Quantum Field Theory and Coalgebraic Logic in Theoretical Computer Science

We suggest that in the framework of the Category Theory it is possible to demonstrate the mathematical and logical dual equivalence between the category of the q-deformed Hopf Coalgebras and the category of the q-deformed Hopf Algebras in quantum field theory (QFT), interpreted as a thermal field theory. Each pair algebra-coalgebra characterizes a QFT system and its mirroring thermal bath, respectively, so to model dissipative quantum systems in far-from-equilibrium conditions, with an evident significance also for biological sciences. Our study is in fact inspired by applications to neuroscience where the brain memory capacity, for instance, has been modeled by using the QFT unitarily inequivalent representations. The q-deformed Hopf Coalgebras and the q-deformed Hopf Algebras constitute two dual categories because characterized by the same functor T, related with the Bogoliubov transform, and by its contravariant application Top, respectively. The q-deformation parameter is related to the Bogoliubov angle, and it is effectively a thermal parameter. Therefore, the different values of q identify univocally, and label the vacua appearing in the foliation process of the quantum vacuum. This means that, in the framework of Universal Coalgebra, as general theory of dynamic and computing systems ("labelled state-transition systems"), the so labelled infinitely many quantum vacua can be interpreted as the Final Coalgebra of an "Infinite State Black-Box Machine". All this opens the way to the possibility of designing a new class of universal quantum computing architectures based on this coalgebraic QFT formulation, as its ability of naturally generating a Fibonacci progression demonstrates.

[1]  Rudolf Haag,et al.  On the equilibrium states in quantum statistical mechanics , 1967 .

[2]  A. Connes,et al.  Von Neumann algebra automorphisms and time-thermodynamics relation in general covariant quantum theories , 1994, gr-qc/9406019.

[3]  Phase Coherence in Quantum Brownian Motion , 1997, quant-ph/9707048.

[4]  Giuseppe Vitiello,et al.  Fractals, coherent states and self-similarity induced noncommutative geometry , 2012, 1206.1854.

[5]  Massimo Piattelli-Palmarini,et al.  Linguistics and some aspects of its underlying dynamics , 2015, Biolinguistics.

[6]  H. Umezawa,et al.  THERMO FIELD DYNAMICS , 1996 .

[7]  Julian Schwinger,et al.  Theory of Many-Particle Systems. I , 1959 .

[8]  G. Vitiello,et al.  Vacuum structure for unstable particles , 1977 .

[9]  Giuseppe Vitiello,et al.  Dissipation of 'dark energy' by cortex in knowledge retrieval. , 2013, Physics of life reviews.

[10]  W. Freeman,et al.  Dissipation and spontaneous symmetry breaking in brain dynamics , 2007, q-bio/0701053.

[11]  S. Siena,et al.  Thermo field dynamics and quantum algebras , 1998, hep-th/9801031.

[12]  G. Vitiello The use of many-body physics and thermodynamics to describe the dynamics of rhythmic generators in sensory cortices engaged in memory and learning , 2015, Current Opinion in Neurobiology.

[13]  Giuseppe Vitiello,et al.  COHERENT STATES, FRACTALS AND BRAIN WAVES , 2009, 0906.0564.

[14]  Hiroomi Umezawa,et al.  Advanced Field Theory: Micro, Macro, and Thermal Physics , 1993 .

[15]  J. Linnett,et al.  Quantum mechanics , 1975, Nature.

[16]  Samson Abramsky,et al.  Introduction to Categories and Categorical Logic , 2011, ArXiv.

[17]  D. Kusnezov,et al.  Quantum Dissipation , 1995, nucl-th/9507034.

[18]  O. Bratteli Operator Algebras And Quantum Statistical Mechanics , 1979 .

[19]  Masamichi Takesaki,et al.  Tomita's Theory of Modular Hilbert Algebras and its Applications , 1970 .

[20]  M. Stone,et al.  The Theory of Representation for Boolean Algebras , 1936 .

[21]  Steve Awodey,et al.  Category Theory , 2006 .

[22]  W. Freeman,et al.  Dissipation, spontaneous breakdown of symmetry and brain dynamics. , 2008 .

[23]  I. Ojima Gauge fields at finite temperatures—“Thermo field dynamics” and the KMS condition and their extension to gauge theories , 1981 .

