Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy

Hiroshi Nakashima; Wei Chen Wen; Keisuke Yamamoto; Dong Wang

doi:10.1149/09204.0003ecst

Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy

Hiroshi Nakashima, Wei Chen Wen, Keisuke Yamamoto, Dong Wang

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

A border trap (BT) evaluation method was established for SiO₂/GeO₂Ge gate stacks by using deep-level transient spectroscopy with a lock-in integrator. Ge metal-oxide-semiconductor capacitors (MOSCAPs) with SiCVGeCVGe gate stacks were fabricated by post-passivation thermal oxidation. The interface trap (IT) and BT signals were successfully separated based on their different dependences on the intensity of injection pulses. By using p-type MOSCAPs, BTs at the position of 0.4 nm from GeO₂Ge interface were measured. The energy of these BTs was centralized at the position near to the valence band edge of Ge, and the density (N_bt) was in the range of 10¹⁷-10₁₈ cm^-3. For n-type MOSCAPs, BTs at the position range of 2.8-3.4 nm from the GeO₂/Ge interface were measured. The energy of these BTs were distributed in a relatively wide range near to the conduction band edge of Ge, and the N_bt was approximately one order of magnitude higher than those for p-MOSCAPs. We also found that Al post metallization annealing can passivate both ITs and BTs near to the valence band edge of Ge but not those near to the conduction band edge.

Original language	English
Title of host publication	Semiconductor Process Integration 11
Editors	J. Murota, C. Claeys, H. Iwai, M. Tao, S. Deleonibus, A. Mai, K. Shiojima, Y. Cao
Publisher	Electrochemical Society Inc.
Pages	3-10
Number of pages	8
Edition	4
ISBN (Electronic)	9781607688785
ISBN (Print)	9781607688785
DOIs	https://doi.org/10.1149/09204.0003ecst
Publication status	Published - 2019
Event	11th Symposium on Semiconductor Process Integration - 236th ECS Meeting - Atlanta, United States Duration: Oct 13 2019 → Oct 17 2019

Publication series

Name	ECS Transactions
Number	4
Volume	92
ISSN (Print)	1938-6737
ISSN (Electronic)	1938-5862

Conference

Conference	11th Symposium on Semiconductor Process Integration - 236th ECS Meeting
Country/Territory	United States
City	Atlanta
Period	10/13/19 → 10/17/19

All Science Journal Classification (ASJC) codes

Engineering(all)

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10.1149/09204.0003ecst

Cite this

Nakashima, H., Wen, W. C., Yamamoto, K., & Wang, D. (2019). Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy. In J. Murota, C. Claeys, H. Iwai, M. Tao, S. Deleonibus, A. Mai, K. Shiojima, & Y. Cao (Eds.), Semiconductor Process Integration 11 (4 ed., pp. 3-10). (ECS Transactions; Vol. 92, No. 4). Electrochemical Society Inc.. https://doi.org/10.1149/09204.0003ecst

Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy. / Nakashima, Hiroshi; Wen, Wei Chen; Yamamoto, Keisuke et al.
Semiconductor Process Integration 11. ed. / J. Murota; C. Claeys; H. Iwai; M. Tao; S. Deleonibus; A. Mai; K. Shiojima; Y. Cao. 4. ed. Electrochemical Society Inc., 2019. p. 3-10 (ECS Transactions; Vol. 92, No. 4).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Nakashima, H, Wen, WC, Yamamoto, K & Wang, D 2019, Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy. in J Murota, C Claeys, H Iwai, M Tao, S Deleonibus, A Mai, K Shiojima & Y Cao (eds), Semiconductor Process Integration 11. 4 edn, ECS Transactions, no. 4, vol. 92, Electrochemical Society Inc., pp. 3-10, 11th Symposium on Semiconductor Process Integration - 236th ECS Meeting, Atlanta, United States, 10/13/19. https://doi.org/10.1149/09204.0003ecst

