Exceeding Nernst limit (59mV/pH): CMOS-based pH sensor for autonomous applications

A highly sensitive field-effect sensor immune to environmental potential fluctuation is proposed. The sensor circuit consists of two sensors each with a charge sensing field effect transistor (FET) and an extended sensing gate (SG). By enlarging the sensing gate of an extended gate ISFET, a remarkab...

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Bibliographic Details
Main Authors: Parizi, K. B., Yeh, A. J., Poon, A. S. Y., Wong, H. S. P.
Format: Conference Proceeding
Language:English
Subjects:
Electrodes
Field effect transistors
Fluctuations
Logic gates
Noise
Sensitivity
Sensors
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Summary:A highly sensitive field-effect sensor immune to environmental potential fluctuation is proposed. The sensor circuit consists of two sensors each with a charge sensing field effect transistor (FET) and an extended sensing gate (SG). By enlarging the sensing gate of an extended gate ISFET, a remarkable sensitivity of 130mV/pH is achieved, exceeding the conventional Nernst limit of 59mV/pH. The proposed differential sensing circuit consists of a pair of matching n-channel and p-channel ion sensitive sensors connected in parallel and biased at a matched transconductance bias point. Potential fluctuations in the electrolyte appear as common mode signal to the differential pair and are cancelled by the matched transistors. This novel differential measurement technique eliminates the need for a true reference electrode such as the bulky Ag/AgCl reference electrode and enables the use of the sensor for autonomous and implantable applications.
ISSN:0163-1918
2156-017X
DOI:10.1109/IEDM.2012.6479098