Publications – Low Dimensional Electronics Lab

52. Evidence of a two-component order parameter in 4Hb-TaS2 in the Little-Parks effect,
Avior Almoalem, Irena Feldman, Michael Shlafman, Yuval E. Yaish, Mark H. Fischer, Michael Moshe, Jonathan Ruhman, and Amit Kanigel, arXiv:2208.13798 (2022).

51. DC Signature of snap-through bi-stability in carbon nanotube resonators,
Sharon Rechnitz, Tal Tabachnik, Shlomo Shlafman, Michael Shlafman, Yuval E. Yaish, Nano Letters, 22, 7304; https://doi.org/10.1021/acs.nanolett.2c01187 (2022).

50. Theoretical modelling of arch-shaped carbon nanotube resonators exhibiting Euler-Bernoulli snap-through bi-stability,
Sharon Rechnitz, Shlomo Shlafman, Tal Tabachnik, Michael Shlafman, Yuval E. Yaish, arXiv:2203.02738 (2022).

49. Mode coupling, bi-stability, and spectral broadening in buckled nanotube resonators,
S. Rechnitz, T. Tabachnik, M. Shlafman, S. Shlafman, and Y. E. Yaish, Nature Communications, 13, 5900; https://doi.org/10.1038/s41467-022-33440-4 (2022).
Featured in a Nature Communications Editors’ Highlights webpage: Devices collection of Nature Portfolio on https://lnkd.in/eTaitiFJ

48. Dynamics of light-induced charge transfer between carbon nanotube and CdSe/CdS nanocrystals,
G. Zeevi, J. Dehnel, A. K. Budnik, Y. Milyutin, G. Ankonina, H. Haick, E. Lifshitz, and Y. E. Yaish, Nano Futures, doi: 10.1088/2399-1984/ac3ccc (2021).

47. PN junction and band to band tunneling in carbon nanotube transistors at room temperature,
G. Zeevi, A. Razin, Y. E. Yaish, Nanotechnology, 32, 335202 (2021).

46. Non-volatile memory and negative photoconductivity in a metal-insulator-semiconductor diode with embedded Co nanoparticles,
V. Mikhelashvili, G. Atiya, Y. Kauﬀmann, Y. Shneider, G. Ankonina, G. Zeevi, Y. E. Yaish,
A. Capua, and G. Eisenstein, Journal of Applied Physics, 123, 224506 (2018).

45. Multicolor Spectral-Speciﬁc Silicon Nanodetectors based on Molecularly Embedded Nanowires,
S. Leﬂer, R. Vizel, E. Yeor, E. Granot, O. Heiﬂer, M. Kwiat, V. Krivitsky, M. Weil, Y. E. Yaish, and F. Patolsky, Nano Letters, 18, 190 (2018).

44. Stress-Induced Resistive Switching in Pt/HfO₂ /Ti Devices,
G. Zeevi, A. Katsman, and Y. E. Yaish, Journal of Electronic Materials, 47, 1505 (2017).

43. Kinetics modeling of nanoparticles growth on and evaporation off nanotubes,
V. Privman, V. Gorshkov, and Y. E. Yaish, Journal of Applied Physics, 121, 014301 (2017).

42. Automated circuit fabrication and direct characterization of carbon nanotube vibrations,
G. Zeevi*, M. Shlafman*, T. Tabachnik, Z. Rogachevsky, S. Rechnitz, I. Goldshtein, S. Shlafman, N. Gordon, G. Alchanati, M. Itzhak, Y. Moshe, E.M. Hajaj, H. Nir, Y. Milyutin, T.Y. Izraeli, A. Razin, O. Shtempluck, V. Kotchtakov, and Y. E. Yaish, Nature Communications, 7:12153 (2016).
Featured Image Nat. Comm. July 2016

41. Self Aligned Hysteresis Free Carbon Nanotube Field-Effect Transistors,
M. Shlafman, T. Tabachnik, O. Shtempluck, A. Razin, V. Kotchtakov and Y. E. Yaish, Applied Physics Letters, 108, 163104 (2016).

40. Stress induced vacancy clustering mechanism of resistive switching in hafnium oxides,
A. Katsman, G. Zeevi, and Y. E. Yaish, MRS Advances, 1, 349 (2016)

39. Analysis of Youngs modulus, initial stress, and crystal orientation of doubly clamped nanowire beams,
Y. E. Yaish, Y. Calahorra, O. Shtempluck, and V. Kotchtakov, Journal of Applied Physics, 117, 164311 (2015).

38. Visualization of electronic density,
B. Grosso, V. R. Cooper, P. Pine, A. Hashibon, Y. E. Yaish, and J. Adler, Computer Physics Communications, 195, 1 (2015).

37. Youngs modulus, residual stress, and crystal orientation of doubly clamped silicon nanowire beams,
Y. Calahorra, O. Shtempluck, V. Kotchtakov, and Y. E. Yaish, Nano Letters, doi:10.1021/nl5047939 (2015).

