Starten Sie Ihre Suche...


Durch die Nutzung unserer Webseite erklären Sie sich damit einverstanden, dass wir Cookies verwenden. Weitere Informationen

13.3% efficient solution deposited Cu(In,Ga)Se2 solar cells processed with different sodium salt sources

Progress in Photovoltaics: Research and Applications. Bd. 24. H. 6. 2016 S. 749 - 759

Erscheinungsjahr: 2016

ISBN/ISSN: 1099-159X

Publikationstyp: Zeitschriftenaufsatz (Übersichtsartikel)

Sprache: Englisch

Doi/URN: 10.1002/pip.2721

Volltext über DOI/URN

GeprüftBibliothek

Inhaltszusammenfassung


In this work, we obtain the highest reported power conversion efficiency (13.3%) for sulfur-free CIGSe solar cells by solution processing. Intentional sodium incorporation is achieved directly by dissolving sodium salts in the ink. The effect on solar cell properties of three sodium sources is investigated: NaCl, NaHCO2, and NaSCN. A comparison is made with absorbers grown on soda-lime glass substrates and in the absence of sodium sources. The incorporation via sodium salts yields significant...In this work, we obtain the highest reported power conversion efficiency (13.3%) for sulfur-free CIGSe solar cells by solution processing. Intentional sodium incorporation is achieved directly by dissolving sodium salts in the ink. The effect on solar cell properties of three sodium sources is investigated: NaCl, NaHCO2, and NaSCN. A comparison is made with absorbers grown on soda-lime glass substrates and in the absence of sodium sources. The incorporation via sodium salts yields significantly better results, which is attributed to enhanced-sodium availability. A comparison with identically annealed sputtered metal precursor layers capable of delivering 15.1% module efficiency suggests that the cell results are limited by the selenization procedure.» weiterlesen» einklappen

  • CIGSe
  • true solution
  • liquid film coating
  • sodium incorporation
  • sodium salts

Autoren


Berner, Ulrich (Autor)
Colombara, Diego (Autor)
de Wild, Jessica (Autor)
Robert, Erika V.C. (Autor)
Schütze, Martin (Autor)
Valle, Nathalie (Autor)
Widenmeyer, Markus (Autor)
Dale, Phillip J. (Autor)

Klassifikation


DFG Fachgebiet:
Physik der kondensierten Materie

DDC Sachgruppe:
Physik

Verbundene Forschungsprojekte


Verknüpfte Personen


Beteiligte Einrichtungen