Direct Patterning of Zinc Sulfide on a Sub-10 Nanometer Scale via Electron Beam Lithography

Direct Patterning of Zinc Sulfide on a Sub-10 Nanometer Scale via Electron Beam Lithography

Nanostructures of metal sulfides are conventionally prepared via chemical techniques and patterned using self-assembly. This poses a considerable amount of challenge when arbitrary shapes and sizes of nanostructures are desired to be placed at precise locations. Here, we describe an alternative appr...

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Veröffentlicht in:ACS nano 2017-10, Vol.11 (10), p.9920-9929
Hauptverfasser: Saifullah, Mohammad S. M, Asbahi, Mohamed, Binti-Kamran Kiyani, Maryam, Tripathy, Sudhiranjan, Ong, Esther A. H, Ibn Saifullah, Asadullah, Tan, Hui Ru, Dutta, Tanmay, Ganesan, Ramakrishnan, Valiyaveettil, Suresh, Chong, Karen S. L
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container_end_page 9929
container_issue 10
container_start_page 9920
container_title ACS nano
container_volume 11
creator Saifullah, Mohammad S. M
Asbahi, Mohamed
Binti-Kamran Kiyani, Maryam
Tripathy, Sudhiranjan
Ong, Esther A. H
Ibn Saifullah, Asadullah
Tan, Hui Ru
Dutta, Tanmay
Ganesan, Ramakrishnan
Valiyaveettil, Suresh
Chong, Karen S. L
description Nanostructures of metal sulfides are conventionally prepared via chemical techniques and patterned using self-assembly. This poses a considerable amount of challenge when arbitrary shapes and sizes of nanostructures are desired to be placed at precise locations. Here, we describe an alternative approach of nanoscale patterning of zinc sulfide (ZnS) directly using a spin-coatable and electron beam sensitive zinc butylxanthate resist without the lift-off or etching step. Time-resolved electron beam damage studies using micro-Raman and micro-FTIR spectroscopies suggest that exposure to a beam of electrons leads to quick disappearance of xanthate moieties most likely via the Chugaev elimination, and further increase of electron dose results in the appearance of ZnS, thereby making the exposed resist insoluble in organic solvents. Formation of ZnS nanocrystals was confirmed by high-resolution transmission electron microscopy and selected area electron diffraction. This property was exploited for the fabrication of ZnS lines as small as 6 nm and also enabled patterning of 10 nm dots with pitches as close as 22 nm. The ZnS patterns fabricated by this technique showed defect-induced photoluminescence related to sub-band-gap optical transitions. This method offers an easy way to generate an ensemble of functional ZnS nanostructures that can be arbitrarily patterned and placed in a precise way. Such an approach may enable programmable design of functional chalcogenide nanostructures.
doi_str_mv 10.1021/acsnano.7b03951
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Time-resolved electron beam damage studies using micro-Raman and micro-FTIR spectroscopies suggest that exposure to a beam of electrons leads to quick disappearance of xanthate moieties most likely via the Chugaev elimination, and further increase of electron dose results in the appearance of ZnS, thereby making the exposed resist insoluble in organic solvents. Formation of ZnS nanocrystals was confirmed by high-resolution transmission electron microscopy and selected area electron diffraction. This property was exploited for the fabrication of ZnS lines as small as 6 nm and also enabled patterning of 10 nm dots with pitches as close as 22 nm. The ZnS patterns fabricated by this technique showed defect-induced photoluminescence related to sub-band-gap optical transitions. This method offers an easy way to generate an ensemble of functional ZnS nanostructures that can be arbitrarily patterned and placed in a precise way. 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