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Publications of Gleb Finkelstein    :recent first  combined  bibtex listing:

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Papers Published

  1. J. Pieprzyk and G. Finkelstein, Towards effective nonlinear cryptosystem design, Iee Proceedings-e Computers And Digital Techniques, vol. 135 no. 6 (November, 1988), pp. 325 -- 335
  2. G. Finkelstein, S. Barad, O. Carmel, I. Barjoseph, Y. Levinson, Biexcitonic effects in transient nonlinear-optical experiments in quantum-wells, Phys. Rev. B, vol. 47 no. 19 (May 1993), pp. 12964 -- 12967
  3. S. Barad, I. Barjoseph, G. Finkelstein, Y. Levinson, Biexcitons in short-pulse optical experiments in strong magnetic-fields in gaas quantum-wells, Phys. Rev. B, vol. 50 no. 24 (December 1994), pp. 18375 -- 18381
  4. G. Finkelstein and I. Barjoseph, Charged excitons in GaAs quantum wells., Nuovo Cimento Della Societa Italiana Di Fisica D-condensed Matter Atomic Molecular And Chemical Physics Fluids Plasmas Biophysics, vol. 17 no. 11-12 (1995), pp. 1239 -- 1245
  5. G. Finkelstein, H. Shtrikman, I. Barjoseph, Optical spectroscopy of a 2-dimensional electron-gas near the metal-insulator-transition, Phys. Rev. Lett., vol. 74 no. 6 (February 1995), pp. 976 -- 979
  6. I. Barjoseph, G. Finkelstein, S. Barad, H. Shtrikman, Y. Levinson, 4-wave-mixing in modulation-doped gaas quantum-wells under strong magnetic-fields, Physica Status Solidi B-basic Research, vol. 188 no. 1 (March 1995), pp. 457 -- 463
  7. G. Finkelstein, H. Shtrikman, I. Barjoseph, Optical spectroscopy of neutral and charged excitons in GaAs/AlGaAs quantum wells in high magnetic fields, Surface Science, vol. 362 no. 1-3 (1996), pp. 357 -- 362
  8. G. Finkelstein, H. Shtrikman, I. Barjoseph, Negatively and positively charged excitons in GaAs/AlxGa1-xAs quantum wells, Phys. Rev. B, vol. 53 no. 4 (January 1996), pp. R1709 -- R1712
  9. G. Finkelstein, H. Shtrikman, I. Barjoseph, Shakeup processes in the recombination spectra of negatively charged excitons, Phys. Rev. B, vol. 53 no. 19 (May 1996), pp. 12593 -- 12596
  10. I. Barjoseph and G. Finkelstein, Trions in GaAs quantum wells, INSTITUTE OF PHYSICS CONFERENCE SERIES, Compound Semiconductors 1996 no. 155 (1997), pp. 711 -- 716
  11. G. Finkelstein, H. Shtrikman, I. Barjoseph, Mechanism of shakeup processes in the photoluminescence of a two-dimensional electron gas at high magnetic fields, Phys. Rev. B, vol. 56 no. 16 (October 1997), pp. 10326 -- 10331
  12. G. Finkelstein, H. Shtrikman, I. Bar-joseph, Shakeup processes in a two-dimensional electron gas in GaAs/AlGaAs quantum wells at high magnetic fields, Uspekhi Fizicheskikh Nauk, vol. 168 no. 2 (February 1998), pp. 121 -- 123
  13. G. Finkelstein, H. Shtrikman, I. Bar-joseph, Shake-up processes of a two-dimensional electron gas in GaAs/AlGaAs quantum wells at high magnetic fields, Physica B, vol. 251 (June 1998), pp. 575 -- 579
  14. G. Finkelstein, Gustav Magnus and his house: Commissioned by the Deutsche Physikalische Gesellschaft, Technology And Culture, vol. 39 no. 3 (July 1998), pp. 568 -- 569
  15. G. Finkelstein, V. Umansky, I. Bar-joseph, V. Ciulin, S. Haacke, J.D. Ganiere, B. Deveaud, Charged exciton dynamics in GaAs quantum wells, Phys. Rev. B, vol. 58 no. 19 (November 1998), pp. 12637 -- 12640
