Thin Film Polycrystalline Silicon Nanowire Biosensors

Hakim, M. A.; Lombardini, Marta; Sun, Kai; Giustiniano, Francesco; Roach, Peter L.; Davies, Donna E.; Howarth, Peter H.; Planque, Maurits R.R. de; Morgan, Hywel; Ashburn, P.

doi:10.1021/nl2042276

Cited by 103 publications

(92 citation statements)

References 31 publications

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“…Nanostructured semiconductor films composed of thin layers of nanostructured objects such as nanoparticles, nanorods, nanowires or nanoporous networks with variable grain size and controlled porosity can exhibit properties superior to conventional thin films due to the deliberate engineering of nanoscale features into their structure and these films have practical applications in areas such as photovoltaics, electrochemical sensors, photoelectrochemical water splitting, biosensors and as antireflection layers. [1][2][3][4][5] Techniques such as thermal evaporation, 6 pulsed laser deposition, 7 DC and RF sputtering, 8,9 plasma evaporatihon, 10 sol-gel technique, 11 molecular beam epitaxy, 12 electrodeposition 13 and chemical vapor deposition 14 have been employed for the synthesis of nanostructured thin films of different semiconductors. Another technologically logical strategy for creating nanostructured films is the alignment of nanoparticle building blocks into ordered superstructures with non-resistive inter-particle contacts by bottom-up approaches and is one of the recent key topics in the area of nanomaterials.…”

Section: Introductionmentioning

confidence: 99%

Grain size tuning of nanostructured Cu2O films through vapour phase supersaturation control and their characterization for practical applications

Anu

Khadar

2015

AIP Advances

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A strategy for creating nanostructured films is the alignment of nanoparticles into ordered superstructures as living organisms synthesize biomaterials with superior physical properties using nanoparticle building blocks. We synthesized nanostructured films of Cu2O of variable grain size by establishing the condition of supersaturation for creation of nanoparticles of copper which deposited as nanograined films and which was then oxidized. This technique has the advantage of being compatible with conventional vacuum processes for electronic device fabrication. The Cu2O film samples consisted of a secondary structure of spherical particles of almost uniform size, each particle being an agglomerate of primary nanocrystals. Fractal analysis of the AFM images of the samples is carried out for studying the aggregation mechanism. Grain size tuning of the nanostructured Cu2O films has been studied using XRD, and micro-Raman and photoluminescence spectroscopy.

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Section: Introductionmentioning

confidence: 99%

Grain size tuning of nanostructured Cu2O films through vapour phase supersaturation control and their characterization for practical applications

Anu

Khadar

2015

AIP Advances

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“…However, when compared to conventional ISFETs, top-down silicon nanowires require costly e-beam or deep UV lithography and Silicon-on-Insulator (SOI) substrates [6,7]. To significantly reduce the fabrication cost, we have proposed a thin-film technology (TFT) alternative using polysilicon nanowires formed by reactive-ion etching (RIE) through a spacer etch technology [8]. However, the formation of polysilicon and gate dielectrics require high temperature processes such as silicon recrystallization and thermal oxidation.…”

Section: Introductionmentioning

confidence: 99%

Low-cost top-down zinc oxide nanowire sensors through a highly transferable ion beam etching for healthcare applications

Zeimpekis

Ditshego

et al. 2016

Microelectronic Engineering

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Abstract-In this work, we demonstrate a wafer-level zinc oxide (ZnO) nanowire fabrication process using ion beam etching and a spacer etch technique. The proposed process can accurately define nanowires without an advanced photolithography and provide a high yield over a 6-inch wafer. The fabricated nanowires are 36 nm wide and 86 nm thick and present excellent transistor characteristics. The pH sensitivity using a liquid gate was found to be 46.5 mV/pH, while the pH sensitivity using a bottom gate showed a sensitivity of 366 mV/pH, which is attributed to the capacitance coupling between the top-and bottom-gates. The maximum process temperature used in the fabrication of the nanowire sensors is optimized to be 200°C (after wet oxidation) which makes it applicable to low-cost substrates such as glass and plastic. The Ion Beam Etching (IBE) process in this work is shown to be highly transferable and can therefore be directly used to form nanowires of different materials, such as polysilicon and molybdenum disulfide, by only an adjustment of the etch time.

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“…Several groups [13]- [16] have reported top-down approaches for the fabrication of polysilicon nanowires using variants of thin film transistor technology. In our previous work [15] we reported a technology for producing rectangular polysilicon nanowire biosensors and demonstrated the detection of two inflammatory biomarkers, the proteins interleukin-8 and tumor necrosis factor-alpha, over a wide range of concentrations and with excellent sensitivity.…”

Section: Introductionmentioning

confidence: 99%

Three-Mask Polysilicon Thin-Film Transistor Biosensor

Zeimpekis

Lombardini

Ditshego

et al. 2014

IEEE Trans. Electron Devices

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Abstract-Biosensors are commonly produced using an SOI CMOS process and advanced lithography to define nanowires. In this work, a simpler and cheaper junctionless 3-mask process is investigated, which uses thin film technology to avoid the use of SOI wafers, in-situ doping to avoid the need for ion implantation and direct contact to a low doped polysilicon film to eliminate the requirement for heavily doped source/drain contacts. Furthermore, TiN is used to contact the biosensor source/drain because it is a hard, resilient material that allows the biosensor chip to be directly connected to a printed circuit board without wire bonding. pH sensing experiments, combined with device modelling, are used to investigate the effects of contact and series resistance on the biosensor performance, as this is a key issue when contacting directly to low doped silicon. It is shown that in-situ phosphorus doping concentrations in the range 4×10

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Thin Film Polycrystalline Silicon Nanowire Biosensors

Cited by 103 publications

References 31 publications

Grain size tuning of nanostructured Cu2O films through vapour phase supersaturation control and their characterization for practical applications

Grain size tuning of nanostructured Cu2O films through vapour phase supersaturation control and their characterization for practical applications

Low-cost top-down zinc oxide nanowire sensors through a highly transferable ion beam etching for healthcare applications

Three-Mask Polysilicon Thin-Film Transistor Biosensor

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