36. Formation and evolution of nickel silicides in silicon nanowires,
A. Katsman, M. Beregovsky, and Y. E. Yaish, IEEE Transactions on Electron Devices, 61, 3363 (2014).

35. Vibrational analysis of thermal oscillations of single-walled carbon nanotubes under axial strain,
P. Pine, Y. E. Yaish, J. Adler, Physical Review B, 89, 115405 (2014).

34. Formation and Evolution of Nickel Silicides in Silicon Nanowires,
A. Katsman, M. Beregovsky, Y. E. Yaish, Nano Studies, 8, 139 (2013).

33. Origin of Hysteresis in Carbon Nanotube Field-Effect Transistors,
Yael Pascal-Levi, Evgeny Shifman, Manish Pal-Chowdhury, Itshak Kalifa, Ida Sivan, Tsvika Rabkin, and Yuval E. Yaish, MRS Proceedings, 1659, 119 (2013).

32. Chemical Potential of Inhomogeneous Single Layer Graphene,
E. M. Hajaj, O. Shtempluk, A. Razin, V. Kochetkov, and Y. E. Yaish, Physical Review B, 88, 045128 (2013).

31. Evolution of Nickel Silicide Intrusions in Silicon Nanowires during Thermal Cycling,
A. Katsman, M. Beregovsky, and Y. E. Yaish, Journal of Applied Physics, 113, 084305 (2013).

30. Gate-Induced Modiﬁcation of Water Adsorption on the Gate Dielectric of Carbon Nanotube Field-Effect Transistors,
Y. Pascal-Levy, E. Shifman, M. Pal-Chowdhury, E. Hajaj, O.Shtempluk, A. Razin, V. Kochetkov, and Y. E. Yaish, ChemPhysChem, 13, 4202 (2012).

29. Diffusion Formation of Nickel Silicide Contacts in SiNWs,
M. Beregovsky, A. Katsman, E. M. Hajaj, and Y. E. Yaish, Solid State Electronics, 80, 110 (2012).

28. Water Assisted Gate Induced Temporal Surface Charge Distribution Probed by Electrostatic Force Microscopy,
Y. Pascal-Levy, E. Shifman, I. Sivan, I. Kalifa, M. Pal-Chowdhury, O. Shtempluk, A. Razin, Kochetkov, and Y. E. Yaish, Journal of Applied Physics, 112, 084329 (2012).

27. Water Assisted Mobile Charge Induced Screening and Origin of Hysteresis in Carbon Nanotube Field-Effect Transistors,
Y. Pascal-Levy, E. Shifman, M. Pal-Chowdhury, I. Kalifa, T.Rabkin, O. Shtempluk, A. Razin, V. Kochetkov, and Y. E. Yaish, Physical Review B, 86, 115444 (2012).

26. Simulations of nanosensors based on single walled carbon nanotubes,
P. Pine, Y. E. Yaish, J. Adler, The Journal of Physics: Conference Series, 402, 012002 (2012).

25. High Performance Horizontal Gate All Around Silicon nanowire Field Effect Transistor,
O. Shirak, O. Shtempluk, V. Kochetkov, G. Bahir, and Y. E. Yaish, Nanotechnology, 23, 395202 (2012).

24. The affect of boundary conditions on the vibrations of armchair, zigzag and chiral single walled carbon nanotubes,
P. Pine, Y. E. Yaish, J. Adler, Journal of Applied Physics, 110, 124311 (2011).

23. From Contact to Diffusion Controlled Growth of Nickel Silicides in Silicon Nanowires,
A. Katsman, Y. E. Yaish, M. Beregovsky, Defect and Diffusion Forum, 323-325, 427 (2011).

22. Thermal oscillations of structurally distinct single-walled carbon nanotubes,
P. Pine, Y. E. Yaish, J. Adler, Physical Review B, 83, 155410 (2011).

21. Diffusion Instability and Tapering of Nickel Silicide Intrusions in Silicon Nanowires,
A. Katsman, M. Beregovsky, Y. E. Yaish, MRS Proceedings, 1408, 141 (2011).

20. Simulation and Vibrational Analysis of Thermal Oscillations of Single Walled Carbon Nanotubes,
P. Pine, Y. E. Yaish, J. Adler, Physical Review B, 83, 155410 (2011).

19. Kinetics of Nickel Silicides Growth in Silicon Nanowires: From Linear to Square Root Growth,
Y. E. Yaish, M. Beregovsky, A. Katsman, Journal of Applied Physics, 109, 094303 (2011).

18. Accurate carrier-type determination of Non-Homogenously Doped Diamond,
N. Yom-Tov, C. Saguy, A. Bolker, R. Kalish, Y. E. Yaish, Journal of Applied Physics, 108 (4), 043711 (2010).

