The manifestations of all elements, including those of hydrogen and helium, are based upon patterns of expression of various and diverse centripetal and centrifugal forces and attraction and repulsion among these forces. After spin develops, spins may, in turn enter into complex patterns of spinning nuclei within a complex pattern of rotatinmg atoms. All of these patters are derived from what is inherent in the synchronous two-way flow from the macrocosm to the microcosm and from the microcosm to the macrocosm. From these interrelatioships the periodic table of the elements would be derivable. In discussing the Enfolding Universe, we set forth the derivation of the hydrogen and helium molecules in oder to give the reader an udea of the processes involved in the formation of elements.

Hydrogen is discussed since it is the first element on the periodic table as well as a non-radioactive element with strong and effective binding together of its centripetal and centrifugal components and of the attraction and repulson between these components. Helium is set forth as a good example of how weak and ineffective biding together of centripetal and centrifugal forces lead to radioactive elements, such as Helium.

Helium is a result of the weak binding together of parts of the deuterium nuclei that have both parallel and antiparallel spins and that merge together in an highly unstabke union. Unlike hydrogen that has a diatomic molecule, helium has a monatonic molecule. Its nucleus spins, but its spin that results from a merger of parallel and antiparallel spins can decay, making helium radioactive.

Its spin interestingly is not apparently based the the spinning nucleus of diatomic hydrogen but based upon the very rare situation when the atoms of hydrogen do develop a spin. Ordinarily the nuclei of hydrogen atoms do not spin but only the nuclei of the hydrogen diatomuc molecule spin. However, after the union of outonic and intonic hydrogen atoms have given rise to the hydrogen molecule, the molecular binding together in its nucleus of outonic and intonic inner cores may dissassocate but the diassociated inner cores continue to spin in what is now atomic and not molecular hydrogen. Since the spins of molecular hydrogen may be in either parallel or antiparallet directions, the now spinning nuclei in atomic hydrogen may be in either pasrallel or antiparallel directions. It apparently is the repulsion between spins that may cause the diassociation when molecules with spins in either parallel or antiparallel directions collide with molecules with spins of like kind.

The spin in molecular hydrogen originated in the first place because of attraction between rotating hydrogen atoms that have inner and outer cores of unlike kind. After the disassociation, the attraction remains. Thereafter, these hydrogen atoms with spinning nuclei then join together to form heavy hydrogen or deuterium. Thereafter deuterium molecules with parallel spin enter into an unstable relationship with deuterium molecules with antiparallel spins, resulting in the monatomic molecule of helium being radioactive and subject to decay. Its radioactivity is a part of helium`s being a result of a very weak balance between attractive and repulsive forces.

Helium is an radioactive element and differs from the radioactive isotope of hydrogen. The radioactive isotope of hydrogen, tritium, results from a binding together of deuterium and protium molecules. Tritium nuclei have an unstable spin, leading to its radioactivity and a tendency for some tritium nuclei to lose their spins by disassociation of the atoms comprising molecular hydrogen. Hydrogen atoms do not ordinarily have a spinning nuclei, but helium atoms do have spinning nuclei that is based upon the rare situation when atomic hydrogen has spinning nuclei.

° Wilson Ogg