Title :
Effect of Back-Gate Biasing on Floating Electrolytes in Silicon-on-Insulator-Based Nanoribbon Sensors
Author :
Fernandes, P.G. ; Chapman, R.A. ; Seitz, O. ; Stiegler, H.J. ; Wen, H.-C. ; Chabal, Y.J. ; Vogel, E.M.
Author_Institution :
Texas Instrum. Inc., Dallas, TX, USA
fDate :
3/1/2012 12:00:00 AM
Abstract :
Silicon-on-insulator (SOI) field-effect-based sensors are often biased using a back substrate gate with biological/electrolytic solutions placed over the top sensor channel. For electrically floating electrolytes in contact with the SOI-buried oxide, we demonstrate that the electrolyte voltage is capacitively coupled to the applied back-gate bias resulting in a dual-gated sensor. Measured electrolyte voltages approach the constant back-gate voltage for real-time measurements, while a slower response is observed with dynamic measurements. Low subthreshold swings and threshold voltages are observed in both experimental and simulated - curves, consistent with strong coupling. Real-time constant voltage sensing can thus be performed at much lower operating voltages.
Keywords :
biosensors; electrolytes; field effect transistors; silicon-on-insulator; back-gate biasing; biological-electrolytic solutions; capacitive coupling; electrolyte voltage; field-effect-based sensors; floating electrolytes; nanoribbon sensors; real-time constant voltage sensing; silicon-on-insulator; subthreshold swings; threshold voltages; top sensor channel; Couplings; Logic gates; Nanowires; Sensor phenomena and characterization; Silicon; Voltage measurement; Biosensor; FET; capacitive coupling; pH; silicon-on-insulator (SOI);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2011.2179115
