scholarly journals The Quantum Condition That Should Have Been Assumed by Bohr When Deriving the Energy Levels of a Hydrogen Atom

2021 ◽  
Vol 09 (06) ◽  
pp. 1230-1244
Author(s):  
Koshun Suto
Keyword(s):  
Hydrogen Atom ◽  
Energy Levels ◽  
Quantum Condition

Two Types of Space in the Hydrogen Atom not Predictable with Quantum Mechanics

2021 ◽  
Vol 8 (2) ◽  
pp. 326-339
Author(s):  
Koshun Suto
Keyword(s):  
Quantum Mechanics ◽  
Hydrogen Atom ◽  
Energy Levels ◽  
Low Energy ◽  
Electron Mass ◽  
Positive Mass ◽  
Negative Mass ◽  
True Nature ◽  
The Relationship ◽  
Quantum Condition

Einstein’s energy-momentum relationship is not applicable to the electron in a hydrogen atom. Therefore, the author has previously derived an energy-momentum relationship applicable to the electron inside the hydrogen atom where potential energy exists. However, the initially-derived relationship did not incorporate the discontinuities in energy which are characteristic of quantum mechanics. Therefore, the author derived a new quantum condition to take the place of Bohr’s quantum condition, i.e., , and that was used to incorporate discontinuity into the relationship derived by the author. When that relationship is solved, it is evident that, in addition to the existing energy levels, there are also ultra-low energy levels where the electron mass becomes negative. A previously unknown state of the hydrogen atom exists, formed from an electron with negative mass and a proton with positive mass. The electron with negative mass exists near the proton. The author predicts that this unknown matter is the true nature of dark matter, an unknown source of gravity whose true nature is currently unknown.

Effect of Finite Proton Size Effect on the Energy Levels of the Hydrogen Atom

2011 ◽  
Vol 61 (11) ◽  
pp. 1030
Author(s):  
Jin Ok Kim ◽  
Ho Meoyng Choi ◽  
Se Gi Yu
Keyword(s):  
Hydrogen Atom ◽  
Size Effect ◽  
Energy Levels

scholarly journals The stark effect of the fine-structure of hydrogen

1928 ◽  
Vol 119 (782) ◽  
pp. 313-334 ◽  
Keyword(s):  
Fine Structure ◽  
Hydrogen Atom ◽  
Electric Field ◽  
Quantum Dynamics ◽  
Stark Effect ◽  
Energy Levels ◽  
Structure Theory ◽  
Weak Electric Field ◽  
Classical Dynamics ◽  
Balmer Series

One of the earliest successes of classical quantum dynamics in a field where ordinary methods had proved inadequate was the solution, by Schwarzschild and Epstein, of the problem of the hydrogen atom in an electric field. It was shown by them that under the influence of the electric field each of the energy levels in which the unperturbed atom can exist on Bohr’s original theory breaks up into a number of equidistant levels whose separation is proportional to the strength of the field. Consequently, each of the Balmer lines splits into a number of components with separations which are integral multiples of the smallest separation. The substitution of the dynamics of special relativity for classical dynamics in the problem of the unperturbed hydrogen atom led Sommerfeld to his well-known theory of the fine-structure of the levels; thus, in the absence of external fields, the state n = 1 ( n = 2 in the old notation) is found to consist of two levels very close together, and n = 2 of three, so that the line H α of the Balmer series, which arises from a transition between these states, has six fine-structure components, of which three, however, are found to have zero intensity. The theory of the Stark effect given by Schwarzschild and Epstein is adequate provided that the electric separation is so much larger than the fine-structure separation of the unperturbed levels that the latter may be regarded as single; but in weak fields, when this is no longer so, a supplementary investigation becomes necessary. This was carried out by Kramers, who showed, on the basis of Sommerfeld’s original fine-structure theory, that the first effect of a weak electric field is to split each fine-structure level into several, the separation being in all cases proportional to the square of the field so long as this is small. When the field is so large that the fine-structure is negligible in comparison with the electric separation, the latter becomes proportional to the first power of the field, in agreement with Schwarzschild and Epstein. The behaviour of a line arising from a transition between two quantum states will be similar; each of the fine-structure components will first be split into several, with a separation proportional to the square of the field; as the field increases the separations increase, and the components begin to perturb each other in a way which leads ultimately to the ordinary Stark effect.

Exact solution of the non-Hermitian eigenvalue problem for electron orbital excitations in a hydrogen atom

2020 ◽  
Author(s):  
Andrey V. Popov
Keyword(s):  
Hydrogen Atom ◽  
Eigenvalue Problem ◽  
Spectral Problem ◽  
Energy Levels ◽  
Stark Shift ◽  
Electronic Excitations ◽  
Angular Momentum Operator ◽  
Complex Energy ◽  
Electron Orbital ◽  
Atomic Energy Levels

A new way of solving the spectral problem for description of electronic excitations is demonstrated for a hydrogen atom. The applied methodology is based on the idea of the electronic excitations description without introducing boundary conditions to the eigenvalue problem for the square of the angular momentum operator. The eigenvalues of such an operator are considered as complex in general. As a result, the spectral problem for the Schrödinger equation becomes non-Hermitian with complex energy values. The imaginary part of the total energy helps to estimate the excitation lifetime within a unified scheme. The existence of the Stark shift of atomic energy levels and the collapse of the atomic spectra are confirmed.

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