Abstract :
Summary form only given. A theoretical and experimental study was carried out on a novel microfabricated device, an ionic liquid-channel field-effect transistor (ILCFET). The work was conducted to determine the feasibility of developing monolithic chemical analyzers for ions in solution. In these analyzers the ions are differentiated by mobility. The ILCFET provides a starting point to fabricate, understand, and model the more complex analyzers. The ILCFET resembles a MOSFET, except that the current flowing from the source to the drain is carried in thin channels by ions of a liquid electrolyte. The gate voltage induces an electric field, transverse to the current flow, which controls the channel conductance. Unlike MOSFETs, in which the channel conductance depends on one mobile charge carrier, holes or electrons, the ILCFET channel conductance depends on the concentrations of both cations and anions
Keywords :
chemical sensors; electrochemical analysis; electrolytic ion mobility; field effect transistors; ILCFET; anion concentration; cation concentration; channel conductance; electric field; gate voltage; ionic liquid-channel field-effect transistor; ions in solution; liquid electrolyte; microfabricated device; monolithic chemical analyzers; Capacitance; Electrodes; Electron emission; FETs; Field emitter arrays; Kinetic energy; Semiconductor diodes; Semiconductor films; Silicon; Surface contamination;
