Applications of NHQM:  design of electronic devices (quantum wells and quantum dotes)

  • Vorobeichik, I., Lefebvre, R., & MoiseyevN. (1998). Field-induced barrier transparency. Europhys. Lett.41(2), 111–116. doi: View Article

 

  • Goldzak, T., Gantz, L., Gilary, I., Bahir, G., & MoiseyevN. (2016). Vertical currents due to interatomic coulombic decay in experiments with two coupled quantum wells. Phys. Rev. B93(4). doi: View Article

 

  • Ben-asher, A., Simsa, D., Uhlirov, T., Sindelka, M., & MoiseyevN. (2020). Laser control of resonance tunneling via an exceptional point. Phys. Rev. Lett.124(25) doi: View Article

 

  • MoiseyevN. (2009b). Suppression of Feshbach resonance widths in two-dimensional waveguides and quantum dots: A lower bound for the number of bound states in the continuum. Phys. Rev. Lett.102(16). doi: View Article [opens a door for the construction of diodes and optical switches that operate with a very narrow band width, or reflectors or mirrors for a selected frequency electromagnetic radiation]

 

Applications of NHQM to optical communication and design optical devices

  • Vorobeichik, I., Peskin, U., & Moiseyev, N. (1995). Propagation of light beam in optical fiber by the (t, t′) method. Nonlinear Opt.

 

  • Vorobeichik, I., Peskin, U., & MoiseyevN. (1995). Modal losses and design of modal irradiance patterns in an optical-fiber by the complex scaled (t,t’) method. J. Opt. Soc. Am. B-Opt. Phys.12(6), 1133–1141. doi: View Article

 

  • Vorobeichik, I., MoiseyevN., & Neuhauser, D. (1997). Effect of the second-derivative paraxial term in the scalar maxwell’s equation on amplitude losses and reflections in optical fibers. J. Opt. Soc. Am. B-Opt. Phys.14(5), 1207–1212. doi: View Article

 

  • Vorobeichik, I., MoiseyevN., Neuhauser, D., Orenstein, M., & Peskin, U. (1997). Calculation of light distribution in optical devices by a global solution of an inhomogeneous scalar wave equation. IEEE J. Quantum Electron.33(7), 1236–1244. doi:10.1109/3.594890

 

  • Vorobeichik, I., Orenstein, M., & MoiseyevN. (1998). Intermediate-mode-assisted optical directional couplers via embedded periodic structure. IEEE J. Quantum Electron.34(9), 1772–1781. doi: View Article [ON THE BASIS OF THE THEORY PRESENTED HERE IN 2000  A STARTUP COMPNANY OPTUN.LTD WAS FOUNDED]

 

  • Vorobeichik, I., Lefebvre, R., & MoiseyevN. (1998). Field-induced barrier transparency. Europhys. Lett.41(2), 111–116. doi: View Article
  • Vorobeichik, I., & MoiseyevN. (1999b). Tunneling control by high-frequency driving. Phys. Rev. A59(3), 2511–2514. doi: View Article

 

  • Kenis, A., Vorobeichik, I., & MoiseyevN. (2000). Analysis of an intermediate-mode-assisted directional coupler using bloch theory. IEEE J. Quantum Electron.36(5), 563–573. doi: View Article

 

  • Kenis, A., Vorobeichik, I., Orenstein, M., & MoiseyevN. (2001). Non-evanescent adiabatic directional coupler. IEEE J. Quantum Electron.37(10), 1321–1328. doi: View Article

 

  • MoiseyevN., & Sindelka, M. (2021). Transfer of information through waveguides near an exceptional point. Phys. Rev. A103(3). doi: View Article