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Remarkable Electrical Conductivity Increase and Pure Metallic Properties from Semiconducting Colloidal Nanocrystals by Cation Exchange for Solution-Processable Optoelectronic Applications.

Sang Eun YoonYongjin KimHyeongjun KimHyo-Geun KwonUnjeong KimSang Yeon LeeJu Hyun ParkHyungtak SeoSang Kyu KwakSang-Wook KimJong H Kim
Published in: Small (Weinheim an der Bergstrasse, Germany) (2023)
The authors report a strategic approach to achieve metallic properties from semiconducting CuFeS colloidal nanocrystal (NC) solids through cation exchange method. An unprecedentedly high electrical conductivity is realized by the efficient generation of charge carriers onto a semiconducting CuS NC template via minimal Fe exchange. An electrical conductivity exceeding 10 500 S cm -1 (13 400 S cm -1 at 2 K) and a sheet resistance of 17 Ω/sq at room temperature, which are among the highest values for solution-processable semiconducting NCs, are achieved successfully from bornite-phase CuFeS NC films possessing 10% Fe atom. The temperature dependence of the corresponding films exhibits pure metallic characteristics. Highly conducting NCs are demonstrated for a thermoelectric layer exhibiting a high power factor over 1.2 mW m -1 K -2 at room temperature, electrical wires for switching on light emitting diods (LEDs), and source-drain electrodes for p- and n-type organic field-effect transistors. Ambient stability, eco-friendly composition, and solution-processability further validate their sustainable and practical applicability. The present study provides a simple but very effective method for significantly increasing charge carrier concentrations in semiconducting colloidal NCs to achieve metallic properties, which is applicable to various optoelectronic devices.
Keyphrases
  • room temperature
  • ionic liquid
  • aqueous solution
  • metal organic framework
  • light emitting
  • air pollution
  • particulate matter
  • high resolution
  • visible light
  • reduced graphene oxide
  • quantum dots