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Novel germanium surface modification for sub-10 nm patterning with electron beam lithography and hydrogen silsesquioxane resist

Novel germanium surface modification for sub-10 nm patterning with electron beam lithography and hydrogen silsesquioxane resist
Novel germanium surface modification for sub-10 nm patterning with electron beam lithography and hydrogen silsesquioxane resist
Germanium is a promising high-mobility channel material for future nanoelectronic devices. Hydrogen silsesquioxane (HSQ) is a well known high-resolution electron beam lithography (EBL) resist, which is usually developed in aqueous based developers. However, this feature of HSQ causes troubles while patterning Ge surface as it is always shielded with native Ge oxides. GeO2 is a water soluble oxide, and since HSQ resist is developed in aqueous solvents, this oxide interferes with the patterning. After the EBL exposure, GeO2 is washed off during the development, lifting the patterned structures and making the high-resolution patterning impossible. To avoid this issue, it is necessary to either clean and passivate the Ge surface or use buffer layers between the native Ge oxides and the HSQ layer. In this article, a novel technique to clean the Ge surface prior to HSQ deposition, using simple “household” acids like citric acid and acetic acid, is reported. The acids are able to remove the native Ge oxides as well as efficiently passivate the surface. The acid passivation was found to hold the HSQ sturdily to the Ge surface, even during development with the aqueous salty solvent. Using this process, Ge nanowires having widths down to 5 nm were successfully patterned on germanium-on-insulator substrates. To the best of our knowledge, these are the smallest top-down fabricated Ge nanostructures reported till date.
2166-2746
041603
Gangnaik, Anushka S.
8b44e462-2a3f-4295-a9ff-1a2f7c09f14d
Georgiev, Yordan M.
75581277-0154-4144-8a94-36eaffeeef02
Collins, Gillian
26450c2d-06de-4595-8568-6ba1dee14d77
Holmes, Justin D.
6f16ad07-0c95-4eba-a71b-70dd149f5a9a
Gangnaik, Anushka S.
8b44e462-2a3f-4295-a9ff-1a2f7c09f14d
Georgiev, Yordan M.
75581277-0154-4144-8a94-36eaffeeef02
Collins, Gillian
26450c2d-06de-4595-8568-6ba1dee14d77
Holmes, Justin D.
6f16ad07-0c95-4eba-a71b-70dd149f5a9a

Gangnaik, Anushka S., Georgiev, Yordan M., Collins, Gillian and Holmes, Justin D. (2016) Novel germanium surface modification for sub-10 nm patterning with electron beam lithography and hydrogen silsesquioxane resist. Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena, 34 (4), 041603. (doi:10.1116/1.4948916).

Record type: Article

Abstract

Germanium is a promising high-mobility channel material for future nanoelectronic devices. Hydrogen silsesquioxane (HSQ) is a well known high-resolution electron beam lithography (EBL) resist, which is usually developed in aqueous based developers. However, this feature of HSQ causes troubles while patterning Ge surface as it is always shielded with native Ge oxides. GeO2 is a water soluble oxide, and since HSQ resist is developed in aqueous solvents, this oxide interferes with the patterning. After the EBL exposure, GeO2 is washed off during the development, lifting the patterned structures and making the high-resolution patterning impossible. To avoid this issue, it is necessary to either clean and passivate the Ge surface or use buffer layers between the native Ge oxides and the HSQ layer. In this article, a novel technique to clean the Ge surface prior to HSQ deposition, using simple “household” acids like citric acid and acetic acid, is reported. The acids are able to remove the native Ge oxides as well as efficiently passivate the surface. The acid passivation was found to hold the HSQ sturdily to the Ge surface, even during development with the aqueous salty solvent. Using this process, Ge nanowires having widths down to 5 nm were successfully patterned on germanium-on-insulator substrates. To the best of our knowledge, these are the smallest top-down fabricated Ge nanostructures reported till date.

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More information

Accepted/In Press date: 6 April 2016
Published date: 10 May 2016
Related URLs:
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Identifiers

Local EPrints ID: 453101
URI: http://eprints.soton.ac.uk/id/eprint/453101
DOI: doi:10.1116/1.4948916
ISSN: 2166-2746
PURE UUID: 570fd9b8-e4c5-470d-af1e-10fd131a38d9

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Date deposited: 08 Jan 2022 16:56
Last modified: 16 Mar 2024 14:31

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Contributors

Author: Anushka S. Gangnaik
Author: Yordan M. Georgiev
Author: Gillian Collins
Author: Justin D. Holmes

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