Dielectric film quality is one of the most important factors that will greatly impact device performance and reliability. Device level electrical analysis techniques for dielectric quality monitoring are highly needed. In this paper we present results using a new electrical AFM mode, scanning Microwave Impedance Microscopy (sMIM), for characterization of device oxide quality and for fault isolation. Devices with poor oxide quality show sMIM nano C-V and dC/dV hysteresis behavior during forward and reverse bias sweep. The sMIM capacitance sensitivity is below 1 aF allowing one to capture C-V spectra from the MOS structure formed by the gate and gate oxide with excellent signal/noise ratio and observe subtle variations between different sites.

Integrated circuit complexity and density are continuously increasing with the rapid progress of advanced technology nodes. The density of wafer acceptance test (WAT) pattern is also becoming higher as the device continuing to shrink. Failure analysis (FA) techniques have been developed to improve the precision of defect isolation. A technique with more precise fault isolation capability is needed when the test pattern density increased. In this paper we have isolated faults within a dense high Rc array by using conductive atomic force microscopy (C-AFM). The fault sites in the array can be located efficiently with nano-scale precision. Point contact I-V measurements provide a quantitative comparison of the fault sites.