  16. S. Glasberg, G. Finkelstein, H. Shtrikman and I. Bar-Joseph, Comparative Study of the Negatively and Positively Charged Excitons in GaAs Quantum Wells, Phys. Rev. B, vol. 59 (December 1999), pp. R10425
  17. G. Finkelstein, P.I. Glicofridis, S.H. Tessmer, R.C. Ashoori and M.R. Melloch, Imaging the Low Compressibility Strips Formed by the Quantum Hall Liquid in a Smooth Potential Gradient, Physica E, vol. 6 (November 2000), pp. 251
  18. G. Finkelstein, P.I. Glicofridis, R.C. Ashoori and M. Shayegan, Topographic Mapping of the Quantum Hall Liquid Using a Few Electron Bubble, Science, vol. 289 (December 2000), pp. 90
  19. G. Finkelstein, P.I. Glicofridis, S.H. Tessmer, R.C. Ashoori and M. R. Melloch, Imaging of Low Compressibility Strips in the Quantum Hall Liquid, Phys. Rev. B, vol. 61 (December 2000), pp. R16 323
  20. P.I. Glicofridis, G. Finkelstein, R.C. Ashoori and M. Shayegan, Determination of the Resistance across Incompressible Strips through Imaging of Charge Motion, Phys. Rev. B, vol. 65 (2002), pp. 121312
  21. B. Zheng, C. Lu, A. Makarovski, G. Finkelstein and J. Liu, Efficient CVD Growth of Single-Walled Carbon Nanotubes on Surface Using Carbon Monoxide Precursor, Nano Letters, vol. 2 no. 8 (August 2002), pp. 895
  22. S.H. Tessmer, G. Finkelstein, P.I. Glicofridis, and R.C. Ashoori, Modeling Subsurface Charge Accumulation Images of a Quantum Hall Liquid, Phys. Rev. B, vol. 66 (August 2002), pp. 125308
  23. Hao Yan, Sung Ha Park, Gleb Finkelstein, John H. Reif, Thomas H. LaBean, DNA-Templated Self-Assembly of Protein Arrays and Highly Conductive Nanowires, Science, vol. 301 (September 2003), pp. 1882
  24. S.H. Park, H. Yan, J.H. Reif, T.H. LaBean, and G. Finkelstein, Electronic nanostructures templated on self-assembled DNA scaffolds, Nanotechnology, vol. 15 (July 2004), pp. S525-S527 [pdf]  [abs]
  25. S.H. Park, R. Barish, H. Li, J.H. Reif, G. Finkelstein, H. Yan, and T.H. LaBean, Three-Helix Bundle DNA Tiles Self-Assemble into 2D Lattice or 1D Templates for Silver Nanowires., Nano Letters, vol. 5 (March, 2005), pp. 693  [abs]
  26. A. Makarovski, L. An, J. Liu, and G. Finkelstein, Persistent Orbitals Degeneracy in Carbon Nanotubes, Physical Review B, vol. 74 (2006), pp. 155431  [abs]
  27. S.H. Park, M.W. Prior, T.H. LaBean, and G. Finkelstein, Silver nanowires templated on DNA molecules, Applied Physics Letters, vol. 89 (2006), pp. 033901  [abs]
  28. M. Prior, A. Makarovski, and G. Finkelstein, Low-temperature conductive tip atomic force microscope for carbon nanotube probing and manipulation, Applied Physics Letters, vol. 91 (2007), pp. 053112
  29. A. Makarovski, A. Zhukov, J. Liu, and G. Finkelstein, SU(4) and SU(2) Kondo Effects in Carbon Nanotube Quantum Dots, Physical Review B, vol. 75 (2007), pp. R241407
  30. A. Makarovski, J. Liu, and G. Finkelstein, Evolution of Transport Regimes in Carbon Nanotube Quantum Dots, Physical Review Letters, vol. 99 (2007), pp. 066801
  31. A. Makarovski, A. Zhukov, J. Liu, and G. Finkelstein, Four-Probe Measurements of Carbon Nanotubes with Narrow Metal Contacts, Physical Review B, vol. 76 (2007), pp. R161405
  32. A. Makarovski, G. Finkelstein, Su(4) mixed valence regime in carbon nanotube quantum dots, Physica B, vol. 403 (2008), pp. 1555
  33. S.H. Park, G. Finkelstein, and T.H. Labean, Stepwise Self-Assembly of DNA Tile Lattices Using dsDNA Bridges, Journal of the American Chemical Society, vol. 130 no. 40-41 (2008)
