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PTL
About this journal

Physics Tomorrow Theoretical Physics Letters (TPL) An SCI-indexed monthly thrice peer-reviewed journal.

 

Physics Tomorrow Theoretical Physics Letters TPL is an international thrice reviewed journal which publishes the novel research and review articles on every dimension of the physics. The current impact factor is 4.16 as per the 2024 update.

physical review a, applied physics letters.

Indexing

Indexed within Scopus, SCIE (Web of Science), CAPlus / SciFinder, Inspec, and many other databases.

Open access

Free for readers, with article processing charges (APC) paid by authors or their institutions.

Table of Contents
For authors

Rapid publication

Manuscripts are peer-reviewed and a first decision provided to authors approximately 21 days after submission; acceptance to publication is undertaken in 8-10 days post first decision.

Recognization

Reviewers who provide timely, thorough peer-review reports receive vouchers entitling them to a discount on the APC of their next publication in any Physics Tomorrow Letters, in appreciation of the work done.

Formatting manuscript

Impact Factor

3.56 (2022) ; 7-Year Impact Factor: 4.16 (2024 running month)

Journal Flyer

Flyer.pdf
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Word of the editor. |

 

Theoretical Physics Letters (TPL) An SCI & SCOPUS -indexed monthly thrice peer-reviewed journal. TPL is an partial open access international journal which covers the recent trends in theoretical, experimental and observational physics. This aims to provide a great opportunity to the lead researchers worldwide for publishing their valuable works at a minimum honorarium. Because I believe that great ideas are priceless. TPL journal is an international, peer-reviewed, partial open-access journal on theoretical, applied physics, science and its applications published monthly online by Physics Tomorrow Letters.

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3.86
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The Nature of the 1 MeV-Gamma quantum in a Classic Interpretation of the Quantum Potential

By considering wave-particle dualism with an interpretation of the squared amplitude of the wave function R2(Y) compatible with the known Bohm’s equations, for a 1 MeV-gamma-quantum considered as ‘gammonic’ (e-e+)- pair of electrons having the phase speed of the associated wave equal to the group speed of passing through a low frictional component of the quantum vacuum, it results a value of the quantum potential Q equal to the particle’s kinetic energy, Qc = ½mv2 , for a classic model of electron composed by heavy photons, this value being explained by a generalized relation of quantum equilibrium of de Broglie type, with the associated entropy proportional to its action S, as representing a centrifugal potential given by a spinorial mass ms = nvmv » me resulting by nv -vector photons explaining also a half of the electron’s rest energy by considering and a dynamic component of the quantum vacuum- given by quantum and sub-quantum winds ............
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Dirac-Majorana neutrino type conversion induced by an oscillating scalar dark matter

Some properties of a neutrino may differ significantly depending on whether it is Dirac or Majorana type. The type is determined by the relative size of Dirac and Majorana masses, which may vary if they arise from an oscillating scalar dark matter.
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Calculation of the Hubble Constant, the Minimum Mass, and the Proton Charge Radius Using the Dirac’s Hypothesis on the Ratio of the Electrostatic Force to the Gravitational Force

This publication suggests that some physical values could be calculated using the Dirac’s hypothesis on the observed ratio of the electrostatic force to the gravitational force. The calculated value of the Hubble constant is H ≈ 72.013 km s‑1 Mpc‑1 and that of the minimum mass, Mmin ≈ 1.720 6 × 10‑68 kg. Recent observations suggest that the proton charge radius could also be calculated using an additional but related assumption: rp ≈ 0.826 4 fm.

38

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Total submitted and accepted manuscript ratio in current month.

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