论文信息 - The origin of stress reduction by low-temperature AlN interlayers

The origin of stress reduction by low-temperature AlN interlayers

Thin low-temperature AlN interlayers can be applied to reduce stress to grow thick crack-free AlGaN layers on GaN buffer layers on sapphire and thick crack-free GaN layers on Si. The mechanism leading to stress reduction is investigated by high resolution x-ray diffractometry measurements on metalorganic chemical vapor phase epitaxy grown samples on Si(111) with different interlayer deposition temperatures. A decrease of tensile stress with decreasing interlayer growth temperature is observed. From reciprocal space maps we conclude that interlayers grown at high temperatures are pseudomorphic, while grown at lower temperatures they are relaxed. Therefore, AlGaN or GaN layers grown on a low temperature AlN interlayer grow under compressive interlayer-induced strain. The stress in the GaN layer depends on the growth temperature that likely controls the amount of AlN interlayer relaxation.

[1] Lester F. Eastman,et al. AlGaN/GaN heterostructures on insulating AlGaN nucleation layers , 1999 .

[2] H. Amano,et al. Control of Dislocations and Stress in AlGaN on Sapphire Using a Low Temperature Interlayer , 1999 .

[3] Michael Heuken,et al. Metalorganic Chemical Vapor Phase Epitaxy of Crack-Free GaN on Si (111) Exceeding 1 µm in Thickness , 2000 .

[4] Jung Han,et al. Control and elimination of cracking of AlGaN using low-temperature AlGaN interlayers , 2001 .

[5] H. Amano,et al. Metalorganic vapor phase epitaxy growth of crack-free AlN on GaN and its application to high-mobility AlN/GaN superlattices , 2001 .

[6] H. Amano,et al. Stress and Defect Control in GaN Using Low Temperature Interlayers , 1998 .

[7] Armin Dadgar,et al. Thick, crack-free blue light-emitting diodes on Si(111) using low-temperature AlN interlayers and in situ SixNy masking , 2002 .

[8] D. Bimberg,et al. Low‐temperature metalorganic chemical vapor deposition of InP on Si(001) , 1991 .

[9] A. Nurmikko,et al. Stress Engineering During Metalorganic Chemical Vapor Deposition of AlGaN/GaN Distributed Bragg Reflectors , 2001 .