Abstract: A semiconductor device having trap sites passivated with deuterium has enhanced immunity to hot carrier effects. The trap sites which are passivated with deuterium are encapsulated beneath a barrier film and are therefore resistant to having the deuterium diffuse away from the trap sites during subsequent high temperature processing operations.

Abstract: The present invention provides a method of forming an electromigration resisting layer in a semiconductor device. In an exemplary embodiment, the method comprises depositing a corrosion inhibitor comprising an organic ligand on a conductive layer of a semiconductor device wherein the conductive layer is susceptible to electromigration. The method further includes subjecting the corrosion inhibitor and the semiconductor device to a high temperature anneal to form an electromigration resisting layer on the conductive layer that reduces electromigration of the conductive layer.

Abstract: The present invention provides a method for determining a hot carrier lifetime of a transistor. In one embodiment, the method comprises the steps of determining an initial transconductance (gm1) of a transistor, and then, applying a stress voltage, which does not exceed a maximum breakdown voltage of the transistor, to the transistor to cause a transconductance degradation of the transistor, and then determining a subsequent transconductance (gm2) of the transistor. A hot carrier lifetime of the transistor can then be determined as a function of gm1 and gm2. Thus, the present invention provides a method in which the hot carrier lifetime is determined from sequential transconductance measurements without intervening, transistor characteristic tests that are typically conducted between the transconductance measurements that degrade the sensitivity of the gm measurement.

Abstract: A process sequence for forming a semiconductor device utilizes a passivation annealing process using deuterium which enhances immunity to hot carrier effects and extends device lifetime. The process sequence is carried out prior to the introduction of metal conductive films to the device. The process sequence includes a three-step passivation, de-passivation, re-passivation sequence and utilizes a barrier film to encapsulate deuterium molecules in the vicinity of a gate oxide, during the de-passivation operation.

Abstract: The electromigration characteristics of integrated circuit conductors are determined by passing a high current for a short period of time through an inventive test structure. This provides a rapid test in a more accurate manner than with the prior art SWEAT (Standard Wafer-level Electromigration Accelerated Test) structure. The test results have been found to be well correlated with long-term low current electromigration tests. A sensitive differential test may be implemented that determines the effects of topography features. The inventive test technique can be performed on every wafer lot, or even every wafer, so that adjustments to the wafer fabrication process can be rapidly implemented.