Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release

The design and fabrication of an ordered nanoporous silicon membrane and integrated heater and temperature sensor is described. The methodology for fabrication of the nanoporous structure has been developed for integration within microelectromechanical systems. The structure is fabricated from a 500...

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Main Authors: Chau C.F., Melvin T.
Other Authors: 25824209000
Format: Article
Published: 2023
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spelling my.uniten.dspace-302792023-12-29T15:46:14Z Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release Chau C.F. Melvin T. 25824209000 56236436100 Design Electromechanical devices MEMS Porous silicon Silicon wafers Temperature sensors Deleterious effects Drug release Fabrication methodology Hexagonal close-packed Integrated heater Nano-porous silicon Nanoporous structures Nearest neighbour Porous membranes Sensor designs Thermally induced Uniform diameter Fabrication The design and fabrication of an ordered nanoporous silicon membrane and integrated heater and temperature sensor is described. The methodology for fabrication of the nanoporous structure has been developed for integration within microelectromechanical systems. The structure is fabricated from a 500?m thick silicon ?100? wafer, which has been etched to provide 4�4mm 2membranes of 50?m thick. Quasi-ordered nanoporous silicon is created within the membrane, the nanopores are of uniform diameter (typical structures of the order of 105 � 5nm) and smooth sidewalls to a depth of ?300nm, in a hexagonal close-packed pattern of 200nm nearest neighbour. The porosity of typical fabricated samples is 31.5%. On the back side of the membrane, a heater and a temperature sensor are incorporated. Three different heater/temperature sensor designs were considered theoretically and the best design was then fabricated and studied experimentally. The results obtained provide both highly ordered nanoporous silicon fabrication methodology as well as evidence that the porous membrane can be heated without deleterious effect. � 2012 IOP Publishing Ltd. Final 2023-12-29T07:46:14Z 2023-12-29T07:46:14Z 2012 Article 10.1088/0960-1317/22/8/085028 2-s2.0-84866327113 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84866327113&doi=10.1088%2f0960-1317%2f22%2f8%2f085028&partnerID=40&md5=53c6d9f2679ada8deba0e5b77da0ba7a https://irepository.uniten.edu.my/handle/123456789/30279 22 8 85028 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Design
Electromechanical devices
MEMS
Porous silicon
Silicon wafers
Temperature sensors
Deleterious effects
Drug release
Fabrication methodology
Hexagonal close-packed
Integrated heater
Nano-porous silicon
Nanoporous structures
Nearest neighbour
Porous membranes
Sensor designs
Thermally induced
Uniform diameter
Fabrication
spellingShingle Design
Electromechanical devices
MEMS
Porous silicon
Silicon wafers
Temperature sensors
Deleterious effects
Drug release
Fabrication methodology
Hexagonal close-packed
Integrated heater
Nano-porous silicon
Nanoporous structures
Nearest neighbour
Porous membranes
Sensor designs
Thermally induced
Uniform diameter
Fabrication
Chau C.F.
Melvin T.
Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
description The design and fabrication of an ordered nanoporous silicon membrane and integrated heater and temperature sensor is described. The methodology for fabrication of the nanoporous structure has been developed for integration within microelectromechanical systems. The structure is fabricated from a 500?m thick silicon ?100? wafer, which has been etched to provide 4�4mm 2membranes of 50?m thick. Quasi-ordered nanoporous silicon is created within the membrane, the nanopores are of uniform diameter (typical structures of the order of 105 � 5nm) and smooth sidewalls to a depth of ?300nm, in a hexagonal close-packed pattern of 200nm nearest neighbour. The porosity of typical fabricated samples is 31.5%. On the back side of the membrane, a heater and a temperature sensor are incorporated. Three different heater/temperature sensor designs were considered theoretically and the best design was then fabricated and studied experimentally. The results obtained provide both highly ordered nanoporous silicon fabrication methodology as well as evidence that the porous membrane can be heated without deleterious effect. � 2012 IOP Publishing Ltd.
author2 25824209000
author_facet 25824209000
Chau C.F.
Melvin T.
format Article
author Chau C.F.
Melvin T.
author_sort Chau C.F.
title Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
title_short Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
title_full Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
title_fullStr Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
title_full_unstemmed Design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
title_sort design and fabrication of a quasi-ordered nanoporous silicon membrane suitable for thermally induced drug release
publishDate 2023
_version_ 1806426363404484608
score 13.222552