Residual Metallic Contamination of Transferred Chemical Vapor Deposited Graphene

Integration of graphene with Si microelectronics is very appealing by offering potentially a broad range of new functionalities. New materials to be integrated with Si platform must conform to stringent purity standards. Here, we investigate graphene layers grown on copper foils by chemical vapor de...

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Veröffentlicht in:	arXiv.org 2015-05
Hauptverfasser:	Lupina, Grzegorz, Kitzmann, Julia, Costina, Ioan, Lukosius, Mindaugas, Wenger, Christian, Wolff, Andre, Vaziri, Sam, Ostling, Mikael, Pasternak, Iwona, Krajewska, Aleksandra, Strupinski, Wlodek, Kataria, Satender, Gahoi, Amit, Lemme, Max C, Ruhl, Guenther, Guenther Zoth, Luxenhofer, Oliver, Mehr, Wolfgang
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Sprache:	eng
Schlagworte:	Chemical vapor deposition Cleaning Contamination Copper Current carriers Depth profiling Diffusion length Electrochemical analysis Graphene Heat treatment Impurities Ions Metal foils Microelectronics Nanotubes Optoelectronics Organic chemistry Physics - Mesoscale and Nanoscale Physics Secondary ion mass spectrometry Silicon substrates X ray reflection X-ray fluorescence
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creator	Lupina, Grzegorz Kitzmann, Julia Costina, Ioan Lukosius, Mindaugas Wenger, Christian Wolff, Andre Vaziri, Sam Ostling, Mikael Pasternak, Iwona Krajewska, Aleksandra Strupinski, Wlodek Kataria, Satender Gahoi, Amit Lemme, Max C Ruhl, Guenther Guenther Zoth Luxenhofer, Oliver Mehr, Wolfgang
description	Integration of graphene with Si microelectronics is very appealing by offering potentially a broad range of new functionalities. New materials to be integrated with Si platform must conform to stringent purity standards. Here, we investigate graphene layers grown on copper foils by chemical vapor deposition and transferred to silicon wafers by wet etch and electrochemical delamination methods with respect to residual sub-monolayer metallic contaminations. Regardless of the transfer method and associated cleaning scheme, time-of-flight secondary ion mass spectrometry and total reflection x-ray fluorescence measurements indicate that the graphene sheets are contaminated with residual metals (copper, iron) with a concentration exceeding 10$^{13}$ atoms/cm$^{2}$. These metal impurities appear to be partly mobile upon thermal treatment as shown by depth profiling and reduction of the minority charge carrier diffusion length in the silicon substrate. As residual metallic impurities can significantly alter electronic and electrochemical properties of graphene and can severely impede the process of integration with silicon microelectronics these results reveal that further progress in synthesis, handling, and cleaning of graphene is required on the way to its advanced electronic and optoelectronic applications.
doi_str_mv	10.48550/arxiv.1505.00889
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New materials to be integrated with Si platform must conform to stringent purity standards. Here, we investigate graphene layers grown on copper foils by chemical vapor deposition and transferred to silicon wafers by wet etch and electrochemical delamination methods with respect to residual sub-monolayer metallic contaminations. Regardless of the transfer method and associated cleaning scheme, time-of-flight secondary ion mass spectrometry and total reflection x-ray fluorescence measurements indicate that the graphene sheets are contaminated with residual metals (copper, iron) with a concentration exceeding 10$^{13}$ atoms/cm$^{2}$. These metal impurities appear to be partly mobile upon thermal treatment as shown by depth profiling and reduction of the minority charge carrier diffusion length in the silicon substrate. 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subjects	Chemical vapor deposition Cleaning Contamination Copper Current carriers Depth profiling Diffusion length Electrochemical analysis Graphene Heat treatment Impurities Ions Metal foils Microelectronics Nanotubes Optoelectronics Organic chemistry Physics - Mesoscale and Nanoscale Physics Secondary ion mass spectrometry Silicon substrates X ray reflection X-ray fluorescence
title	Residual Metallic Contamination of Transferred Chemical Vapor Deposited Graphene
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