Structure fractals and para-quaternionic geometry

Julian Ławrynowicz, Massimo Vaccaro

Abstract


It is well known that starting with real structure, the Cayley-Dickson process gives complex, quaternionic, and octonionic (Cayley) structures related to the Adolf Hurwitz composition formula for dimensions \(p = 2, 4\) and \(8\), respectively, but the procedure fails for \(p = 16\) in the sense that the composition formula involves no more a triple of quadratic forms of the same dimension; the other two dimensions are \(n = 2^7\). Instead, Ławrynowicz and Suzuki (2001) have considered graded fractal bundles of the flower type related to complex and Pauli structures and, in relation to the iteration process \(p \to p + 2 \to p + 4 \to ...\), they have constructed \(2^4\)-dimensional “bipetals” for \(p = 9\) and \(2^7\)-dimensional “bisepals” for \(p = 13\). The objects constructed appear to have an interesting property of periodicity related to the gradating function on the fractal diagonal interpreted as the “pistil” and a family of pairs of segments parallel to the diagonal and equidistant from it, interpreted as the “stamens”. The first named author, M. Nowak-Kepczyk, and S. Marchiafava (2006, 2009a, b) gave an effective, explicit determination of the periods and expressed them in terms of complex and quaternionic structures, thus showing the quaternionic background of that periodicity. In contrast to earlier results, the fractal bundle flower structure, in particular petals, sepals, pistils, and stamens are not introduced ab initio; they are quoted a posteriori, when they are fully motivated. Physical concepts of dual and conjugate objects as well as of antiparticles led us to extend the periodicity theorem to structure fractals in para-quaternionic formulation, applying some results in this direction by the second named author. The paper is concluded by outlining some applications.

Keywords


Fractal; quaternion; para-quaternion; Clifford structure; para-quaternionic structure; bilinear form; quadratic form

Full Text:

PDF

References


Kigami, J., Analysis on Fractals, Cambridge Tracts in Mathematics 143, Cambridge University Press, Cambridge, 2001.

Kovacheva, R., Ławrynowicz, J. and Nowak-Kepczyk, M., Critical dimension 13 in approximation related to fractals of algebraic structure, XIII Conference on Analytic

Functions, Bull. Soc. Sci. Lett. Łódź Ser. Rech. Deform. 37 (2002), 77-102.

Ławrynowicz, J., Marchiafava, S. and Nowak-Kępczyk, M., Quaternionic background of the periodicity of petal and sepal structures in some fractals of the flower type,

Proceedings of the 5th ISAAC Congress, Catania, July 25-30, 2005: More Progresses in Analysis, ed. by H. Begehr and F. Nicolosi, World Scientific, Singapore, 2009, pp.

-996.

Ławrynowicz, J., Marchiafava, S. and Nowak-Kępczyk, M., Periodicity theorem for structure fractals in quaternionic formulation, Int. J. Geom. Methods Mod. Phys. 5

(2006), 1167-1197.

Ławrynowicz, J., Marchiafava, S. and Nowak-Kępczyk, M., Cluster sets and periodicity in some structure fractals, Topics in Contemporary Differential Geometry, Complex Analysis and Mathematical Physics, ed. by S. Dimiev and K. Sekigawa, World Scientific, New Jersey–Singapore–London, 2007, pp. 179-195.

Ławrynowicz, J., Marchiafava, S. and Nowak-Kępczyk, M., Mathematical outlook of fractals and related to simple orthorhombic Ising-Onsager-Zhan lattices, Complex

Strucures, Intergrability, Vector Fields, and Mathematical Physics, ed. by S. Dimiev and K. Sekigawa, World Scientific, Singapore, 2009, pp. 156-166.

Ławrynowicz, J., Marchiafava, S. and Nowak-Kępczyk, M., Applied peridicity theorem for structure fractals in quaternionic formulation, Applied Complex and Quaternionic Approximation, ed. by R. K,Kovacheva, J. Ławrynowicz and S. Marchiafava, Ediz. Nuova Cultura Univ. “La Sapienza”, Roma, 2009, pp. 93-122.

Ławrynowicz, J., Nono, K. and Suzuki, O., Hyperfunctions on fractal boundaries: meromorphic Schauder basis for a fractal set, Bull. Soc. Sci. Lett. Łódź Ser. Deform. 53 (2007), 63-74.

Ławrynowicz, J., Nowak-Kępczyk, M. and Suzuki, O., A duality theorem for inoculated graded fractal bundles vs. Cuntz algebras and their central extensions, Int. J. Pure Appl. Math. 52 (2009), 315-338.

Ławrynowicz, J., Ogata, T. and Suzuki, O., Differential and integral calculus for Schauder basis on a fractal set (I) (Schauder basis 80 years after), Lvov Mathematical

School in the Period 1915–45 as Seen Today, ed. by B. Bojarski, J. Ławrynowicz and Ya. G. Prytuła, Banach Center Publications 87, Institute of Mathematics, Polish

Academy of Sciences, Warszawa, 2009, pp. 115-140.

Ławrynowicz, J., Suzuki, O., Periodicity theorem for graded fractal bundles related to Clifford structures, Int. J. Pure Appl. Math. 24 (2005), no. 2, 181-209.

Ławrynowicz, J., Suzuki, O. and Castillo Alvarado, F. L., Basic properties and applications of graded fractal bundles related to Clifford structures: An introduction, Ukrain. Math. Zh. 60 (2008), 603-618.

Lounesto, P., Clifford Algebra and Spinors, London Math. Soc. Lecture Notes 239, Cambridge Univ. Press, Cambridge, 1997, 2nd ed. (vol. 286), ibid. 2001.

Vaccaro, M., Subspaces of a para-quaternionic Hermitian vector space, 2010, ArXiv:1011.2947v1 [math.D6]; Internat. J. of Geom. Methods in Modern Phys. 8

(2011), in print.

Vaccaro, M., Basics of linear para-quaternionic geometry I. Hermitian para-type structure on a real vector space, Bull. Soc. Sci. Lett. Łódź Ser. Rech. Deform. 61 (2011), no. 1, 23-36.

Vaccaro, M., Basics of linear para-quaternionic geometry II. Decomposition of a generic subspace of a para-quaternionic hermitian vector space, Bull. Soc. Sci. Lett.

Łódź Ser. Rech. Deform. 61 (2011), no. 2, 17-34.




DOI: http://dx.doi.org/10.17951/a.2011.65.2.63-73
Date of publication: 2016-07-27 21:54:09
Date of submission: 2016-07-26 21:20:33


Statistics


Total abstract view - 720
Downloads (from 2020-06-17) - PDF - 361

Indicators



Refbacks

  • There are currently no refbacks.


Copyright (c) 2011 Julian Ławrynowicz, Massimo Vaccaro