Abstract: The present invention discloses a simple and convenient method for fabricating a capacitor device with BiCMOS processes. An electrode of the capacitor device formed according to the present invention is an ion doping region formed in an epitaxy layer so that the thickness of the dielectric layer of the capacitor device decreased relative to a specific ion concentration. Accordingly, the capacitor device formed therein has a high capacitance and good performance.

Abstract: A method for measuring both buried strap and deep trench leakage currents in DRAM cell capacitors. By keeping the voltages on both plates of the capacitor equal, the buried strap leakage current (IBS) may be isolated and measured. A range of voltages is applied to a terminal of an associated transistor to obtain a corresponding range of buried strap leakage currents. An unequal voltage is next applied across the capacitor, and a total leakage current is measured. By applying a known potential to a substrate of the transistor during this total leakage current measurement, the associated IBS may be determined. Next, the IBS is subtracted from the measured total leakage current to obtain the deep trench leakage current (IDT).

Abstract: A method is used to fully extract coupling coefficients of a flash memory cell by a GIDL manner. The flash memory cell is composed of a substrate, a drain region, source region, a control gate and a floating gate. The method keeps the source voltage Vs and the substrate voltage Vb fixed. The drain voltage Vd and the control gate voltage are varied. Then, measuring a GIDL current obtains a first coefficient ratio of the drain coupling coefficient ad to the gate coupling &agr;cg, that is, &agr;d/&agr;cg. Similarly, keeping the drain voltage Vd and the substrate voltage Vb fixed and varying the source voltage Vs and the control gate voltage Vcg, a second coefficient ratio of the source coupling coefficient &agr;s to the gate coupling coefficient &agr;cg, that is, &agr;s/&agr;cg.

Abstract: This invention relates to the characterization of integrated circuit devices and more particularly to an improved method for monitoring for unacceptable kink behavior, in the threshold voltage characteristics of FET devices, that can be caused by a tendency for reduced gate oxide thickness and reduced substrate doping concentration, along the length of channel regions bounded by STI. This is achieved by comparing a pair of drain current versus gate voltage characteristics, as a function of two values of substrate voltage. Relative voltage shifts between the two curves are compared at a value of drain current that is well below the kink and at a value of drain current that is well above the kink. The quantitative degree of kink behavior is determined by how much greater the voltage shift, corresponding to the value of drain current well above the kink, exceeds the voltage shift, corresponding to the value of drain current well below the kink.