (12A) or a _ dynamic separation/transitions layer which can be composed by any state of matter - i.e. a layer formed by liquid plasma, metallic material vapor (i.e. K, Na, Ca, Mg), liquid metallic element layer gas, molecular matter, solid matter and/or by electromagnetic fields - in the reactor cavity, and at least one transportation means (i.e. channels 13A, 74) doors 72A, ports 13B, mouths, valves 13C, slides 13E, pumps, open/closing system, gates, etc.) that can be located everywhere in the reactor (i.e. in a central column 14, in a separation wall 13D and 25, or in the reactor embodiment 10B) and/or connected with the reactor, i. to transport relevant elements (i.e. hydrogen gas 17 to core B in fig. 1 and fig 2) from outside to the inside of the appropriate core(s) of the reactor; ii. to transport plasma (11), atomic and/or molecular elements from one inside cavity (20) or core to one or more other internal cavities (21, 19A and 19B) or cores for the purpose to change compositional properties of such elements (26) by _ the environmental conditions (i.e. gravitational, wall dynamic manna be. a. one or properties of : environmental the (i.e. conditions may be stronger. within the matter within the embodiment.