Mathematical Physics II

Edited by
December 2020
182 pages
  • ISBN978-3-03943-495-4 (Hardback)
  • ISBN978-3-03943-496-1 (PDF)

This book is a reprint of the Special Issue Mathematical Physics II that was published in

Computer Science & Mathematics
Physical Sciences
Public Health & Healthcare
The charm of Mathematical Physics resides in the conceptual difficulty of understanding why the language of Mathematics is so appropriate to formulate the laws of Physics and to make precise predictions. Citing Eugene Wigner, this “unreasonable appropriateness of Mathematics in the Natural Sciences” emerged soon at the beginning of the scientific thought and was splendidly depicted by the words of Galileo: “The grand book, the Universe, is written in the language of Mathematics.” In this marriage, what Bertrand Russell called the supreme beauty, cold and austere, of Mathematics complements the supreme beauty, warm and engaging, of Physics. This book, which consists of nine articles, gives a flavor of these beauties and covers an ample range of mathematical subjects that play a relevant role in the study of physics and engineering. This range includes the study of free probability measures associated with p-adic number fields, non-commutative measures of quantum discord, non-linear Schrödinger equation analysis, spectral operators related to holomorphic extensions of series expansions, Gibbs phenomenon, deformed wave equation analysis, and optimization methods in the numerical study of material properties.
  • Hardback
License and Copyright
© 2021 by the authors; CC BY-NC-ND license
prolongation structure; mNLS equation; Riemann-Hilbert problem; initial-boundary value problem; free probability; primes; p-adic number fields; Banach *-probability spaces; weighted-semicircular elements; semicircular elements; truncated linear functionals; FCM fuel; thermal–mechanical performance; failure probability; silicon carbide; quantum discord; non-commutativity measure; dynamic models; Gibbs phenomenon; quasi-affine; shift-invariant system; dual tight framelets; oblique extension principle; B-splines; crack growth behavior; particle model; intersecting flaws; uniaxial compression; reinforced concrete; retaining wall; optimization; bearing capacity; particle swarm optimization; PSO; generalized Fourier transform; deformed wave equation; Huygens’ principle; representation of ??(2,ℝ); holomorphic extension; spherical Laplace transform; non-Euclidean Fourier transform; Fourier–Legendre expansion