Title :
Integrated VLSI potentiostat for cyclic voltammetry in electrolytic reactions
Author :
Narula, Harpreet S. ; Harris, John G.
Author_Institution :
Computational Neuro-Eng. Lab, Univ. of Florida, Gainesville, FL, USA
Abstract :
This paper describes a CMOS integrated potentiostatic control circuit. The design maintains a constant bias potential between the reference and working electrodes for an amperometric chemical sensor. A technique of converting input currents into time for amperometric measurements is proposed. Redox currents ranging from 1pA to 200nA can be measured with a maximum non-linearity of ±0.1% over this range. The design can be used to generate a cyclic voltammogram for an electrochemical reaction by sweeping the voltages across the range specified by the user. Analog inputs are processed and digital outputs are generated without requiring a power-hungry A/D converter. A prototype chip has been fabricated in the 0.5μm AMI CMOS process. Experimental results are reported showing the performance of the circuit as a chemical sensor.
Keywords :
CMOS integrated circuits; VLSI; electrochemical sensors; voltammetry (chemical analysis); 0.5 micron; 1E3 to 200 nA; A-D converter; AMI CMOS process; CMOS integrated circuit; amperometric chemical sensor; bias potential; cyclic voltammetry; cyclic voltammogram; electrochemical reaction; electrolytic reactions; integrated VLSI potentiostat; potentiostatic control circuit; prototype chip; redox currents; reference electrodes; working electrodes; Analog-digital conversion; Chemical sensors; Current measurement; Electrodes; Integrated circuit measurements; Power generation; Prototypes; Time measurement; Very large scale integration; Voltage;
Conference_Titel :
VLSI, 2004. Proceedings. IEEE Computer society Annual Symposium on
Print_ISBN :
0-7695-2097-9
DOI :
10.1109/ISVLSI.2004.1339552
