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Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers

Highly parallelized optical super-resolution lithography techniques are key for realizing bulk volume nanopatterning in materials. The majority of demonstrated STED-inspired lithography schemes are serial writing techniques. Here we use a recently developed model spirothiopyran monolayer photoresist...

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Autores principales: Vijayamohanan, Harikrishnan, Kenath, Gopal S., Palermo, Edmund F., Ullal, Chaitanya K.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: The Royal Society of Chemistry 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9071233/
https://www.ncbi.nlm.nih.gov/pubmed/35529644
http://dx.doi.org/10.1039/c9ra05864h
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author Vijayamohanan, Harikrishnan
Kenath, Gopal S.
Palermo, Edmund F.
Ullal, Chaitanya K.
author_facet Vijayamohanan, Harikrishnan
Kenath, Gopal S.
Palermo, Edmund F.
Ullal, Chaitanya K.
author_sort Vijayamohanan, Harikrishnan
collection PubMed
description Highly parallelized optical super-resolution lithography techniques are key for realizing bulk volume nanopatterning in materials. The majority of demonstrated STED-inspired lithography schemes are serial writing techniques. Here we use a recently developed model spirothiopyran monolayer photoresist to study the non-equilibrium kinetics of STED-inspired lithography systems to achieve large area interference lithography with super-resolved feature dimensions. The linewidth is predicted to increase with exposure time and the contrast is predicted to go through a maximum, resulting in a narrow window of optimum exposure. Experimental results are found to match with high quantitative accuracy. The low photoinhibition saturation threshold of the spirothiopyran renders it especially conducive for parallelized large area nanopatterning. Lines with 56 and 92 nm FWHM were obtained using serial and parallel patterning, respectively. Functionalization of surfaces with heterobifunctional PEGs enables diverse patterning of any desired chemical functionality on these monolayers. These results provide important insight prior to realizing a highly parallelized volume nanofabrication technique.
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spelling pubmed-90712332022-05-06 Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers Vijayamohanan, Harikrishnan Kenath, Gopal S. Palermo, Edmund F. Ullal, Chaitanya K. RSC Adv Chemistry Highly parallelized optical super-resolution lithography techniques are key for realizing bulk volume nanopatterning in materials. The majority of demonstrated STED-inspired lithography schemes are serial writing techniques. Here we use a recently developed model spirothiopyran monolayer photoresist to study the non-equilibrium kinetics of STED-inspired lithography systems to achieve large area interference lithography with super-resolved feature dimensions. The linewidth is predicted to increase with exposure time and the contrast is predicted to go through a maximum, resulting in a narrow window of optimum exposure. Experimental results are found to match with high quantitative accuracy. The low photoinhibition saturation threshold of the spirothiopyran renders it especially conducive for parallelized large area nanopatterning. Lines with 56 and 92 nm FWHM were obtained using serial and parallel patterning, respectively. Functionalization of surfaces with heterobifunctional PEGs enables diverse patterning of any desired chemical functionality on these monolayers. These results provide important insight prior to realizing a highly parallelized volume nanofabrication technique. The Royal Society of Chemistry 2019-09-13 /pmc/articles/PMC9071233/ /pubmed/35529644 http://dx.doi.org/10.1039/c9ra05864h Text en This journal is © The Royal Society of Chemistry https://creativecommons.org/licenses/by-nc/3.0/
spellingShingle Chemistry
Vijayamohanan, Harikrishnan
Kenath, Gopal S.
Palermo, Edmund F.
Ullal, Chaitanya K.
Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
title Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
title_full Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
title_fullStr Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
title_full_unstemmed Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
title_short Super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
title_sort super-resolution interference lithography enabled by non-equilibrium kinetics of photochromic monolayers
topic Chemistry
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9071233/
https://www.ncbi.nlm.nih.gov/pubmed/35529644
http://dx.doi.org/10.1039/c9ra05864h
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