  34. U.C. Coskun, H. Mebrahtu, P. Huang, J. Huang, A. Biasco, A. Makarovski, A. Lazarides, T. LaBean, and G. Finkelstein, Chemical patterning of silicon dioxide substrates for selective deposition of gold nanoparticles and fabrication of single-electron transistors, Applied Physics Letters, vol. 93 (2008), pp. 123101
  35. F.B. Anders, D.E. Logan, M.R. Galpin, and G. Finkelstein, Zero-Bias Conductance in Carbon Nanotube Quantum Dots, Physical Review Letters, vol. 100 (2008), pp. 086809
  36. Yu. Bomze, H. Mebrahtu, I. Borzenets, A. Makarovski, and G. Finkelstein, Resonant tunneling in a dissipative environment, Physical Review B, vol. 79 (2009), pp. 241402R [GetabsServlet]  [abs]
  37. Yu. Bomze, I. Borzenets, H. Mebrahtu, A. Makarovski, and G. Finkelstein, Two-stage Kondo effect and Kondo-box level spectroscopy in a carbon nanotube, Physical Review B, vol. 82 (2010), pp. 161411R  [abs]
  38. Mauricio Pilo-Pais, Sarah Goldberg, Enrique C. Samano, Thomas H. LaBean, and Gleb Finkelstein, Connecting the Nanodots: Programmable Nanofabrication of Fused Metal Shapes on DNA Templates, Nano Letters, vol. 11 (2011), pp. 3489-3492 [nl202066c], [doi]  [abs]
  39. Enrique C. Samano, Mauricio Pilo-Pais, Sarah Goldberg, Briana N. Vogen, Gleb Finkelstein, and Thomas H. LaBean, Self-assembling DNA templates for programmed artificial biomineralization, Soft Matter / Highlights, vol. 7 (2011), pp. 3240 [c0sm01318h], [doi]  [abs]
  40. Peng Li, Phillip M. Wu, Yuriy Bomze, Ivan V. Borzenets, Gleb Finkelstein, and A. M. Chang, Single Phase Slip Limited Switching Current in 1-Dimensional Superconducting Al Nanowires, Physical Review Letters, vol. 107 (2011), pp. 137004 [e137004], [doi]  [abs]
  41. I.V. Borzenets, U.C. Coskun, S.J. Jones and G. Finkelstein, Phase Diffusion in Graphene-Based Josephson Junctions, Physical Review Letters, vol. 107 (2011), pp. 137005 [e137005], [doi]  [abs]
  42. P. Li, P.M. Wu, Y. Bomze, I.V. Borzenets, G. Finkelstein and A.M. Chang, Retrapping current, self-heating, and hysteretic current-voltage characteristics in ultranarrow superconducting aluminum nanowires, Physical Review B, vol. 84 (2011), pp. 184508 [e184508], [doi]
  43. I. Borzenets, U.C. Coskun, H. Mebrahtu, and G. Finkelstein, Pb-graphene-Pb Josephson junctions: characterization in magnetic field, IEEE transactions on Applied Superconductivity, vol. 22 (2012), pp. 1800104, ISSN 1051-8223  [abs]
  44. I.V. Borzenets, I. Yoon, M.W. Prior, B.R. Donald, R.D. Mooney, and G. Finkelstein, Ultra-sharp metal and nanotube-based probes for applications in scanning microscopy and neural recording,, Journal of Applied Physics, vol. 111 no. 074703 (2012), pp. 074703, ISSN 0021-8979  [abs] [author's comments]
  45. Henok T. Mebrahtu, Ivan V. Borzenets, Dong E. Liu, Huaixiu Zheng, Yuriy V. Bomze, Alex I. Smirnov, Harold U. Baranger, and Gleb Finkelstein, Quantum phase transition in a resonant level coupled to interacting leads, Nature, vol. 488 (August 2, 2012), pp. 61 [html], [doi]  [abs]

Papers Submitted

  1. Inho Yoon, Kosuke Hamaguchi, Ivan V. Borzenets, Gleb Finkelstein, Richard Mooney, and Bruce R. Donald, Intracellular neural recording with pure carbon nanotube probes, Nature Nanotechnology (2012)  [abs]
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