Performance of broken gap MoO3/ZnS heterojunctions as abrupt electronic switches, MOSFETs, negative capacitance FETs and bandpass filters suitable for 3G/4G technologies
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Dosyalar
Tarih
2022
Yazarlar
Dergi Başlığı
Dergi ISSN
Cilt Başlığı
Yayıncı
Springer
Erişim Hakkı
info:eu-repo/semantics/closedAccess
Özet
Herein, MoO3/ZnS broken gap heterojunction devices are fabricated by thermal evaporation under a vacuum pressure of 10?5 mbar. The devices are characterized by X-ray difraction, energy dispersive X-ray spectroscopy, ultraviolet-visible light spectroscopy and impedance spectroscopy. Three channels composed of one Schottky arm (Ag/ZnS) and two ohmic arms (Au, C)/ZnS are formed on the epilayer of the amorphous (MoO3)/polycrystalline (ZnS) heterojunctions. Optical analyses show that the broken gap devices exhibit valance and conduction band ofsets of 2.6 eV and 2.8 eV, respectively. Practical tests on the devices show that they can behave as abrupt electronic switches with biasing independent current rectifcation ratios of 2.7 × 103 at an applied voltage of 0.14 V. The Au/MoO3/ZnS/Ag channels displayed metal oxide feld efect transistor characteristics as they are efective in the frequency domain of 3.0–20 MHz. In addition to its performance as a negative capacitance FET, the broken gap device can be employed as a radiowave/microwave cavity with notch frequency ( fn) values of 0.86 GHz, 1.16 GHz, 1.69 GHz and 1.75 GHz. The ideality of the resonators was observed at 1.16 GHz for the Au/MoO3/ZnS/C channel. This channel displayed bandpass flter characteristics with voltage standing wave ratios of 1.0 and return loss values of 40.2 dBs.
Açıklama
Anahtar Kelimeler
MoO3/ZnS Heterojunction, Band Offsets, Microwave Resonators, Negative Capacitance
Kaynak
Journal of Electronic Materials
WoS Q Değeri
Q3
Scopus Q Değeri
N/A
Cilt
Sayı
Künye
Qasrawi, A.F., Yaseen, N.M.A. Performance of Broken Gap MoO3/ZnS Heterojunctions as Abrupt Electronic Switches, MOSFETs, Negative Capacitance FETs and Bandpass Filters Suitable for 3G/4G Technologies. J. Electron. Mater. (2022).