Oxygen vacancies at the Si(001)/SiO2 interface

J. C. Greer; T. M. Hendersen; G. Bersuker; R. J. Bartlett; A. Korkin

Oxygen vacancies at the Si(001)/SiO₂ interface

J. C. Greer, T. M. Hendersen, G. Bersuker, R. J. Bartlett, A. Korkin

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

1 Citation (Scopus)

Abstract

High-k oxides deposited on silicon substrates form interfacial silicon dioxide layers. The interface layer is of importance in microelectronics, due both to charge transport at the silicon/silicon dioxide interface and to the oxide layer influencing the equivalent oxide thickness (EOT). Electrical characterization of low temperature thermal oxides grown by atomic layer deposition of hafnia dioxide indicates a dielectric constant at the interfacial region larger than for stochiometric SiO:. A proposed mechanism for the observed increase is the interface becomes oxygen deficient during the growth process. Oxygen vacancies in SiO₂ are examined by ab initio computations and are found to be more stable in the vicinity of the interface, thus identifying a chemical driving force for oxygen reduction at the interface. Copyright The Electrochemical Society.

Original language	English
Title of host publication	Silicon Materials Science and Technology X
Pages	205-211
Number of pages	7
Edition	2
Publication status	Published - 2006
Externally published	Yes
Event	10th International Symposium on Silicon Materials Science and Technology - 209th Meeting of the Electrochemical Society - Denver, CO, United States Duration: 7 May 2006 → 12 May 2006

Publication series

Name	ECS Transactions
Number	2
Volume	2
ISSN (Print)	1938-5862
ISSN (Electronic)	1938-6737

Conference

Conference	10th International Symposium on Silicon Materials Science and Technology - 209th Meeting of the Electrochemical Society
Country/Territory	United States
City	Denver, CO
Period	7/05/06 → 12/05/06

ASJC Scopus subject areas

General Engineering

Cite this

@inproceedings{7c4a89a836184522ab0b8d793151566a,

title = "Oxygen vacancies at the Si(001)/SiO2 interface",

abstract = "High-k oxides deposited on silicon substrates form interfacial silicon dioxide layers. The interface layer is of importance in microelectronics, due both to charge transport at the silicon/silicon dioxide interface and to the oxide layer influencing the equivalent oxide thickness (EOT). Electrical characterization of low temperature thermal oxides grown by atomic layer deposition of hafnia dioxide indicates a dielectric constant at the interfacial region larger than for stochiometric SiO:. A proposed mechanism for the observed increase is the interface becomes oxygen deficient during the growth process. Oxygen vacancies in SiO2 are examined by ab initio computations and are found to be more stable in the vicinity of the interface, thus identifying a chemical driving force for oxygen reduction at the interface. Copyright The Electrochemical Society.",

author = "Greer, {J. C.} and Hendersen, {T. M.} and G. Bersuker and Bartlett, {R. J.} and A. Korkin",

note = "Copyright: Copyright 2009 Elsevier B.V., All rights reserved.; 10th International Symposium on Silicon Materials Science and Technology - 209th Meeting of the Electrochemical Society ; Conference date: 07-05-2006 Through 12-05-2006",

year = "2006",

language = "English",

isbn = "156677439X",

series = "ECS Transactions",

number = "2",

pages = "205--211",

booktitle = "Silicon Materials Science and Technology X",

edition = "2",

}

Greer, JC, Hendersen, TM, Bersuker, G, Bartlett, RJ & Korkin, A 2006, Oxygen vacancies at the Si(001)/SiO₂ interface. in Silicon Materials Science and Technology X. 2 edn, ECS Transactions, no. 2, vol. 2, pp. 205-211, 10th International Symposium on Silicon Materials Science and Technology - 209th Meeting of the Electrochemical Society, Denver, CO, United States, 7/05/06.

TY - GEN

T1 - Oxygen vacancies at the Si(001)/SiO2 interface

AU - Greer, J. C.

AU - Hendersen, T. M.

AU - Bersuker, G.

AU - Bartlett, R. J.

AU - Korkin, A.

PY - 2006

Y1 - 2006

N2 - High-k oxides deposited on silicon substrates form interfacial silicon dioxide layers. The interface layer is of importance in microelectronics, due both to charge transport at the silicon/silicon dioxide interface and to the oxide layer influencing the equivalent oxide thickness (EOT). Electrical characterization of low temperature thermal oxides grown by atomic layer deposition of hafnia dioxide indicates a dielectric constant at the interfacial region larger than for stochiometric SiO:. A proposed mechanism for the observed increase is the interface becomes oxygen deficient during the growth process. Oxygen vacancies in SiO2 are examined by ab initio computations and are found to be more stable in the vicinity of the interface, thus identifying a chemical driving force for oxygen reduction at the interface. Copyright The Electrochemical Society.

AB - High-k oxides deposited on silicon substrates form interfacial silicon dioxide layers. The interface layer is of importance in microelectronics, due both to charge transport at the silicon/silicon dioxide interface and to the oxide layer influencing the equivalent oxide thickness (EOT). Electrical characterization of low temperature thermal oxides grown by atomic layer deposition of hafnia dioxide indicates a dielectric constant at the interfacial region larger than for stochiometric SiO:. A proposed mechanism for the observed increase is the interface becomes oxygen deficient during the growth process. Oxygen vacancies in SiO2 are examined by ab initio computations and are found to be more stable in the vicinity of the interface, thus identifying a chemical driving force for oxygen reduction at the interface. Copyright The Electrochemical Society.

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M3 - Conference contribution

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SN - 156677439X

SN - 9781566774390

T3 - ECS Transactions

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EP - 211

BT - Silicon Materials Science and Technology X

T2 - 10th International Symposium on Silicon Materials Science and Technology - 209th Meeting of the Electrochemical Society

Y2 - 7 May 2006 through 12 May 2006

ER -