[24]  G. Vitiello My double unveiled , 2001 .

[25]  R. Kubo Statistical-Mechanical Theory of Irreversible Processes : I. General Theory and Simple Applications to Magnetic and Conduction Problems , 1957 .

[26]  S. Simon,et al.  Non-Abelian Anyons and Topological Quantum Computation , 2007, 0707.1889.

[27]  Jan J. M. M. Rutten,et al.  Universal coalgebra: a theory of systems , 2000, Theor. Comput. Sci..

[29]  Antonio L. Perrone A Formal Scheme for Avoiding Undecidable Problems - Applications to Chaotic Behaviour, Characterization and Parallel Computation , 1993, Analysis of Dynamical and Cognitive Systems.

[30]  Emanuela Merelli,et al.  Topological Field Theory of Data: Mining Data Beyond Complex Networks , 2016 .

[31]  B. Rosenow,et al.  Enhanced Bulk-Edge Coulomb Coupling in Fractional Fabry-Perot Interferometers. , 2014, Physical review letters.

[32]  J. O'Brien,et al.  Universal linear optics , 2015, Science.

[33]  Gérard G. Emch,et al.  Algebraic methods in statistical mechanics and quantum field theory , 1972 .

[34]  Samson Abramsky,et al.  Coalgebras, Chu Spaces, and Representations of Physical Systems , 2009, 2010 25th Annual IEEE Symposium on Logic in Computer Science.

[35]  Giuseppe Vitiello,et al.  DISSIPATION AND MEMORY CAPACITY IN THE QUANTUM BRAIN MODEL , 1995, quant-ph/9502006.

[36]  M. Stone The theory of representations for Boolean algebras , 1936 .

[37]  S. Braunstein,et al.  Quantum computation , 1996 .

[38]  W. Freeman,et al.  Nonlinear brain dynamics as macroscopic manifestation of underlying many-body field dynamics , 2005, q-bio/0511037.

[39]  Peter Aczel,et al.  A Final Coalgebra Theorem , 1989, Category Theory and Computer Science.

[40]  I. Chuang,et al.  Quantum Computation and Quantum Information: Introduction to the Tenth Anniversary Edition , 2010 .

[41]  Is quantum simulation of turbulence within reach , 2014 .

[42]  I. I. Ivanchik THEORY OF THE MANY-PARTICLE SYSTEMS. , 1968 .

[43]  Samson Abramsky,et al.  A Cook's Tour of the Finitary Non-Well-Founded Sets , 2011, We Will Show Them!.

[44]  K. West,et al.  Magnetic-field-tuned Aharonov-Bohm oscillations and evidence for non-Abelian anyons at ν = 5/2. , 2013, Physical review letters.

[45]  J. Cronin Broken Symmetries , 2011 .

[46]  G. Basti The Quantum Field Theory (QFT) Dual Paradigm in Fundamental Physics and the Semantic Information Content and Measure in Cognitive Sciences , 2017 .

[47]  Giuseppe Vitiello,et al.  Classical chaotic trajectories in quantum field theory , 2003, hep-th/0309197.

[48]  H. Matsumoto,et al.  Thermo Field Dynamics and Condensed States , 1982 .

[49]  Giuseppe Vitiello,et al.  On the Isomorphism between Dissipative Systems, Fractal Self-Similarity and Electrodynamics. Toward an Integrated Vision of Nature , 2014, Syst..

[50]  D. A. Edwards The mathematical foundations of quantum mechanics , 1979, Synthese.

[51]  竹崎 正道 Tomita's theory of modular Hilbert algebras and its applications , 1970 .

[52]  Mario Rasetti,et al.  Quantum Physics, Topology, Formal Languages, Computation: A Categorical View as Homage to David Hilbert , 2014, Perspectives on Science.

[53]  A. Perelomov Generalized Coherent States and Their Applications , 1986 .

[54]  Luca Aceto,et al.  Advanced Topics in Bisimulation and Coinduction , 2012, Cambridge tracts in theoretical computer science.

[55]  G. Basti A change of paradigm in cognitive neurosciences: comment on: "Dissipation of 'dark energy' by cortex in knowledge retrieval" by Capolupo, Freeman and Vitiello. , 2013, Physics of life reviews.