Design and characterization of (Al, C)/p-Ge/p-BN/C isotype resonant electronic devices

Garni, S.E. Al; Qasrawi, A.F.

doi:10.1002/pssa.201532013

Cited by 7 publications

(5 citation statements)

References 18 publications

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“…PVCR of 6.2 is reported for AlSb/GaInAsSb quantum well RTD's 16 . PVCR of 62 was also observed for Ge/BN interfaces 17 . These types of devices occupy large space in communication technology as they are sources of negative conductance which is a main factor in Gigahertz/ terahertz communication technology 14,18,19 .…”

Section: Resultsmentioning

confidence: 72%

Ag/SeO2/C Avalanche Type Resonant Tunneling Schottky Barriers

2022

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Herein, the design and characterization of Ag/SeO 2 /C avalanche type resonant tunneling devices are reported. Thin pellets of SeO 2 nano-powders pressed under hydraulic pressure of 1.0 MPa which is used as the active material are characterized. They showed tetragonal structure refereeing to space group of 2 4 mbc P and lattice parameters of a b = = 7.866 Å and c = 5.336 Å. The current-voltage characteristic curves have shown that SeO 2 can perform as active media to produce resonant tunneling diodes when forward biased and as avalanche type diode when reverse biased. The peak to valley current ratios of these diodes reached 18.3. In addition, the impedance spectroscopy measurements have shown that the device works in the low impedance mode when operated in the microwave range of frequency near 1.50 GHz. Negative conductance effect is observed in that frequency domain. The features of the Ag/SeO 2 /C nominate them for use as signal amplifiers and microwave oscillators.

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Section: Resultsmentioning

confidence: 72%

Ag/SeO2/C Avalanche Type Resonant Tunneling Schottky Barriers

2022

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“…As the metal work functions of the gold and carbon are 5.34 eV and 5.1 eV, respectively, and the BN is of p-type (as determined by the hot probe technique) with barrier height of 9.64 eV [9], the Au/BN represent a Schottky diode and the C/BN represent another Schottky diode. The presentation of both Schottky-type metals on the front and rare part of the BN makes the Au/BN/C device structure represent a metalsemiconductor-metal (MSM) back-to-back Schottky device.…”

Section: Resultsmentioning

confidence: 99%

“…The paste, which was prepared at the Alfa Aesar chemical firm (product number 043773) included a typical solution of BN nanopowders (50%) solved in 40% water and 10% aluminum phosphate (AlPO4). Further details about the properties of this material were previously given [9]. The BN liquid was poured over the gold substrate, shacked gently, and left to dry for 24 hours.…”

Section: Methodsmentioning

confidence: 99%

Microwave Impedance Spectroscopy and Temperature Effects on the Electrical Properties of Au/BN/C Interfaces

Khanfar¹,

Qasrawi²,

Ghannam³

2017

Active and Passive Electronic Components

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In the current study, an Au/BN/C microwave back-to-back Schottky device is designed and characterized. The device morphology and roughness were evaluated by means of scanning electron and atomic force microscopy. As verified by the Richardson–Schottky current conduction transport mechanism which is well fitted to the experimental data, the temperature dependence of the current-voltage characteristics of the devices is dominated by the electric field assisted thermionic emission of charge carriers over a barrier height of ~0.87 eV and depletion region width of ~1.1 μm. Both the depletion width and barrier height followed an increasing trend with increasing temperature. On the other hand, the alternating current conductivity analysis which was carried out in the frequency range of 100–1400 MHz revealed the domination of the phonon assisted quantum mechanical tunneling (hopping) of charge carriers through correlated barriers (CBH). In addition, the impedance and power spectral studies carried out in the gigahertz-frequency domain revealed a resonance-antiresonance feature at frequency of ~1.6 GHz. The microwave power spectra of this device revealed an ideal band stop filter of notch frequency of ~1.6 GHz. The ac signal analysis of this device displays promising characteristics for using this device as wave traps.

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“…First of all, it is reasonable to consider the roles of BN and Pd on the sensing behavior of ZnO NWs. In BN coated ZnO as shown in Figure 8a, since a thin (5±2 nm) BN film is coated around the ZnO NWs, due to the work function difference between ZnO and BN, 84,85 in intimate contact between ZnO and BN electrons from ZnO are transferred to BN and Schottcky barriers (height of 5.52 eV) will be formed on the interfaces between ZnO and BN (Figure S12a), which can expand the electron depletion layer relative to pristine ZnO NWs. Upon…”

Section: Sensing Mechanismsmentioning

confidence: 99%