PhD Position in Chemical, materials and energy technology, Early stage researcher

Updated: 3 months ago
Job Type: FullTime
Deadline: 30 Jun 2022

Tallinn University of Technology, School of Engineering, Department of Materials and Environmental Technology offers a 4-year PhD position in the field of chemical, materials and energy technology.

Proposed doctoral thesis topic: "Development of antimony chalcogenide semiconductor alloys for innovative photovoltaic and optoelectronic applications".

Supervisor: Senior Researcher Nicolae Spalatu and Professor Jon Major

Abstract

The overall goal of the project is to develop and optimize the non-toxic and earth-abundant Sb-chalcogenide absorber alloys for efficient thin film solar cells by using cost-effective and mass production close-spaced sublimation (CSS) technique. The project addresses the following research questions: What will be the most suitable processing approaches for the synthesis of these materials using low temperature, low cost and highly scalable techniques? How a semiconductor alloy system would allow tailoring the bandgap (from 1.1 eV to 1.8 eV) and current-voltage tunability required to design efficient thin-film solar cell configurations? How systematic material and device characterization can provide understanding of the physico-chemistry of the processes, properties of the materials and solar cells, and deliver insights for further optimization?

Description

The PhD candidate's doctoral study and research work will be a joint collaboration and supervision at Tallinn University of Technology – TalTech, Tallinn, Estonia and University of Liverpool – UOL, Liverpool, UK. The applicant will have a unique opportunity to carry out research work at TalTech and UOL.

The candidate will carry out a multidisciplinary scientific activity in the framework of the projects PSG689 and PRG627 and European Union's H2020 programme under the ERA Chair project 5GSOLAR grant agreement No 952509, on the development and characterization of thin films and solar cell devices based on emerging antimony chalcogenides Sb2(S,Se)3 PV absorber materials. The PhD student will be involved in all the solar cells processing stages. This will include the fabrication of absorber layers by physical techniques such as CSS, vapor transport deposition (VTD) and vacuum thermal evaporation (VTE) on different substrates: glass, glass/TCOs, glass/Mo, glass/TCOs/window layer. Various CSS deposition parameters (substrate and source temperature, growth pressure) and post-deposition treatments (in tube-furnaces, hot-plates) will be optimized for obtaining single-phase, high-crystallinity, dense, and homogeneous absorber layers with suitable optoelectronic properties and proper thicknesses for thin film solar cell applications. The PhD student will also fabricate different window layers such as CdS, by CSS and chemical bath deposition methods (CBD), and TiO2 by chemical spray pyrolysis (CSP) and will identify the optimal window/buffer partner in solar cells. The student will prepare the photovoltaic solar cells based on these materials, define the ad hoc selective contacts for efficient charge extraction and characterize the materials properties and solar cells output parameters.

The proposed research project will help the student to acquire a vast range of competences and skills in developing and design thin film solar cells, will strengthen the researcher's ability to publish in international journals, as well as broadening the network of international contacts with companies and other research groups in the PV field from EU and the world at large through the participation at different international conferences.

Responsibilities and (foreseen) tasks

  • Screening and optimization of deposition processes of antimony chalcogenide-based absorbers, to create well-oriented, continuous, uniform films on appropriate substrates
  • Optimization of deposition processes for Sb2Se3 and related alloys (Sb2(S,Se)3 -Bi2(S,Se)3 alloys) with controlled tuned bandgap for efficient thin film solar cells
  • Map the key technological parameters of the used experimental approaches
  • Identification of optimal buffer layers and electron/hole selective transport layers for efficient cell device architectures.
  • Development and optimization of thin film solar cells based on antimony chalcogenide-based absorbers
  • Characterization of materials and solar cell devices using various dedicated characterization techniques.
  • Analysis of the research data, preparing reports, presentation at conferences (poster, oral talk), write research papers
  • Contribute to the organization and dissemination of research and practitioner workshops where project findings are presented

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