Alan Blake scite author profile

All existing transistors are based on the use of semiconductor junctions formed by introducing dopant atoms into the semiconductor material. As the distance between junctions in modern devices drops below 10 nm, extraordinarily high doping concentration gradients become necessary. Because of the laws of diffusion and the statistical nature of the distribution of the doping atoms, such junctions represent an increasingly difficult fabrication challenge for the semiconductor industry. Here, we propose and demonstrate a new type of transistor in which there are no junctions and no doping concentration gradients. These devices have full CMOS functionality and are made using silicon nanowires. They have near-ideal subthreshold slope, extremely low leakage currents, and less degradation of mobility with gate voltage and temperature than classical transistors.

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Ion-Transfer Electrochemistry at Arrays of Nanointerfaces between Immiscible Electrolyte Solutions Confined within Silicon Nitride Nanopore Membranes

Scanlon

Strutwolf

Blake

et al. 2010

Anal. Chem.

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Ion transfer across interfaces between immiscible liquids provides a means for the nonredox electrochemical detection of ions. Miniaturization of such interfaces brings the benefits of enhanced mass transport. Here, the electrochemical behavior of geometrically regular arrays of nanoscale interfaces between two immiscible electrolyte solutions (nanoITIES arrays) is presented. These were prepared by supporting the two electrolyte phases within silicon nitride membranes containing engineered arrays of nanopores. The nanoITIES arrays were characterized by cyclic voltammetry of the interfacial transfer of tetraethylammonium cation (TEA(+)) between the aqueous phase and the gelled organic phase. Effects of pore radius, pore center-to-center separation, and number of pores in the array were examined. The ion transfer produced apparent steady-state voltammetry on the forward and reverse sweeps at all experimentally accessible scan rates and at all nanopore array designs. However, background-subtraction of the voltammograms revealed the evolution of a peak-shaped response on the reverse sweep with increasing scan rate, indicative of pores filled with the organic phase to a certain extent. The steady-state voltammetric behavior at the nanoITIES arrays on the forward sweep for arrays with significant diffusion zone overlap between adjacent nanoITIES is indicative of the dominance of radial diffusion to interfaces at the edge of the arrays over linear diffusion to interfaces within the arrays. This implies that nanoITIES arrays, which occupy an overall area of micrometer dimensions, behave like a single microITIES of corresponding area to the nanoITIES array.

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SOI gated resistor: CMOS without junctions

et al. 2009

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The curious case of thin-body Ge crystallization

Duffy

Shayesteh

McCarthy

et al. 2011

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Microneedle-based electrodes with integrated through-silicon via for biopotential recording

O’Mahony

Pini

Blake

et al. 2012

Sensors and Actuators A: Physical

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Microscopic gel–liquid interfaces supported by hollow microneedle array for voltammetric drug detection

Vázquez

Herzog

O’Mahony³

et al. 2014

Sensors and Actuators B: Chemical

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This report describes a method for integration of a gel-liquid interface in hollow microneedles compatible with minimally invasive, electrochemical detection of drugs in vivo. The electrochemical sensor was characterised using cyclic voltammetry of tetraethyl ammonium. The experimental work demonstrated the detection of propranolol as a representative drug in physiological buffer with the microneedle system. A calibration curve for propranolol was built from measurements with differential pulse stripping voltammetry, indicating a sensitivity of 43 nA µM-1 , a limit of detection of 50 nM and a linear range between 50-200 nM.

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Evaluation of Vibrational PiezoMEMS Harvester That Scavenges Energy From a Magnetic Field Surrounding an AC Current-Carrying Wire

Olszewski

Houlihan

Blake

et al. 2017

J. Microelectromech. Syst.

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A Silicon-based MEMS Vibrating Mesh Nebulizer for Inhaled Drug Delivery

Olszewski

MacLoughlin

Blake

et al. 2016

Procedia Engineering

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Alan Blake

Nanowire transistors without junctions

Ion-Transfer Electrochemistry at Arrays of Nanointerfaces between Immiscible Electrolyte Solutions Confined within Silicon Nitride Nanopore Membranes

SOI gated resistor: CMOS without junctions

The curious case of thin-body Ge crystallization

Microneedle-based electrodes with integrated through-silicon via for biopotential recording

Microscopic gel–liquid interfaces supported by hollow microneedle array for voltammetric drug detection

Evaluation of Vibrational PiezoMEMS Harvester That Scavenges Energy From a Magnetic Field Surrounding an AC Current-Carrying Wire

A Silicon-based MEMS Vibrating Mesh Nebulizer for Inhaled Drug Delivery

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