Joseph Kouneiher

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Joseph Kouneiher
Joseph Kouneiher.jpg
Born(1963-08-08)8 August 1963
France
Website https://scholar.google.fr/citations?user=9-0vJ4gAAAAJ&hl=en

Joseph Kouneiher is a French mathematical physicist. [1] He is a professor of mathematical physics and engineering sciences at Nice SA University, France. He works primarily on the foundations of science, and his work in the domains of quantum field theory, quantum gravity, string theory and conformal field theory is widely cited and is well known. [2] He holds three PHDs in mathematical physics and Epistemology and history of sciences.

Contents

Research work

He developed and generalized (with his colleague Frédéric Hélein) Hermann Weyl's Hamiltonian formalism for quantum fields theories, what we call today a Covariant Hamiltonian formalism for the calculus of variations with several variables. [3] [4] [5] The main purpose is to build a hamiltonian theory of fields which is consistent with the principles of relativity. It's a finite dimension formalism for a quantum theories. He also clarified the topological (or cohomological) aspect of certain approach to quantum gravity and the role of the integrability in the foundations of such theories. [6] [7] [8] [9]

In addition to his contributions in mathematical physics, he introduced the cohomological aspect of the mathematical logic theories or what we call now cohomological logic. The aim of the program of "cohomological logic" is to generalize the foundations of the usual theories of logic and connect logic with homotopy theory by introducing a Hopf structure into the generalized logic theories through a geometric approach. This formalism has a great impact on the foundations of some representations of quantum theories [10] [11]

His collaborations with Michael Atiyah to figure out a geometric model for matter. Starting from the idea of an ultimate granular structure of the space-time, which generalizes the continuum and the discontinuum aspects of the space-time, he developed a formalism which generalizes the differential equations and difference equations theories to treat such spaces that appear continuous at low energies and exhibit a dual continuum and discontinuum aspects at high energy.

Apart from his deep-routed interests in foundational sciences, he is also an aficionado of classical music. He composes musical pieces and plays piano among many other instruments.

Archimedes S.I.E.E.

Along with several leading figures, Joseph is the co-founder of the Foundation Archimedes to promote sciences, innovation, education and environment.

The scientific committee includes Sir Roger Penrose, Alain Connes, Simon Donaldson, Mathilde Marcolli, Hugo Duminil-Copin, Misha Gromov, Abhay Ashtekar, Carlo Rovelli, Jeremy Butterfield, Jean-Pierre Luminet, Abhay Ashtekar, Alicia Dickenstein, Jean-Pierre Bourguignon and Sir Michael Atiyah. [12]

Located in Saint-Raphaël, Var, provides interdisciplinary research residencies for both French and international researchers, entrepreneurs, and industrialists. Its facilities are designed to promote focus and creativity, offering opportunities for both individual and small group study stays. The Foundation supports work across a broad range of disciplines, including Industrial Sciences, Technologies, and Environmental Studies.

A key mission of the Foundation is to host prominent scientists, entrepreneurs, and industrialists whose contributions have advanced understanding of the physical world and humanity, as well as driven technological and cultural innovations. The goal is to foster high-level research and innovation across various fields.

Books authored/co-authored/edited

Related Research Articles

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<span class="mw-page-title-main">Loop quantum gravity</span> Theory of quantum gravity, merging quantum mechanics and general relativity

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In theoretical physics, geometrodynamics is an attempt to describe spacetime and associated phenomena completely in terms of geometry. Technically, its goal is to unify the fundamental forces and reformulate general relativity as a configuration space of three-metrics, modulo three-dimensional diffeomorphisms. The origin of this idea can be found in an English mathematician William Kingdon Clifford's works. This theory was enthusiastically promoted by John Wheeler in the 1960s, and work on it continues in the 21st century.

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References

  1. "Joseph Kouneiher - Citations Google Scholar". scholar.google.fr.
  2. Luciano, Boi (2 November 2005). Geometries of Nature, Living Systems And Human Cognition: New Interactions of Mathematics With Natural Sciences And Humanities. World Scientific. ISBN   9789814479455 via Google Books.
  3. J. Kouneiher and F. Hélein, Finite dimensional Hamiltonian formalism for gauge and quantum fields theories, J. Math. Phys. vol 43, N◦ 5, 2002.
  4. F. Hélein and J. Kouneiher, Covariant Hamiltonian formalism for the calculus of variations with several variables : Lepage–Dedecker versus De Donder–Weyl, Adv. Theor. Math. Phys. Vol 8, N◦ 3, 565–601, 2004
  5. J. Kouneiher and F. Hélein, The notion of observable in the covariant Hamiltonian formalism for the calculus of variations with several variables, Adv. Theor. Math. Phys. Vol 8, N◦ 4, 735–777, 2004.
  6. J. Kouneiher, Symmetry and Cohomological foundations of Physics, J. Kouneiher ed. Vers une nouvelle Philosophie de la nature : Actualités Mathématiques, Physique et Biologique, ed. Her- mann, 2010.
  7. J. Kouneiher and C. Barbachoux, Cartan’s soldered spaces and conservation laws in physics, Int. J . Geom. Meth. Mod. Phys., Vol 12, N◦ 09, 1550089, 2015.
  8. C. Barbachoux and J. Kouneiher, Dark matter as residual of Topological changes, Int. J. Geom. Methods Mod. Phys. DOI : 10.1142/S0219887816500274
  9. J. Kouneiher, Einstein flow, Geometrization and cosmology, Int. J. Mod. Phys. A, vol 30, N◦ 18n19, 1530047, 2015.
  10. J. Kouneiher and A. Balan, Propositional manifolds and logical cohomology, Synthese 125 : 147–154, 2000.
  11. N. da Costa and J. Kouneiher, Superlogic manifolds and geometric approach to quantum logic, International Journal of Geometric Methods in Modern Physics Vol. 12, 2015.
  12. "Board (All)".
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