Single Electron Transistors as Position Detectors for Nano Electomechanical Systems
DOI:
https://doi.org/10.48165/Keywords:
Detector, resonator, electromechanical system, current blockade, mechanical instability, compression force, buckling, oscillator, phase transitionAbstract
We have studied the single electron transistors are extremely sensitive devices as position detectors for nanoelectromechanical systems. Suspended carbon nanotubes have observed a reduction of the mechanical resonance frequency of the fundamental bending at low bias voltages near the degenerate region. This effect is a precursor of the mechanical instability and thus of the current blockade. We have found that the consequence of a capacitive electromechanical coupling in a suspended single electron transistor when the supporting beam is brought close to the Euler buckling instability by a lateral compression force. The result is that the low bias current blockade originating from the coupling between the electronic degrees of freedom and the classical resonator enhanced by several orders of magnitude in the vicinity of the instability. These results are a direct consequence of the continuous nature of the Eular buckling instability and the associated critical slowing down of the fundamental bending mode of the beam at the instability. Our results frequently have close and instructive analogies with mean field theory of second order phase transitions. In order to increase energy, we can increase the electrostating coupling between the oscillator and the single electron transistor, since energy depends quadratically on electrostatic force and a large change in the gate voltage is found when electrons tunnel. In the way of reducing oscillator spring constant in a controlled manner is to operate a doubly clamped beam subject to a lateral compression force. Under the action of the lateral compression force the system exhibited a continuous transition from a flat to a blockade state, while the fundamental bending mode became softer as approached the mechanical instability. We have found that near the buckling instability the current blockade induced by the mechanical resonator is strongly enhanced, rendering this effect. The obtained results were found in good agreement with previously obtained results.
References
. Knobel. R. G. and Cleland. A. N (2002), Appl. Phys. Lett. 81, 2258.
. Knobel. R. G and Cleland. A. N (2003), Nature (London), 424, 291.
. Armour. A. D, Blencowe. M. P and Schwab. K. C. (2002), Phys. Rev. Lett. 88, 148301. [4]. Gorelck. L. Y, Isacsson. A, Voinova. M. V, Kasemo. B, Shekhar. R. I and Jonson. M, (1998), Phys. Rev. Lett. 80, 4526.
. Pistolesi. F and Fazio. R, (2005), Phys. Rev. Lett. 94, 036806.
. Usmani. O, Blanter. Y. M and Nazarov. Y. V, (2007), Phys. Rev. B, 75, 195312. [7]. Pistolesi. F and Labarthe (2007), Phys. Rev. B, 76, 165317.
. Koch. J and Von Oppen. F, (2005), Phys. Rev. Lett. 94, 206804.
. Koch. J, Von Oppen. F and Andreev. A. V. (2006), Phys. Rev. B, 74, 205438. [10]. Leturcq. R, Stampfer. C, Inderbitzin, Durrer. L, Heirold. C, Mariani. E, Schultz. M. G, Von Oppen. F and Ensslin. K, (2009), Nat. Phys., 5, 327.
. Mozyrsky. D, Hastings. M. B and Martin. I, (2006), Phys. Rev. B, 73, 035104. [12]. Pistolesi. F, Blanter. Y. M and Martin. I, (2008), Phys. Rev. B, 78, 085127.
. Armor. A. D, Blencowe. M. P and Zhang. Y, (2004), Phys. Rev. B, 69, 125313. [14]. Kirton. P. G and Armour. A. D, (2013), Phys. Rev. B, 87, 155407.
. Blencowe. M. P, (2005), Contemp (2005), Phys. 46, 249.
. Piovano. G, Cavaliere. F, Paladino. E and Sassetti. M, (2011), Phys. Rev. B, 83, 24311. [17]. Nocera. A, Derroni. C. A, Marigliano Ramaglia. V and Cataudella. V, (2012), Phys. Rev. B, 86, 035420.
. Meerwaldt. H. B, Labadze. G, Schneider. B. H, Taspinar. A, Blanter. Y. M, Vanderznat. H. S. J and Steele. G. A, (2012), Phys. Rev. B, 86, 115454.
. Weick. G, Von Oppen. F and Pistolesi. F, (2011), Phys. Rev. B, 83, 035420.
. Ferry. D. K, Goodnick. S. M. and Bird. J. P, (2009), Transport in Nano structures, 2nd ed (Cambridge University Press, Cambridge, U. K.)
. Bruggemann. J, Weick. G, Pistolesi. F and Von. Oppen. F, (2012), Phys. Rev. B, 85, 125441. [22]. Camalet. S, Kohler. S and Hanggi. P, (2004), Phys. Rev. B, 70, 155326.
. Alam Md. Nausad and Aparajita, (2020), Bulletin of Pure and Applied Sciences- Physics 39D, no-1, 39.
. Giri Ashutosh Kumar, Kumar Pankaj and Singh Parmendra Ranjan, (2017), Bulletin of Pure and Applied Sciences- Physics, 36D, no-2, 136.