Matching the Transconductance Characteristics of CMOS ISFET Arrays by Removing Trapped Charge

This paper presents an approach for matching the transconductance characteristics of CMOS ISFET arrays by removing trapped charge. We describe how to design arrays of floating-gate ISFETs so that ultraviolet (UV) radiation and bulk-substrate biasing can be used to remove the random amount of trapped charge that accumulates on the gates during fabrication. The approach is applied directly to a prototype single-chip 2 2 array of ISFETs, which is designed and fabricated in a standard 0.35- CMOS process. By considering the transconductance characteristics of the 2 2 array before and after UV exposure, it is shown that the response can be matched after 10 h and that the ISFET threshold voltages converge to an equilibrium value of approximately 1 V. After matching, it is found that the ISFET array has a measured sensitivity of 46 mV/pH and can successfully image a change in the pH of a homogeneous electrolyte solution.

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