Abstract
In this article, we compute energy of fractional conformable derivative of normalization function and Fermi-Walker fractional derivatives of pseudo-hyperbolic magnetic curves on the \({\mathbb {H}}_{0}^{2}\) associated with Minkowski 3-space. Primarily, we obtain conformable derivatives for pseudo-hyperbolic magnetic \(\Omega \left( \delta \right) ,\) \( \Omega \left( {\textbf{t}}\right) ,\) \(\Omega \left( {\textbf{n}}\right) \) vector fields. Furthermore, we obtain F–W conformable derivatives for recursion and normalization functions. Also, we present some characterizations for Lorentz fields connected with pseudo-hyperbolic conformable corpuscle. Lastly, we get energy of fractional conformable derivative of normalization function for \(\Omega \left( \delta \right) ,\) \(\Omega \left( {\textbf{t}}\right) ,\) \( \Omega \left( {\textbf{n}}\right) \) vector fields of vector fields connected by a hyperbolic framework in p-hyperbolic space \({\mathbb {H}}_{0}^{2}\).
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Körpinar, T., Körpinar, Z. & Özdemir, H. Optical conformable normalization energy of hyperbolic magnetic curves. Opt Quant Electron 55, 1233 (2023). https://doi.org/10.1007/s11082-023-05342-2
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DOI: https://doi.org/10.1007/s11082-023-05342-2