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title = "Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy",

abstract = "A border trap (BT) evaluation method was established for SiO2/GeO2Ge gate stacks by using deep-level transient spectroscopy with a lock-in integrator. Ge metal-oxide-semiconductor capacitors (MOSCAPs) with SiCVGeCVGe gate stacks were fabricated by post-passivation thermal oxidation. The interface trap (IT) and BT signals were successfully separated based on their different dependences on the intensity of injection pulses. By using p-type MOSCAPs, BTs at the position of 0.4 nm from GeO2Ge interface were measured. The energy of these BTs was centralized at the position near to the valence band edge of Ge, and the density (Nbt) was in the range of 1017-1018 cm-3. For n-type MOSCAPs, BTs at the position range of 2.8-3.4 nm from the GeO2/Ge interface were measured. The energy of these BTs were distributed in a relatively wide range near to the conduction band edge of Ge, and the Nbt was approximately one order of magnitude higher than those for p-MOSCAPs. We also found that Al post metallization annealing can passivate both ITs and BTs near to the valence band edge of Ge but not those near to the conduction band edge.",

author = "Hiroshi Nakashima and Wen, {Wei Chen} and Keisuke Yamamoto and Dong Wang",

note = "Funding Information: This work was supported by (JSPS) KAKENHI (grant numbers 17H03237) and MEXT/JSPS Leading Initiative for Excellent Young Researchers (LEADER). Publisher Copyright: {\textcopyright} The Electrochemical Society.; 11th Symposium on Semiconductor Process Integration - 236th ECS Meeting ; Conference date: 13-10-2019 Through 17-10-2019",

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doi = "10.1149/09204.0003ecst",

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T1 - Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy

AU - Nakashima, Hiroshi

AU - Wen, Wei Chen

AU - Yamamoto, Keisuke

AU - Wang, Dong

N1 - Funding Information: This work was supported by (JSPS) KAKENHI (grant numbers 17H03237) and MEXT/JSPS Leading Initiative for Excellent Young Researchers (LEADER). Publisher Copyright: © The Electrochemical Society.

PY - 2019

Y1 - 2019

N2 - A border trap (BT) evaluation method was established for SiO2/GeO2Ge gate stacks by using deep-level transient spectroscopy with a lock-in integrator. Ge metal-oxide-semiconductor capacitors (MOSCAPs) with SiCVGeCVGe gate stacks were fabricated by post-passivation thermal oxidation. The interface trap (IT) and BT signals were successfully separated based on their different dependences on the intensity of injection pulses. By using p-type MOSCAPs, BTs at the position of 0.4 nm from GeO2Ge interface were measured. The energy of these BTs was centralized at the position near to the valence band edge of Ge, and the density (Nbt) was in the range of 1017-1018 cm-3. For n-type MOSCAPs, BTs at the position range of 2.8-3.4 nm from the GeO2/Ge interface were measured. The energy of these BTs were distributed in a relatively wide range near to the conduction band edge of Ge, and the Nbt was approximately one order of magnitude higher than those for p-MOSCAPs. We also found that Al post metallization annealing can passivate both ITs and BTs near to the valence band edge of Ge but not those near to the conduction band edge.

AB - A border trap (BT) evaluation method was established for SiO2/GeO2Ge gate stacks by using deep-level transient spectroscopy with a lock-in integrator. Ge metal-oxide-semiconductor capacitors (MOSCAPs) with SiCVGeCVGe gate stacks were fabricated by post-passivation thermal oxidation. The interface trap (IT) and BT signals were successfully separated based on their different dependences on the intensity of injection pulses. By using p-type MOSCAPs, BTs at the position of 0.4 nm from GeO2Ge interface were measured. The energy of these BTs was centralized at the position near to the valence band edge of Ge, and the density (Nbt) was in the range of 1017-1018 cm-3. For n-type MOSCAPs, BTs at the position range of 2.8-3.4 nm from the GeO2/Ge interface were measured. The energy of these BTs were distributed in a relatively wide range near to the conduction band edge of Ge, and the Nbt was approximately one order of magnitude higher than those for p-MOSCAPs. We also found that Al post metallization annealing can passivate both ITs and BTs near to the valence band edge of Ge but not those near to the conduction band edge.

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T2 - 11th Symposium on Semiconductor Process Integration - 236th ECS Meeting

Y2 - 13 October 2019 through 17 October 2019

ER -

Border-trap characterization for Ge gate stacks using deep-level transient spectroscopy

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