Heisenberg chain equations in terms of Fockian covariance with electric field account and multiferroics in nanoscale

Heitler–Heisenberg multispin states were studied via irreducible representations of the united symmetry with respect to permutations and space transformations group. The mean energy is given in explicit form in terms of the characters of the joint group irreducible representations. The system’s Fockian covariance incorporates its exchange integral of the self-consistent states into the Heisenberg chain theory. External fields account is delivered in perturbation theory frame. Its application to statistical physics approach leads to the thermodynamic parameter evaluation. The nanotube example with space symmetry including rotations and translations, is studied. Its symmetry introduces basic closest neighbor exchange integrals that enter the statistical sum.

1. Heisenberg W. Zur Theorie des Ferromagnetismus. Zeitschrift fur Physik ¨ , 1928, 49(9-10), P. 619–636.

2. Fock V.A. An Approximate Method for Solving the Quantum Many-Body Problem. Reported at the Session of the Russian Phys.-Chem. Soc. on 17 December 1929. Selected works. Quantum Mechanics and Quantum Field Theory. Ed. by L.D. Faddeev, L.A. Khalfin, I.V. Komarov. P. 137–164, CRC Press, 2004.

3. Popov I.Y., Melikhov I.F. The discrete spectrum of the multiparticle Hamiltonian in the framework of the Hartree-Fock approximation. Journal of Physics: Conference Series, 2014, 541. P. 012099/1–4.

4. Heitler W. Zur Gruppentheorie der homopolaren chemischen Bindung. Zs. Phys., 1928, 47, P. 835–838.

5. Geyler V.A., Popov I.Yu. Group-theoretical analysis of lattice Hamiltonians with a magnetic field. Phys. Lett. A., 1995, 201, P. 359–364.

6. Wigner E. Group Theory. Academic Press, New York, London, 1959.

7. Petrashen M., Trifonov E. Applications of Group Theory in Quantum Mechanics. Dover publication, 2009.

8. Jens P. Dahl: Introduction to The Quantum World of Atoms and Molecules. World Scientific Publishing, Singapore, 2001.

9. Fock V.A. Application of Two-Electron Functions in the Theory of Chemical Bonds. Selected works. Quantum Mechanics and Quantum Field Theory. Ed. by L.D. Faddeev, L.A. Khalfin, I.V. Komarov. P. 519–524, CRC Press, 2004.

10. Fock V.A. On Quantum Exchange Energy. Selected works. Quantum Mechanics and Quantum Field Theory. Ed. by L.D. Faddeev, L.A. Khalfin, I.V. Komarov. P. 263–278, CRC Press, 2004.

11. Roberts J.A.G., Tompson C.J. Dynamics of the classical Heisenberg spin chain. Journal of Physics A: Mathematical and General, 1988, 21(8), P. 1769–1780.

12. Leble S. Cyclic-periodic ZRP structures. Scattering problem for generalized Bloch functions and conductivity. Nanosystems: physics, chemistry, mathematics, 2018, 9(2), P. 225–243.

13. Dzyaloshinskii I.E. On the magneto-electrical effect in antiferromagnets. J. Exp. Theor. Phys. (U.S.S.R.), 1959, 37, P. 881–882.

14. Chandrashekar Radhakrishnan, Manikandan Parthasarathy, Segar Jambulingam and Tim Byrnes. Quantum coherence of the Heisenberg spin models with Dzyaloshinsky–Moriya interactions. Scientific Reports, 2017, 7, P. 13865.

15. Spaldin, Nicola A., Fiebig, Manfred. The renaissance of magnetoelectric multiferroics. Science, 2005, 309(5733), P. 391–392.

16. Zakharov V.E., Takhtajan L.A. Equivalence of the nonlinear Schrodinger equation and the equation of a Heisenberg ferromagnet. ¨ Theor. Math. Phys., 1979, 38, P. 17–23.

17. Heitler W. Staorungsenergie und Austausch beim Mehrk ¨ aorperproblem. ¨ Zs. Phys., 1927, 46, P. 47.