Fabrication and characterization of germanium-on-insulator through epitaxy, bonding, and layer transfer

A scalable method to fabricate germanium on insulator (GOI) substrate through epitaxy, bonding, and layer transfer is reported. The germanium (Ge) epitaxial film is grown directly on a silicon (Si) (001) donor wafer using a “three-step growth” approach in a reduced pressure chemical vapour depositio...

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Veröffentlicht in:	Journal of applied physics 2014-09, Vol.116 (10)
Hauptverfasser:	Lee, Kwang Hong, Bao, Shuyu, Chong, Gang Yih, Tan, Yew Heng, Fitzgerald, Eugene A., Tan, Chuan Seng
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Chemical vapor deposition Chemical-mechanical polishing Dislocation density Epitaxial growth Germanium Misfit dislocations Organic chemistry Silicon Substrates Surface roughness Tensile strain Threading dislocations
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container_issue	10
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container_title	Journal of applied physics
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creator	Lee, Kwang Hong Bao, Shuyu Chong, Gang Yih Tan, Yew Heng Fitzgerald, Eugene A. Tan, Chuan Seng
description	A scalable method to fabricate germanium on insulator (GOI) substrate through epitaxy, bonding, and layer transfer is reported. The germanium (Ge) epitaxial film is grown directly on a silicon (Si) (001) donor wafer using a “three-step growth” approach in a reduced pressure chemical vapour deposition. The Ge epilayer is then bonded and transferred to another Si (001) wafer to form the GOI substrate. The Ge epilayer on GOI substrate has higher tensile strain (from 0.20% to 0.35%) and rougher surface (2.28 times rougher) compared to the Ge epilayer before transferring (i.e., Ge on Si wafer). This is because the misfit dislocations which are initially hidden along the Ge/Si interface are now flipped over and exposed on the top surface. These misfit dislocations can be removed by either chemical mechanical polishing or annealing. As a result, the Ge epilayer with low threading dislocations density level and surface roughness could be realized.
doi_str_mv	10.1063/1.4895487
format	Article
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The germanium (Ge) epitaxial film is grown directly on a silicon (Si) (001) donor wafer using a “three-step growth” approach in a reduced pressure chemical vapour deposition. The Ge epilayer is then bonded and transferred to another Si (001) wafer to form the GOI substrate. The Ge epilayer on GOI substrate has higher tensile strain (from 0.20% to 0.35%) and rougher surface (2.28 times rougher) compared to the Ge epilayer before transferring (i.e., Ge on Si wafer). This is because the misfit dislocations which are initially hidden along the Ge/Si interface are now flipped over and exposed on the top surface. These misfit dislocations can be removed by either chemical mechanical polishing or annealing. 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subjects	Applied physics Chemical vapor deposition Chemical-mechanical polishing Dislocation density Epitaxial growth Germanium Misfit dislocations Organic chemistry Silicon Substrates Surface roughness Tensile strain Threading dislocations
title	Fabrication and characterization of germanium-on-insulator through epitaxy, bonding, and layer transfer
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