17. Surface diffusion controlled of Nickel Silicides in Silicon Nanowires,
A. Katsman, Y. E. Yaish, E. Rabkin, and M. Beregovsky, Journal of Electronic material, 39, 365 (2010).

16. Visualizing Nanodiamond and Nanotubes with AViz,
J. Adler, Y. Gershon, T. Mutat, A. Sorkin, E. Warszawski, R. Kalish, and Y. E. Yaish, Computer Simulation Studies in Condensed-Matter Physics XIX, 123, 56–60 (2009).

15. Coulomb oscillations and Hall effect in quasi–2D graphite quantum dots,
J. S. Bunch, Y. Yaish, M. Brink, K. Bolotin, and P. L. McEuen, Nano Lett. 5, 287 (2005).

14. A tunable carbon nanotube electromechanical oscillator,
V. Sazonova, Y. Yaish, H. Ustunel, D. Roundy, T. A. Arias, and P. L. McEuen, Nature, 431, 284 (2004).

13. Determination of electron orbital magnetic moments in carbon nanotubes,
E. D. Minot, Y. Yaish, V. Sazonova, and P. L. McEuen, Nature, 428, 536 (2004).

12. Electron-phonon scattering in metallic single-walled carbon nanotubes,
J. Y. Park, S. Rosenblatt, Y. Yaish, V. Sazonova, H. Ustunel, S. Braig, T. A. Arias, P. W. Brouwer, and P. L. McEuen, Nano Lett. 4, 517 (2004).

11. Electrical nanoprobing of semiconducting carbon nanotubes using an atomic force microscope,
Y. Yaish, J. Y. Park, S. Rosenblatt, V. Sazonova, M. Brink, and P. L. McEuen, Phys. Rev. Lett. 92 (2004).

10. Wiring up single molecules,
J. W. Park, A. N. Pasupathy, J. I. Goldsmith, A. V. Soldatov, C. Chang, Y. Yaish, J. P. Sethna, H. D. Abruna, D. C. Ralph, and P. L. McEuen, Thin Solid Films” 438, 457 (2003).

9. Thermodynamic spin magnetization of strongly correlated two-dimensional electrons in a silicon inversion layer,
O. Prus, Y. Yaish, M. Reznikov, U. Sivan, and V. Pudalov, Phys. Rev. B 67 (2003).

Tuning carbon nanotube band gaps with strain,
E. D. Minot, Y. Yaish, V. Sazonova, J. Y. Park, M. Brink, and P. L. McEuen, Phys. Rev. Lett. 90 (2003).

8. The thermodynamic spin magnetization of strongly correlated two-dimensional electrons in a silicon inversion layer,
O. Prus, Y. Yaish, M. Reznikov, U. Sivan, and V. Pudalov, Physics of Semiconductors 2002, Proceedings institute of physics conference series, 171, 185 (2003).

7. High performance electrolyte gated carbon nanotube transistors,
S. Rosenblatt, Y. Yaish, J. Park, J. Gore, V. Sazonova, and P. L. McEuen, Nano Lett. 2, 869 (2002).

6. Coulomb blockade and the Kondo effect in single-atom transistors,
J. Park, A. N. Pasupathy, J. I. Goldsmith, C. Chang, Y. Yaish, J. R. Petta, M. Rinkoski, J. P. Sethna, H. D. Abruna, P. L. McEuen, and D. C. Ralph, Nature 417, 722 (2002).

5. Electrical cutting and nicking of carbon nanotubes using an atomic force
J. Y. Park, Y. Yaish, M. Brink, S. Rosenblatt, and P. L. McEuen, Appl. Phys. Lett. 80, 4446 (2002).

4. On the relation between interband scattering and metallic behavior of two dimensional holes in GaAs/AlGaAs,
U. Sivan, Y. Yaish, O. Prus, S. Shapira, I. Ussishkin, E. Buchstab, G. Ben Yoseph, and A. Stern, Electronic Correlations: From Meso- to Nano-Physics, 181 (2001).

3. Two band transport and the question of a metal-insulator transition in GaAs/GaAlAs two dimensional holes,
Yuval Yaish, Oleg Prus, Evgeny Buchstab, Gidi Ben Yoseph, Uri Sivan, Iddo Ussishkin, Ady Stern, arXiv:cond-mat/0109469 (2001).

2. In-plane magnetization of electrons in a silicon inversion layer Electronic Correlations,
M. Reznikov, O. Prus, Y. Yaish, U. Sivan, and V. Pudalov, Electronic Correlations: From Meso- to Nano-Physics, 201 (2001).

1. Interband scattering and the ”metallic phase” of two-dimensional holes in GaAs/AlGaAs,
Y. Yaish, O. Prus, E. Buchstab, S. Shapira, G. Ben Yoseph, U. Sivan, and A. Stern, Phys. Rev. Lett. 84, 4954 (2000).