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GaN buffer growth temperature and efficiency of InGaN/GaN quantum wells - The critical role of nitrogen vacancies at the GaN surface

At a Glance

Section titled ā€œAt a Glanceā€
MetadataDetails
Publication Date2021-03-15
JournalApplied Physics Letters
AuthorsYao Chen, Camille Haller, Wei Liu, S. Yu. Karpov, J.ā€F. Carlin
InstitutionsƉcole Polytechnique FĆ©dĆ©rale de Lausanne
Citations28

Abstract

Section titled ā€œAbstractā€

An indium-containing layer positioned underneath the InGaN/GaN quantum well (QW) active region is commonly used in high efficiency blue light-emitting diodes. Recent studies proposed that the role of this underlayer is to trap surface defects (SDs), which, otherwise, generate non-radiative recombination centers in the QWs. However, the origin and the nature of these defects remain unknown. Our previous study revealed that high-temperature growth of GaN promotes SD creation. In this work, we investigate the impact of the GaN-buffer growth temperature on the InGaN/GaN QW efficiency. We show that the 300 K photoluminescence decay time of a single QW deposited on 1-Ī¼m-thick GaN buffer dramatically decreases from few ns to less than 100 ps when the GaN buffer growth temperature is increased from 870 Ā°C to 1045 Ā°C. This internal quantum efficiency collapse is ascribed to the generation of SDs in the GaN buffer. A theoretical study of temperature-dependent defect formation energy in GaN suggests that these SDs are most likely nitrogen vacancies. Finally, we investigate the formation dynamics of SDs and show that they are mainly generated at the early stage of the GaN growth, i.e., within 50 nm, and then reach a steady state concentration mainly fixed by the GaN growth temperature.

Tech Support

Section titled ā€œTech Supportā€

Original Source

Section titled ā€œOriginal Sourceā€

References

Section titled ā€œReferencesā€
  1. 1994 - Candela-class high-brightness InGaN/AlGaN double-heterostructure blue-light-emitting diodes [Crossref]
  2. 2015 - Bulk GaN flip-chip violet light-emitting diodes with optimized efficiency for high-power operation [Crossref]
  3. 2006 - Origin of defect-insensitive emission probability in In-containing (Al, In, Ga) N alloy semiconductors [Crossref]
  4. 1996 - Growth and characterization of bulk InGaN films and quantum wells [Crossref]
  5. 1996 - Radiative recombination lifetime measurements of InGaN single quantum well [Crossref]
  6. 2004 - High luminescent efficiency of InGaN multiple quantum wells grown on InGaN underlying layers [Crossref]
  7. 2006 - Enhanced optical properties of InGaN MQWs with InGaN underlying layers [Crossref]
  8. 2010 - Boosting green GaInN/GaN light-emitting diode performance by a GaInN underlying layer [Crossref]
  9. 2016 - Calcium impurity as a source of non-radiative recombination in (In, Ga) N layers grown by molecular beam epitaxy [Crossref]
  10. 2017 - Burying non-radiative defects in InGaN underlayer to increase InGaN/GaN quantum well efficiency [Crossref]

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