Abstract
Herein, cadmium bromide thin film devices are designed for possible use in communication technology. The 1.0 μm thin layer of CdBr2 is sandwiched between two Au (1.0 μm thick) layers using the thermal evaporation technique under a vacuum pressure of 10-5 mbar. The Au/CdBr2/Au devices are structurally morphologically and electrically characterized. It is observed that the hexagonal cadmium bromide exhibits large lattice mismatches with cubic Au substrates. The randomly distributed nano- rod like grains is accompanied with average surface roughness of ~26 nm. When an ac signal of low amplitude is imposed between the terminals of the Au/CdBr2/Au devices, a negative capacitance effect in the frequency domain of 10-1800 MHz is observed. In addition, analysis of the impedance spectra in the same domain has shown that the device behaves as band pass/stop filters suitable for 4G technology. The microwave based standard analysis of the Au/CdBr2/Au band filters have shown that it displays a notch (fco) frequency of 2.0 GHz. The cutoff frequency at fco reaches 7.86 GHz. The features of the Au/CdBr2/Au devices nominate it for use as microwave resonators and as negative capacitance devices suitable for; 4G technology, noise reduction and for parasitic capacitance cancellation.
Highlights
Cadmium bromide compound capture the interest of researchers due to its nature of applications
Ag doped CdBr2 is mentioned being sensitive to the high energy photons like X-rays and ultra-violets. Such property of the material is advantageous as it leads to the enhancement of the optical density in CdBr2 during chemical reactions[3]
As confirmed by the hot probe technique, cadmium bromide thin films coated onto glass substrates reveal p − type semiconductor characteristics
Summary
Cadmium bromide compound capture the interest of researchers due to its nature of applications. It has great potential for lasing applications[1]. This compound is used for the enhancement of the efficiency of CdTe solar cells[2]. Ag doped CdBr2 is mentioned being sensitive to the high energy photons like X-rays and ultra-violets. Such property of the material is advantageous as it leads to the enhancement of the optical density in CdBr2 during chemical reactions[3]
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