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Overcoming Carrier Concentration Limits in Polycrystalline CdTe Thin Films with In Situ Doping.

Brian E McCandlessWayne A BuchananChristopher P ThompsonGowri SriramagiriRobert J LovelettJoel DuenowDavid AlbinSøren JensenEric ColegroveJohn MoseleyHelio MoutinhoSteven P HarveyMowafak Al-JassimWyatt K Metzger
Published in: Scientific reports (2018)
Thin film materials for photovoltaics such as cadmium telluride (CdTe), copper-indium diselenide-based chalcopyrites (CIGS), and lead iodide-based perovskites offer the potential of lower solar module capital costs and improved performance to microcrystalline silicon. However, for decades understanding and controlling hole and electron concentration in these polycrystalline films has been extremely challenging and limiting. Ionic bonding between constituent atoms often leads to tenacious intrinsic compensating defect chemistries that are difficult to control. Device modeling indicates that increasing CdTe hole density while retaining carrier lifetimes of several nanoseconds can increase solar cell efficiency to 25%. This paper describes in-situ Sb, As, and P doping and post-growth annealing that increases hole density from historic 1014 limits to 1016-1017 cm-3 levels without compromising lifetime in thin polycrystalline CdTe films, which opens paths to advance solar performance and achieve costs below conventional electricity sources.
Keyphrases
  • quantum dots
  • solar cells
  • perovskite solar cells
  • molecularly imprinted
  • room temperature
  • cell therapy
  • drinking water
  • stem cells
  • transition metal
  • liquid chromatography
  • tandem mass spectrometry