Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter

In one of our previous papers, it was shown that for the ground state of hydrogenic atoms/ions, it is possible to match the interior (inside the nucleus) solution of the Dirac equation with the singular exterior solution of the Dirac equation, so that the singular solution should not be rejected for...

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Main Author: Eugene Oks
Format: Article
Language:English
Published: MDPI AG 2020-07-01
Series:Atoms
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Online Access:https://www.mdpi.com/2218-2004/8/3/33
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spelling doaj-6db18243ff7c4ddd94e711b6e8f440d72020-11-25T03:13:11ZengMDPI AGAtoms2218-20042020-07-018333310.3390/atoms8030033Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark MatterEugene Oks0Physics Department, Auburn University, 380 Duncan Drive, Auburn, AL 36849, USAIn one of our previous papers, it was shown that for the ground state of hydrogenic atoms/ions, it is possible to match the interior (inside the nucleus) solution of the Dirac equation with the singular exterior solution of the Dirac equation, so that the singular solution should not be rejected for the ground state of hydrogenic atoms/ions. In that paper, there was presented also the first experimental proof of the existence of this Alternative Kind of Hydrogen Atoms (AKHA)—by showing that the presence of the AKHA solves a long-standing mystery of the huge discrepancy between the experimental and previous theoretical results concerning the high-energy tail of the linear momentum distribution in the ground state of hydrogen atoms. In another paper, we showed that for hydrogen atoms, the singular solution of the Dirac equation outside the proton is legitimate not just for the ground state 1<sup>2</sup>S<sub>1/2</sub>, but also for the states 2<sup>2</sup>S<sub>1/2</sub>, 3<sup>2</sup>S<sub>1/2</sub> and so on: it is legitimate for all the discrete states n<sup>2</sup>S<sub>1/2</sub>. Moreover, the singular exterior solution is legitimate also for the l = 0 states of the continuous spectrum. In that paper, we demonstrated that the AKHA can be the basis for explaining the recent puzzling astrophysical observational results concerning the redshifted radio line 21 cm from the early Universe. Thus, there seems to be the astrophysical evidence of the existence of the AKHA—in addition to the already available observational proof of their existence from atomic experiments. In the present paper, we point out that the AKHA provide an alternative view on dark matter—without resorting to new subatomic particles or dramatically changing the existing physical laws. This is because due to the selection rules, the AKHA do not have state that can be coupled by the electric dipole radiation. We also reformulate the above theoretical results in terms that hydrogen atoms can have two flavors: one flavor corresponding to the regular solution outside the proton, another—to the singular solution outside the proton, both solutions corresponding to the same energy. Since this means the additional degeneracy, then according to the fundamental theorem of quantum mechanics, there should be an additional conserved quantity, which we call isohydrogen spin (isohyspin). Further atomic experiments for accurately measuring the high-energy tail of the linear momentum distribution in the ground state of hydrogen atoms, as well as further observational studies of the redshifted 21 cm radio line from the early Universe, could provide a further proof that dark matter or a part of it is the AKHA.https://www.mdpi.com/2218-2004/8/3/33alternative kind of hydrogen atomstwo flavors of hydrogen atomsnew symmetry of hydrogen atomsexplanation of the dark matterexplanation of the puzzle of 21 cm radio lineearly Universe
collection DOAJ
language English
format Article
sources DOAJ
author Eugene Oks
spellingShingle Eugene Oks
Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter
Atoms
alternative kind of hydrogen atoms
two flavors of hydrogen atoms
new symmetry of hydrogen atoms
explanation of the dark matter
explanation of the puzzle of 21 cm radio line
early Universe
author_facet Eugene Oks
author_sort Eugene Oks
title Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter
title_short Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter
title_full Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter
title_fullStr Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter
title_full_unstemmed Two Flavors of Hydrogen Atoms: A Possible Explanation of Dark Matter
title_sort two flavors of hydrogen atoms: a possible explanation of dark matter
publisher MDPI AG
series Atoms
issn 2218-2004
publishDate 2020-07-01
description In one of our previous papers, it was shown that for the ground state of hydrogenic atoms/ions, it is possible to match the interior (inside the nucleus) solution of the Dirac equation with the singular exterior solution of the Dirac equation, so that the singular solution should not be rejected for the ground state of hydrogenic atoms/ions. In that paper, there was presented also the first experimental proof of the existence of this Alternative Kind of Hydrogen Atoms (AKHA)—by showing that the presence of the AKHA solves a long-standing mystery of the huge discrepancy between the experimental and previous theoretical results concerning the high-energy tail of the linear momentum distribution in the ground state of hydrogen atoms. In another paper, we showed that for hydrogen atoms, the singular solution of the Dirac equation outside the proton is legitimate not just for the ground state 1<sup>2</sup>S<sub>1/2</sub>, but also for the states 2<sup>2</sup>S<sub>1/2</sub>, 3<sup>2</sup>S<sub>1/2</sub> and so on: it is legitimate for all the discrete states n<sup>2</sup>S<sub>1/2</sub>. Moreover, the singular exterior solution is legitimate also for the l = 0 states of the continuous spectrum. In that paper, we demonstrated that the AKHA can be the basis for explaining the recent puzzling astrophysical observational results concerning the redshifted radio line 21 cm from the early Universe. Thus, there seems to be the astrophysical evidence of the existence of the AKHA—in addition to the already available observational proof of their existence from atomic experiments. In the present paper, we point out that the AKHA provide an alternative view on dark matter—without resorting to new subatomic particles or dramatically changing the existing physical laws. This is because due to the selection rules, the AKHA do not have state that can be coupled by the electric dipole radiation. We also reformulate the above theoretical results in terms that hydrogen atoms can have two flavors: one flavor corresponding to the regular solution outside the proton, another—to the singular solution outside the proton, both solutions corresponding to the same energy. Since this means the additional degeneracy, then according to the fundamental theorem of quantum mechanics, there should be an additional conserved quantity, which we call isohydrogen spin (isohyspin). Further atomic experiments for accurately measuring the high-energy tail of the linear momentum distribution in the ground state of hydrogen atoms, as well as further observational studies of the redshifted 21 cm radio line from the early Universe, could provide a further proof that dark matter or a part of it is the AKHA.
topic alternative kind of hydrogen atoms
two flavors of hydrogen atoms
new symmetry of hydrogen atoms
explanation of the dark matter
explanation of the puzzle of 21 cm radio line
early Universe
url https://www.mdpi.com/2218-2004/8/3/33
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