Investigation of the Structural and Optoelectronic Properties of the Se/Ga<sub>2< Heterojunctions

No Thumbnail Available

Date

2018

Journal Title

Journal ISSN

Volume Title

Publisher

Elsevier Science Sa

Open Access Color

OpenAIRE Downloads

OpenAIRE Views

Research Projects

Organizational Units

Organizational Unit
Department of Electrical & Electronics Engineering
Department of Electrical and Electronics Engineering (EE) offers solid graduate education and research program. Our Department is known for its student-centered and practice-oriented education. We are devoted to provide an exceptional educational experience to our students and prepare them for the highest personal and professional accomplishments. The advanced teaching and research laboratories are designed to educate the future workforce and meet the challenges of current technologies. The faculty's research activities are high voltage, electrical machinery, power systems, signal and image processing and photonics. Our students have exciting opportunities to participate in our department's research projects as well as in various activities sponsored by TUBİTAK, and other professional societies. European Remote Radio Laboratory project, which provides internet-access to our laboratories, has been accomplished under the leadership of our department with contributions from several European institutions.

Journal Issue

Events

Abstract

In the current study, the structural and optical properties of the Se/Ga2S3 heterojunctions are investigated by means of X-ray diffraction and ultraviolet-visible light spectrophotometry techniques. The optical interface which was prepared by the physical vapor deposition technique, comprises a polycrystalline orthorhombic selenium layer of thickness of 500 nm coated with amorphous layer of 200 nm thick Ga2S3. The top layer is observed to cause yield stress on the Se layer leading to strained type interface. Optically, the evaporation of Ga2S3 onto selenium blue shifted the energy band gap of Se. The conduction and valence band offsets exhibited values of 1.28 and 0.20 eV, respectively. On the other hand, the optical conductivity spectra which were studied and modeled by the Drude-Lorentz approach in the terahertz frequency domain of 275-675 THz revealed enhanced optical conduction parameters. The use of Se as substrate to Ga2S3 enhanced the drift mobility and plasmon frequency of the Ga2S3. The value of the drift mobility reached 64 cm(2)/Vs at plasmon frequency of 2.04 GHz. In addition, the Se/Ga2S3 interface are observed to exhibit high biasing dependent photosensitivity to visible light irradiation. Such properties of this interface nominate it for use in optoelectronics including visible light communications. (C) 2018 Elsevier B.V. All rights reserved.

Description

Qasrawi, Atef Fayez/0000-0001-8193-6975

Keywords

Se, Ga2S3, X-ray, Optical conductivity, Photocurrent, Visible light communications

Turkish CoHE Thesis Center URL

Fields of Science

Citation

WoS Q

Q1

Scopus Q

Source

Volume

769

Issue

Start Page

78

End Page

82

Collections