Reduction of stress at the initial stages of GaN growth on Si(111)
- 6 January 2003
- journal article
- research article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 82 (1) , 28-30
- https://doi.org/10.1063/1.1534940
Abstract
GaN growth on heterosubstrates usually leads to an initially high dislocation density at the substrate/seed layer interface. Due to the initial growth from small crystallites, tensile stress is generated at the coalescence boundaries during GaN growth. In addition, with tensile thermal stress this leads to cracking of GaN on Si and SiC substrates when cooling to room temperature. By partially masking the typically applied AlN seed layer on Si(111) with an in situ deposited SiN mask a reduction in tensile stress can be achieved for the subsequently grown GaN layer. Additionally, the 6 K GaN band edge photoluminescence is increased by about an order of magnitude and shifts by 21 meV, which can be attributed to a change in tensile stress of ∼0.8 GPa , in good agreement with x-ray diffractometry measurements. This improvement in material properties can be attributed to a reduction of grain boundaries by the growth of larger sized crystallites and lateral overgrowth of less defective GaN.Keywords
This publication has 18 references indexed in Scilit:
- Bright, Crack-Free InGaN/GaN Light Emitters on Si(111)Physica Status Solidi (a), 2002
- GaN-based optoelectronics on silicon substratesMaterials Science and Engineering: B, 2002
- Physical Origins of Intrinsic Stresses in Volmer–Weber Thin FilmsMRS Bulletin, 2002
- In situ and ex situ evaluation of the film coalescence for GaN growth on GaN nucleation layersJournal of Crystal Growth, 2000
- Metalorganic Chemical Vapor Phase Epitaxy of Crack-Free GaN on Si (111) Exceeding 1 µm in ThicknessJapanese Journal of Applied Physics, 2000
- Anti-Surfactant in III-Nitride Epitaxy –Quantum Dot Formation and Dislocation Termination–Japanese Journal of Applied Physics, 2000
- A new method for a great reduction of dislocation density in a GaN layer grown on a sapphire substrateJournal of Crystal Growth, 2000
- Growth of high-quality GaN by low-pressure metal-organic vapour phase epitaxy (LP-MOVPE) from 3D islands and lateral overgrowthJournal of Crystal Growth, 1999
- GaN thin films deposited via organometallic vapor phase epitaxy on α(6H)–SiC(0001) using high-temperature monocrystalline AlN buffer layersApplied Physics Letters, 1995
- Low-temperature metalorganic chemical vapor deposition of InP on Si(001)Applied Physics Letters, 1991