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10 15 20 25 30 35 40 45 50 23 The reactor cores (fig.1: A, B, C1, C2, D, E) can have each — internally and between them - other conditions and/or dimensions, size and structure — such as: different local temperature, different local compression, different positioning in one or more magnetic fields, different positioning in a gravitational magnetic field, different composition of the wall different thickness (50) of the wall(s), . different regularity of the wall shape(s) (i.e. asymmetrical volume 51), different surface dimensions of the wall, separated chambers in a core (fig.1: C1 and C2), wee Heb eet ae nal p. non-spherical cores (fig1: E). So each core or its sub-chamber(s) can hold the exact conditional parameters to realize specific phases of decomposition, composition and/or recomposition for some or for all elements involved. If for a certain type of elements all parameters fit this will lead to the synthesis of the desired atomic elements and molecular San Ey Oe 2 ed i a Tn Y op ES 2 a products of high purity or specific impurity, such as H2O, conductive amino acids, etc. Thus the plasma reactor will not only provide energy but the side effects of the plasma make it possible to have the fashionable controlled creation of specific state and composition of atomic elements, molecular elements and molecules for various use, which can lead to the production of rare basic matter, the production of products with high demand, new type of materials, giving new markets and new business model(s). So such plasma reactor (fig.3, fig.4) can alter or rearrange the state, the entanglement and/or composition of introduced atomic elements, but can also alter or rearrange the state, entanglement and/or composition of introduced molecular elements. Due to processing steps, such as siphoning some elements to another core where the elements can come in contact with other elements under lower pressure and lower temperature, inside the cores involved the plasma reactor can provokes the repositioning of parts of the initial elements to one or more new preferred inter-positioning(s), this creates at least one preferred atomic and/or molecular element (i.e. H2O), different from the original(s) matter(s) or any state of matter which was initially introduced. So we claim also the method by which a plasma reactor is used as a separation and synthesis system to provokes - due to siphoning and processing steps inside the cores involved - the repositioning of parts of the introduced initial elements to new preferred inter-position(s) or rearrangement(s), thus creating at least one preferred atomic and/or molecular element, different from the original(s) matter(s) or any state of matter which was initially introduced. A special plasma reactor has a central core (fig.1:A, 27) or chamber positioned in the central area of the reactor. This chamber is encircled by at least one core (fig.2:B) that holds the plasma (11), and the chamber is fit to generate atomic elements, molecular elements and/or molecules (i.e. diamonds 30, conductive