TITLE:
Semiconductor Fluorinated Carbon Nanotube as a Low Voltage Current Amplifier Acoustic Device
AUTHORS:
D. Sakyi-Arthur, S. Y. Mensah, K. W. Adu, K. A. Dompreh, R. Edziah, N. Mensah, C. Jebuni-Adanu
KEYWORDS:
Carbon Nanotube, Fluorinated, Acoustoelectric Effect, Low Voltage, Acoustic Device
JOURNAL NAME:
World Journal of Condensed Matter Physics,
Vol.10 No.1,
February
12,
2020
ABSTRACT: Acoustoelectric effect (AE) in a non-degenerate fluorinated single walled carbon nanotube (FSWCNT) semiconductor was carried out using a tractable analytical approach in the hypersound regime , where q is the acoustic wavenumber and is the electron mean-free path. In the presence of an external electric field, a strong nonlinear dependence of the normalized AE current density , on (is the electron drift velocity and is the speed of sound in the medium) was observed and depends on the acoustic wave frequency, , wavenumber q, temperature T and the electron-phonon interactions parameter, . When , decreases to a resonance minimum and increases again, where the FSWCNT is said to be amplifying the current. Conversely, when , rises to a maximum and starts to decrease, similar to the observed behaviour in negative differential conductivity which is a consequence of Bragg’s reflection at the band edges at T=300K. However, FSWCNT will offer the potential for room temperature application as an acoustic switch or transistor and also as a material for ultrasound current source density imaging (UCSDI) and AE hydrophone devices in biomedical engineering. Moreover, our results prove the feasibility of implementing chip-scale non-reciprocal acoustic devices in an FSWCNT platform through acoustoelectric amplification.