Basics of MIS-type gas sensors with thin nanoporous silicon

Skryshevsky, V. A.

doi:10.1109/elnano.2014.6873967

Cited by 6 publications

(4 citation statements)

References 19 publications

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“…However, for porous silicon, such a situation is not realized. It was established that for porous silicon, Φ b is only weakly dependant on Φ M , and, as shown previously, the material parameters of porous silicon are more important factors affecting the properties of the M-PSi contacts (Scheen et al 2012;Skryshevsky 2014). Therefore, I-V characteristics differ significantly from the ideal behavior and the more general I-V relation with the ideality factor (n) is applicable.…”

Section: Ohmic Contactsmentioning

confidence: 94%

“…In addition, the porous silicon has a very large effective surface area and, consequently, a large concentration of dangling bonds that may act as the high concentration of carrier traps in PS (Remaki et al 2003;Skryshevsky 2014). Therefore, the porous layers with high resistance impart a major contribution to the large value of dynamic series resistance of the metal/PSi/c-Si/metal structure.…”

Section: Ohmic Contactsmentioning

confidence: 97%

See 1 more Smart Citation

The Mechanism of Metal-Assisted Etching of Silicon

2016

Porous Silicon: From Formation to Application: Formation and Properties, Volume One

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Section: Ohmic Contactsmentioning

confidence: 94%

Section: Ohmic Contactsmentioning

confidence: 97%

The Mechanism of Metal-Assisted Etching of Silicon

2016

Porous Silicon: From Formation to Application: Formation and Properties, Volume One

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“…Пористий кремній наразі активно використовується в електроніці та сенсориці, як антивідбиваюче покриття для фотоелементів, матеріал для виготовлення світлодіодів, чутливе покриття для УФ-датчиків та різноманітних сенсорів [3], [4].…”

Section: вступunclassified

Features of photoluminescence and transmission spectra of thin film porous silicon layers on insulator substrates

Dusheiko¹,

Koltsov²,

Obukhova³

2017

Mìkrosist. elektron. akust.

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Кафедра Мікроелектроніки ФЕЛ Національний технічний університет України «Київський політехнічний інститут імені Ігоря Сікорського» kpi.ua Київ, Україна Реферат-В роботі проведено дослідження спектрів пропускання і фотолюмінісценції шарів пористого кремнію отриманих хімічним травленням з тонких плівок кремнію на основах з полі кору та сапфіру. Показано що характер спектру поглинання таких структур залежить як від умов отримання плівок кремнію так і від матеріалу основи. В результаті дослідження спектрів фотолюмінісценції що збуджувалась УФ-випромінюванням (285 нм) показано, що окрім характерних для пористого кремнію піків в області 600-700 нм в тонких шарах пористого кремнію спостерігаються піки в короткохвильовій області. Бібл. 13, рис. 8. Ключові словапористий кремній; фотолюмінесценція; хімічне травлення; спектр; тонкі плівки.

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“…On the other hand use of porous silicon increase active area surface and porous layer by itself can be used as detection structure of the sensor [6]- [12]. In this work, a combination of two nanostructuresporous silicon and metal nanoparticles was used in the aim to determine best combination and technological process for hydrogen peroxide sensor formation.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Peroxide Measurements by MISFET and LET Structures with Rear Porous Silicon Layer and Metallic Nanoparticles

Kutova

Obukhova

Dusheiko

et al. 2018

Mìkrosist. elektron. akust.

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In the paper hydrogen peroxide MISFET and LET sensor performance is investigated. As hydrogen peroxide is a product of many chemical reactions, especially biological reactions, peroxide sensors are now widely used for detection of another. In this work, a combination of two nanostructures that are now used for hydrogen peroxide detection-porous silicon and metal nanoparticles was used. A MISFET (metal-insulator-semiconductor field effect transistor) was chosen as the basic sensor but unlike conventional FET sensors sensitive area was formed on the rear side of the sensor. In the aim to simplify sensor structure a LET (lighteffect transistor) with sensitive area on the rear side was also tested. LET structure was produced by the same technology as FET, but then subgate system was removed by chemical etching. Porous silicon was formed by metal-assisted chemical etching (MACE) that consists of two stages. During the first stage, metallic nanoparticles are deposited on the surface by chemical or physical deposition. During second one these particles become catalysts of chemical reaction and pores are formed under them. Pore shape and density depend on both stages conditions. Formation of porous silicon on the rear side leads to changes of substrate charge and influence gate-source curve as well as drain-source curve. Drain current for FET with an active area is lower due to the negative charge accumulated in porous silicon thanks to high tie connections concentration. Dependence of LET drain current on LED intensity (current) is almost linear and drain-source curves are similar to FET structure ones. FET samples with porous silicon/Pt and LET samples with porous silicon/Ag both show more stable and well-defined dependence of drain current on hydrogen peroxide concentration then samples without porous layer. All sensors have saturation of drain current from concentrations of hydrogen peroxide about 0.5-1% and dependence on concentration is first order exponential decay, obviously due to saturation of working area by reaction products or heating effect of hydrogen peroxide decomposition. In concentration range up to 0.3%

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Basics of MIS-type gas sensors with thin nanoporous silicon

Cited by 6 publications

References 19 publications

The Mechanism of Metal-Assisted Etching of Silicon

The Mechanism of Metal-Assisted Etching of Silicon

Features of photoluminescence and transmission spectra of thin film porous silicon layers on insulator substrates

Hydrogen Peroxide Measurements by MISFET and LET Structures with Rear Porous Silicon Layer and Metallic Nanoparticles

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