Light Enhanced Electron Transduction and Amplified Sensing at a Nanostructure Modified Semiconductor Interface

Laminack, William; Gole, James L.

doi:10.1002/adfm.201301250

Cited by 21 publications

(13 citation statements)

References 16 publications

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“…In contrast, the response to NH 3 increased in the TiO 2− x N x modified PSi sensor for both UV and white light. When detecting NO 2 , Laminack and Gole had the opposite situation. The light had a marked effect on the resistance response to NO 2 for untreated PSi, which was counter to that observed for the PSi microstructure platform deposited with distinct nanostructured island sites of TiO 2 and TiO 2− x N x .…”

Section: Approaches To Optimization Of Psi‐based Gas and Vapor Sensorsmentioning

confidence: 96%

“…To measure the change in response to NO 2 , a UV lamp was introduced in the enclosed testing chamber. Laminack and Gole also studied the influence of light on the sensor response of PSi‐based sensors. They found that white light and UV light did not have any effect on the sensor response to NH 3 for untreated PSi.…”

Section: Approaches To Optimization Of Psi‐based Gas and Vapor Sensorsmentioning

confidence: 99%

“…Kim et al supposed that UV light activates the response of the oriental polarization which has a slow relaxation time for an AC field. Laminack and Gole believed that the UV and white light excitation causes the TiO 2− x N x to become more acidic, enhancing the electron withdrawing power and thus increasing the sensor response. However, till now, the consistent mechanisms, which can explain the photoassisted gas‐sensing properties of various PSi‐based structures, are absent.…”

Section: Approaches To Optimization Of Psi‐based Gas and Vapor Sensorsmentioning

confidence: 99%

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How to Improve the Performance of Porous Silicon‐Based Gas and Vapor Sensors? Approaches and Achievements

Rusu

2019

Physica Status Solidi (a)

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It is shown that, along with the advantages, sensors based on porous silicon (PSi) have disadvantages that inhibit their widespread use. The parameters of PSi which can affect the performance of PSi-based sensors are considered in detail, and approaches are analyzed that allow for the improvement of the main characteristics of PSi-based gas and vapor sensors. It is concluded that despite the progress made in terms of improving the sensitivity, selectivity, and stability of PSi-based sensors, further research and development in this direction is necessary, as the existing methods do not provide the required stability of the characteristics and selectivity of their response.

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Section: Approaches To Optimization Of Psi‐based Gas and Vapor Sensorsmentioning

confidence: 96%

Section: Approaches To Optimization Of Psi‐based Gas and Vapor Sensorsmentioning

confidence: 99%

Section: Approaches To Optimization Of Psi‐based Gas and Vapor Sensorsmentioning

confidence: 99%

See 1 more Smart Citation

How to Improve the Performance of Porous Silicon‐Based Gas and Vapor Sensors? Approaches and Achievements

Rusu

2019

Physica Status Solidi (a)

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“…The use of low light levels (≤ ! Watt) demonstrates the feasibility for developing Solar Pumped Sensors [13]. The ability to deal with water vapor contamination has been demonstrated [14].…”

Section: The Interfacementioning

confidence: 99%

Nanostructure directed interfaces created from nanoparticle island sites deposited to microporous arrays and forming sensor platforms

Gole¹,

Laminack²,

Boudreaux³

2017

Front Nanosci Nanotech

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Novel nanostructured island sites are made to decorate a microporous/nanoporous array. These island sites are formed from a variety of easily produced nanostructured metal oxides deposited from solution. Sensor platforms are distinct from and do not require film-based coating. The nanostructure directing acidic metal oxide sites which vary in their Lewis acidity decorate micropores and control the electron transduction process. The interaction of analytes with these island sites varies in a predictable manner and can be modified through in-situ functionalization of their Lewis acidity. The microporous structure allows rapid Fickian diffusion of analytes to the active nanostructure island sites whose reversible interaction dominates the sensor response as it requires low energy consumption. Highly accurate repeat depositions are not required. We require that the island sites are deposited at sufficiently low concentration so as not to interact electronically with each other. The response time of these interfaces is more rapid than film-based depositions, which require a more lengthy diffusion time. The sensors are reversible. The nanoporous structure prevents sintering of these island centers at elevated temperatures. The concentration of detection centers can be made to produce an optimum matrix of enhanced sensor responses, force a dominant distinct analyte-interface physisorption (rather than chemisorption). The produced semiconductor interface is easily functionalized to create an enhanced range of nanoparticle semiconductor sites. The matrix provides a sensitive means of transferring electrons that are easily detected. The sensors operate at room temperature as well as elevated temperatures. Low energy magnetic field signal enhancement can be achieved with transition metals. Contaminated sensors can be readily rejuvenated. Pulsed mode operation ensures low analyte consumption and high analyte selectivity and further provides the ability to rapidly assess false positive signals using Fast Fourier Transfer techniques, Solar pumped sensors requiring low light levels (≤ 1 Watt) have been demonstrated. Water vapor contamination can be greatly if not entirely reduced. The modelling of sensor response with a new Fermi energy distribution -based response isotherm is found to be superior to other isotherms. Sensors operate can be made to operate efficiently for two gases simultaneously. Modes of extending these studies to multiple gas arrays are considered.

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“…In addition, the sensor platforms are capable of operation under extremely small magnetic field control [27]. The devices have the potential for adaptation to solar pumped sensing, micro-reactor, and solar assisted micro-reactors to achieve difficult but important chemical transformations, extending the development of basic heterogeneous catalyst sites and potential acid/base pairing combinations [28]. The technology has now been applied to the characterization of volatile liquids including the alcohols, acetone, chloroform, additional polar and nonpolar solvents, and more complex liquids including isoprene.…”

Section: Technology Featuresmentioning

confidence: 99%

New Generation Devices for Gas (Liquid) Sensing

Jl¹,

Laminack²

2016

J Phys Chem Biophys

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Light Enhanced Electron Transduction and Amplified Sensing at a Nanostructure Modified Semiconductor Interface

Cited by 21 publications

References 16 publications

How to Improve the Performance of Porous Silicon‐Based Gas and Vapor Sensors? Approaches and Achievements

How to Improve the Performance of Porous Silicon‐Based Gas and Vapor Sensors? Approaches and Achievements

Nanostructure directed interfaces created from nanoparticle island sites deposited to microporous arrays and forming sensor platforms

New Generation Devices for Gas (Liquid) Sensing

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