Photoluminescence-Based Sensing With Porous Silicon Films, Microparticles, and Nanoparticles

Here, chemical sensors made from porous Si are reviewed, with an emphasis on systems that harness photoluminescence and related energy‐ and charge‐transfer mechanisms available to porous Si‐derived nanocrystallites. Quenching of luminescence by molecular adsorbates involves the harvesting of energy...

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Published inAdvanced functional materials Vol. 19; no. 20; pp. 3195 - 3208
Main Authors Sailor, Michael J., Wu, Elizabeth C.
Format Journal Article
LanguageEnglish
Published Weinheim WILEY-VCH Verlag 23.10.2009
WILEY‐VCH Verlag
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Summary:Here, chemical sensors made from porous Si are reviewed, with an emphasis on systems that harness photoluminescence and related energy‐ and charge‐transfer mechanisms available to porous Si‐derived nanocrystallites. Quenching of luminescence by molecular adsorbates involves the harvesting of energy from a delocalized nanostructure that can be much larger than the molecule being sensed, providing a means to amplify the sensory event. The interaction of chemical species on the surface of porous Si can exert a pronounced influence on this process, and examples of some of the key chemical reactions that modify either the surface or the bulk properties of porous Si are presented. Sensors based on micron‐scale and smaller porous Si particles are also discussed. Miniaturization to this size regime enables new applications, including imaging of cancerous tissues, indirect detection of reactive oxygen species (ROS), and controlled drug release. Examples of environmental and in vivo sensing systems enabled by porous Si are provided. The nanoscale features in porous silicon have interesting photoluminescence and related energy‐ and charge‐transfer properties that can be harnessed to sense chemicals in the gas or liquid phases. This review discusses macro‐, micro‐, and nanosensor devices derived from porous silicon, providing examples of environmental and in vivo applications. The influence of surface chemistry is particularly highlighted.
Bibliography:U.S. National Science Foundation, Division of Materials Research - No. DMR-0806859
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ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.200900535