Humidity‐Compensating Sensor for Volatile Organic Compounds Using Stacked Porous Silicon Photonic Crystals

Ruminski, Anne M.; Moore, Matthew M.; Sailor, Michael J.

doi:10.1002/adfm.200701494

Cited by 91 publications

(80 citation statements)

References 30 publications

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“…[66] In addition, the capability to fabricate multiple, distinct porous domains in a single nanostructure is an enabling feature of porous Si. [73] Generally, biological assays require reagents and sample processing steps. Recent advances in microfluidics, inkjet technologies, and the like have made great strides in reducing sample processing and analysis times, and porous Si systems have also made contributions to this area.…”

Section: Discussionmentioning

confidence: 99%

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

Sailor

2009

Adv Funct Materials

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150

107

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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.

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Section: Discussionmentioning

confidence: 99%

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

Sailor

2009

Adv Funct Materials

Self Cite

150

107

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“…Using aliphatic compounds that contain specifi c functional groups such as carboxylate provides a means to incorporate different surface affi nity properties while retaining the chemical stability of the Si-C bonded sensor surface. [ 21 ] A carbonaceous species can also be grafted to the porous Si surface by thermal decomposition of acetylene on a native porous Si By Anne M. Ruminski, Brian H. King, Jarno Salonen, Jay L. Snyder, and Michael J. Sailor* to generate distinct surface functionalities.…”

Section: Introductionmentioning

confidence: 99%

Porous Silicon‐Based Optical Microsensors for Volatile Organic Analytes: Effect of Surface Chemistry on Stability and Specificity

Ruminski

King

Salonen

et al. 2010

Adv Funct Materials

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Sensing of the volatile organic compounds (VOCs) isopropyl alcohol (IPA) and heptane in air using sub-millimeter porous silicon-based sensor elements is demonstrated in the concentration range 50-800 ppm. The sensor elements are prepared as one-dimensional photonic crystals (rugate fi lters) by programmed electrochemical etch of p + + silicon, and analyte sensing is achieved by measurement of the wavelength shift of the photonic resonance. The sensors are studied as a function of surface chemistry: ozone oxidation, thermal oxidation, hydrosilylation (1-dodecene), electrochemical methylation, reaction with dicholorodimethylsilane and thermal carbonization with acetylene. The thermally oxidized and the dichlorodimethylsilane-modifi ed materials show the greatest stability under atmospheric conditions. Optical microsensors are prepared by attachment of the porous Si layer to the distal end of optical fi bers. The acetylated porous Si microsensor displays a greater response to heptane than to IPA, whereas the other chemical modifi cations display a greater response to IPA than to heptane. The thermal oxide sensor displays a strong response to water vapor, while the acetylated material shows a relatively weak response. The results suggest that a combination of optical fi ber sensors with different surface chemistries can be used to classify VOC analytes. Application of the miniature sensors to the detection of VOC breakthrough in a full-scale activated carbon respirator cartridge simulator is demonstrated.

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“…Time response and penetration of the gas in the depth of PSi was estimated [194]. A doublestack structure, in which one photonic crystal (rendered hydrophilic) is used to monitor humidity and another one (rendered hydrophobic) to ensure an organic compound has been employed in order to null the effect of changing humidity [195]. A polymer-PSi microcavity was proposed to detect volatile explosives such as trinitrotoluene [196].…”

Section: Passive Photonic Structuresmentioning

confidence: 99%

Silicon Nanocrystals in Porous Silicon and Applications

Gelloz

2010

Silicon Nanocrystals

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Humidity‐Compensating Sensor for Volatile Organic Compounds Using Stacked Porous Silicon Photonic Crystals

Cited by 91 publications

References 30 publications

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

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

Porous Silicon‐Based Optical Microsensors for Volatile Organic Analytes: Effect of Surface Chemistry on Stability and Specificity

Silicon Nanocrystals in Porous Silicon and Applications

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