Link to Full List Of Publications
Foundations of Non Hermitian Quantum Mechanics
- Moiseyev, N., Certain, P., & Weinhold, F. (1978). Resonance properties of complex-rotated hamiltonians. Mol. Phys., 36(6), 1613–1630. doi: View Article [c-product, c-variational theory, c-hyper virial theorem]
- Moiseyev, N., & Certain, P. (1979). Perturbation approach to the complex-rotation method. Mol. Phys., 37(5), 1621–1632. doi: View Article
- Moiseyev, N., & Corcoran, C. (1979). Autoionizing states of H2 and H2− using the complex-scaling method. Phys. Rev. A, 20(3), 814–817. doi: 10.1103/PhysRevA.20.814 [resonances by analytical continuation of Hamiltonian matrix elements to the complex plane rather than operators]
- Moiseyev, N., & Weinhold, F. (1979). Electron-correlation effects in the positions and widths of 2-electron auto-ionizing resonances. Phys. Rev. A, 20(1), 27–31. doi: View Article
- Moiseyev, N., & Friedland, S. (1980). Association of resonance states with the incomplete spectrum of finite complex-scaled hamiltonian matrices. Phys. Rev. A, 22(2), 618–624. doi: View Article [first association of EP (branch point in the spectrum ) with resonances by complex scaling]
- Moiseyev, N. (1981). Virial-theorem for bound and resonance states as a special case of the scattering virial-theorem. Phys. Rev. A, 24(5), 2824–2825. doi: View Article
- Moiseyev, N., Friedland, S., & Certain, P. (1981). Cusps, theta-trajectories, and the complex virial-theorem. J. Chem. Phys., 74(8), 4739–4740. doi:View Article [first association of resonances with cusps in trajectory plots of complex energies]
- Moiseyev, N. (1981a). Studies of multi-channel resonances by the complex scaling method. Mol. Phys., 42(1), 129–139. doi: View Article
- Moiseyev, N. (1982). Resonance states by the generalized complex variational method. Mol. Phys., 47(3), 585–598. doi: View Article
- Moiseyev, N. (1983). Resonance by the complex coordinate method with Hermitian hamiltonian. Chem. Phys. Lett., 99(4), 364–367. doi: View Article [first Hermitian representation of non-hermitian TISE]
- Moiseyev, N., & Hirschfelder, J. (1988). Representation of several complex coordinate methods by similarity transformation operators. J. Chem. Phys., 88(2), 1063–1065. doi: View Article [formal ground to large number if not all computational algorithms for calculating resonances by complex scaling]
- Moiseyev, N., & Peskin, U. (1990). Partial widths obtained by the complex resonance-scattering theory. Phys. Rev. A, 42(1), 255–260. doi: View Article
- Bental, N., Moiseyev, N., Leforestier, C., & Kosloff, R. (1991). Positions, lifetimes, and partial widths of metastable quasi-energy states by solving the time-dependent complex-scaled Schrodinger-equation. J. Chem. Phys., 94(11), 7311–7318.doi: View Article
- Peskin, U., & Moiseyev, N. (1992). The complex coordinate scattering theory and the Kohn variational method: A general formulation and application to long range potentials. J. Chem. Phys., 97(9), 6443–6450. doi: View Article
- Rom, N., Ryaboy, V., & Moiseyev, N. (1993). Cumulative reaction probability by the complex coordinate scattering-theory. J. Chem. Phys., 98(8), 6327–6331.doi: View Article
- Vorobeichik, I., & Moiseyev, N. (1998). State-to-state transition probabilities for time-dependent hamiltonians using complex absorbing potentials. J. Phys. B-At. Mol. Opt. Phys., 31(4), 645–656. doi: View Article
- Moiseyev, N. (1998). Derivations of universal exact complex absorption potentials by the generalized complex coordinate method. J. Phys. B-At. Mol. Opt. Phys., 31(7), 1431–1441. doi: View Article
- Moiseyev, N., & Cederbaum, L. (1999). Suppression of electron correlation and of autoionization by strong laser fields. J. Phys. B-At. Mol. Opt. Phys., 32(12), L279–L284. doi: View Article
- Vorobeichik, I., & Moiseyev, N. (1999). Revealing broad overlapping resonances by strong laser fields. Phys. Rev. A, 59(2), 1699–1702. doi: View Article
- Narevicius, E., & Moiseyev, N. (2000). Non-hermitian formulation of interference effect in scattering experiments. J. Chem. Phys., 113(15), 6088–6095. doi: View Article
- Moiseyev, N., & Lein, M. (2003). Non-hermitian quantum mechanics for high-order harmonic generation spectra. J. Phys. Chem. A, 107(37), 7181–7188.doi: View Article
- Fleischer, a., & Moiseyev, N. (2005). Adiabatic theorem for non-hermitian time-dependent open systems. Phys. Rev. A, 72(3). doi: View Article
- Moiseyev, N. (2009). Feshbach resonances: The branching of quantum mechanics into hermitian and non-hermitian formalisms. J. Phys. Chem. A, 113(26), 7660–7666. doi: View Article
- Gilary, I., Fleischer, a., & Moiseyev, N. (2005). Calculations of time-dependent observables in non-hermitian quantum mechanics: The problem and a possible solution. Phys. Rev. A, 72(1, A-B). doi: View Article
- Moiseyev, N. (2017). Forces on nuclei moving on autoionizing molecular potential energy surfaces. J. Chem. Phys., 146(2). doi: View Article
- Pick, A., Kapralova-zd’anska, P. R., & Moiseyev, N. (2019). Ab-initio theory of photoionization via resonances. J. Chem. Phys., 150(20). doi: View Article
- Ben-asher, A., Simsa, D., Uhlirov, T., Sindelka, M., & Moiseyev, N. (2020). Laser control of resonance tunneling via an exceptional point. Phys. Rev. Lett., 124(25). doi: View Article
BOOK [first ever written on NHQM] :
- Moiseyev, N. (2011). Non-Hermitian quantum mechanics. Cambridge University Press doi: View Article.
- Monograph: Moiseyev, N. (1998). Quantum theory of resonances: Calculating energies, widths and cross-sections by complex scaling. Phys. Rep.-Rev. Sec. Phys. Lett., 302(5-6), 212–293.
REVIEWS:
- Narevicius, E., & Moiseyev, N. (2003). Non-Hermitian Quantum Mechanics: Theory and Experiments Not Amenable to Conventional QM. In Advanced Topics in Theoretical Chemical Physics (pp. 311-338). Springer, Dordrecht.
- Moiseyev, N. (1995). Time-Independent Scattering Theory for General Time-Dependent Hamiltonians. Comments on Atomic and Molecular Physics, 31(2), 87-108.
- Moiseyev, N., & Korsch, H. (1990). Resonance positions and widths for time-periodic hamiltonians by the complex coordinate method. Isr. J. Chem., 30(1-2), 107–114.