Publication

Colloidal quantum dot solids: Nanoscale control of the electronic properties

Balázs, D. M. 2018 [Groningen]: University of Groningen. 118 p.

Research output: ThesisThesis fully internal (DIV)

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Documents

  • Title and contents

    Final publisher's version, 355 KB, PDF-document

  • Chapter 1

    Final publisher's version, 913 KB, PDF-document

  • Chapter 2

    Final publisher's version, 587 KB, PDF-document

  • Chapter 3

    Final publisher's version, 1 MB, PDF-document

  • Chapter 4

    Final publisher's version, 1 MB, PDF-document

    Embargo ends: 16/02/2019

  • Chapter 5

    Final publisher's version, 1 MB, PDF-document

  • Chapter 6

    Final publisher's version, 1 MB, PDF-document

    Embargo ends: 16/02/2019

  • Summary

    Final publisher's version, 16 KB, PDF-document

  • Samenvatting

    Final publisher's version, 103 KB, PDF-document

  • Acknowledgement

    Final publisher's version, 110 KB, PDF-document

  • Complete thesis

    Final publisher's version, 6 MB, PDF-document

    Embargo ends: 16/02/2019

  • Propositions

    Final publisher's version, 12 KB, PDF-document

  • Dániel Máté Balázs
The interest in CQDs stems from the prospects of fully tunable electronic and optical properties and easy fabrication. Both of these features are advantageous for applications in solar cells and optoelectronic devices. However, for a very long time, the prospects remained unexploited in lack of deep knowledge on the chemistry and physics of the materials. Due to the large surface of the nanocrystals, different processes become dominant compared in comparison with bulk samples, and different characterization and treatment methods had to be developed to test and control the relevant properties. The knowledge in colloid chemistry had to be expanded making it suitable for the fabrication of highly pure, electronic-grade materials. This thesis demonstrates several ways of controlling the electronic properties of CQD arrays, the so-called CQD solids. These materials show much larger tunability of the electronic, electrical and optical properties than the bulk semiconductors, and show unique possibilities. Several questions and challenges are still open, but the results suggest that researchers will soon be in full control of the electronic properties of these materials, enabling commercial applications. The commercialization of CQDs solids in niche applications based on the tunable properties will certainly bring a new era in energy harvesting and (opto)electronics.
Original languageEnglish
QualificationDoctor of Philosophy
Awarding Institution
Supervisors/Advisors
  • Loi, Maria, Supervisor
  • Kovalenko, Maksym V., Co-supervisor, External person
  • Noheda Pinuaga, Beatriz, Assessment committee
  • Facchetti, A., Assessment committee, External person
  • Hanrath, T., Assessment committee, External person
Award date16-Feb-2018
Place of Publication[Groningen]
Publisher
Print ISBNs978-94-034-0365-6
Electronic ISBNs978-94-034-0364-9
StatePublished - 2018

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