NUMERICAL STUDY OF QUANTUM DOT SPECTRUM CALCULATION ON THE BASE OF MONTE CARLO METHOD


Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription Access

Abstract

The work is directed to numerical simulation of quantum dots spectrum for molecular nanostructure of small size for creation of new nanotechnology. Quantum dots are the small peaces of semiconductor which presents the molecular system heterostucture. The cariers of charge are confined in small region. The main acsent is made on development of effective method for determination of eigenfuncions and eigenvalues of quantum dot. Quantum dots are used in nanoelectronics, in bio-sensors of nanosize, and in the systems of medical diagnostics of high precision.

Full Text

Restricted Access

About the authors

Alexander Mikhailovich Popov

Lomonosov Moscow State University

Email: professorpopov@gmail.com
doctor in physics and mathematics; professor Moscow, Russian Federation

References

  1. Попов А.М. Вычислительные нанотехнологии. М.: КноРус, 2014. 312 c.
  2. Kosztin I., Farber B., Schulten K. Introduction to the diffusion Monte Carlo method // Am. J. Phys. 1997. № 64. Р. 633-644.
  3. Shumway J., Ceperly D.M. Quantum Monte Carlo methods in the study of nanostructures // Encyclopedia of Nanoscience and Nanotechnology. 2004.
  4. Clote P. Computational molecular biology an introduction.
  5. Сетубал Ж., Майданис Ж. Введение в вычислительную молекулярную биологию. М.-Ижевск: НИЦ «Регулярная и хаотична динамика», Ин-т компьютерных исследований, 2007. 420 с.
  6. Clary D.C. Torsional diffusion Monte Carlo: A method for quantum simulations of proteins. University College London. 2001.
  7. Kerr R.A., Bartol T.M. Fast Monte Carlo simulation methods for biological reaction-diffusion systems in solution and on surfaces. 2008.
  8. Iba Y. Population Monte-Carlo algorithms. The Institute of Statistical Mathematics.
  9. Riley M.R., Buettner H.M. Monte Carlo simulation of diffusion and reaction in two-dimensional cell structures // Biophysical Journal. May 1995. Vol. 68.
  10. Goldman J., Andrews S., Bray D. Size and composition of membrane protein clusters predicted by Monte Carlo analysis. 2004.
  11. Aluru S. Handbook of Computational Molecular Biology.
  12. Лахно В.Д. Биоинформатика и высокопроизводиельные вычисления. Институт математических проблем биологии РАН.
  13. Wang Y. Open MP and MPI implementation of diffusion Monte Carlo algorithm.
  14. Компьютеры и суперкомпьютеры в биологии / под ред. В.Д. Лахно, М.Н. Устинина. М.-Ижевск: Ин-т компьютерных исследований, 2002.
  15. Hansmann U.H.E. Parallel tempering algorithm for conformational studies of biological molecules. 1997.
  16. Earl D.J., Deem M.W. Parallel tempering: Theory, applications, and new perspectives, 2005.
  17. Caflisch A., Niederer P., Anliker M. Monte Carlo minimization with thermalization for global optimization of polypeptide conformations in Cartesian coordinate space. 1992.
  18. Sanbonmatsu K.Y., Garcia A.E. Structure of met-enkephalin in explicit aqueous solution using replica exchange molecular dynamics, 2002.
  19. Zimmerman S.S., Pottle M.S., Nemethy G., Scheraga H.A. Conformational analysis of the 20 naturally occurring amino acid residues using ECEPP // Macromolecules. 1977. Vol. 10. № 1.
  20. Nemethy G., Pottle M.S., Scheraga H.A. Energy parameters in polypeptides. 9. Updating of geometrical parameters, nonbonded interactions, and hydrogen bond for the naturally occurring amino acids // J. Phys. Chem. 1983. № 87.
  21. Sippl M.J., Nemethy G., Scheraga H.A. Intermolecular potentials from crystal data. 6. Determination of empirical potentials for O-H-O-C hydrogen bonds from packing configurations // J. Phys. Chem. 1984. № 88.
  22. McGuire R.F., Vanderkool G. Determination of intermolecular potentials from crystal data. II. Crystal packing with applications to poly (amino acids). 1970.
  23. Zaman M.H., Shen M. Computer simulation of met-enkephalin using explicit atom and united atom potentials: similarities, differences, and suggestions for improvement // J. Phys. Chem. 2003. № 107.
  24. Rackovsky S., Scheraga H.A. Differential geometry and polymer conformation. 4. Conformational and nucleation properties of individual. amino acids, macromolecules. 1982. Р. 15.
  25. Hsu H., Berg B.A., Grassberger P. Monte Carlo protein folding: Simulations of met-enkephalin with solvent-accessible area parametrizations, 2004.
  26. Mitas L. Diffusion Monte Carlo, national center for supercomputing applications. University of Illinois at Urbana-Champaign. Altekar G.et al. Parallel metropolis coupled Markov chain Monte Carlo for bayesian phylogenetic inference // Bioinformatics. 2004. № 20 (3). Р. 407-415.
  27. Geyer C.J. Markov chain Monte Carlo maximum likelihood // Computing Science and Statistics. 1991. № 23. Р. 156-163,

Supplementary files

Supplementary Files
Action
1. JATS XML
Download


This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies