Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and a pair of polyimide layers disposed over the substrate so that they define an interface therebetween. One or both of the pair of polyimide layers have a trench that separates the interface from the one or more metal layers. The trench can be formed by etching the polyimide layer(s). A topcoat insulation layer is disposed over the one or more metal layers and polyimide layers. The topcoat insulation layer is impervious to moisture and the trench inhibits migration of moisture along the interface to the one or more metal layers, thereby preventing metal migration from the one or more metal layers along the interface.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and a pair of polyimide layers disposed over the substrate so that they define an interface therebetween. One or both of the pair of polyimide layers have a trench that separates the interface from the one or more metal layers. The trench can be formed by etching the polyimide layer(s). A topcoat insulation layer is disposed over the one or more metal layers and polyimide layers. The topcoat insulation layer is impervious to moisture and the trench inhibits migration of moisture along the interface to the one or more metal layers, thereby preventing metal migration from the one or more metal layers along the interface.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and a pair of polyimide layers disposed over the substrate so that they define an interface therebetween. One or both of the pair of polyimide layers have a trench that separates the interface from the one or more metal layers. The trench can be formed by etching the polyimide layer(s). A topcoat insulation layer is disposed over the one or more metal layers and polyimide layers. The topcoat insulation layer is impervious to moisture and the trench inhibits migration of moisture along the interface to the one or more metal layers, thereby preventing metal migration from the one or more metal layers along the interface.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and a pair of polyimide layers disposed over the substrate so that they define an interface therebetween. One or both of the pair of polyimide layers have a trench that separates the interface from the one or more metal layers. The trench can be formed by etching the polyimide layer(s). A topcoat insulation layer is disposed over the one or more metal layers and polyimide layers. The topcoat insulation layer is impervious to moisture and the trench inhibits migration of moisture along the interface to the one or more metal layers, thereby preventing metal migration from the one or more metal layers along the interface.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and one or more polyimide layers disposed over the substrate. Each polyimide layer can have a trench that separates a first portion of the polyimide layer that is adjacent a metal layer from a second portion of the polyimide layer. The trench(es) can be formed by etching the polyimide layer(s). A topcoat insulation layer can be disposed over the polyimide layers, a portion of the topcoat insulation layer disposed over the trench(es) define a moat. The topcoat insulation layer is impervious to moisture and the moat inhibits moisture from traveling along the one or more polymer interlevel dielectric layers from the second portion to the first portion.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and a pair of polyimide layers disposed over the substrate so that they define an interface therebetween. One or both of the pair of polyimide layers have a trench that separates the interface from the one or more metal layers. The trench can be formed by etching the polyimide layer(s). A topcoat insulation layer is disposed over the one or more metal layers and polyimide layers. The topcoat insulation layer is impervious to moisture and the trench inhibits migration of moisture along the interface to the one or more metal layers, thereby preventing metal migration from the one or more metal layers along the interface.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and a pair of polyimide layers disposed over the substrate so that they define an interface therebetween. One or both of the pair of polyimide layers have a trench that separates the interface from the one or more metal layers. The trench can be formed by etching the polyimide layer(s). A topcoat insulation layer is disposed over the one or more metal layers and polyimide layers. The topcoat insulation layer is impervious to moisture and the trench inhibits migration of moisture along the interface to the one or more metal layers, thereby preventing metal migration from the one or more metal layers along the interface.

Abstract: A semiconductor die includes a substrate layer, one or more metal layers disposed over the substrate layer, and one or more polyimide layers disposed over the substrate. Each polyimide layer can have a trench that separates a first portion of the polyimide layer that is adjacent a metal layer from a second portion of the polyimide layer. The trench(es) can be formed by etching the polyimide layer(s). A topcoat insulation layer can be disposed over the polyimide layers, a portion of the topcoat insulation layer disposed over the trench(es) define a moat. The topcoat insulation layer is impervious to moisture and the moat inhibits moisture from traveling along the one or more polymer interlevel dielectric layers from the second portion to the first portion.

Abstract: Gate structures for semiconductor devices include a silicon nitride layer, an electron beam evaporated tantalum nitride layer disposed on the silicon nitride layer, a first electron beam evaporated titanium layer disposed on the tantalum nitride layer, an electron beam evaporated gold layer deposited on the first titanium layer, and a second electron beam evaporated titanium layer deposited on the gold layer.

Abstract: Gate structures for semiconductor devices include a silicon nitride layer, an electron beam evaporated tantalum nitride layer disposed on the silicon nitride layer, a first electron beam evaporated titanium layer disposed on the tantalum nitride layer, an electron beam evaporated gold layer deposited on the first titanium layer, and a second electron beam evaporated titanium layer deposited on the gold layer.

Abstract: Gate metallization structures and methods for semiconductor devices are disclosed, wherein a refractory metal barrier is implemented to provide performance improvements. Transistor devices are disclosed having a compound semiconductor substrate and an electron-beam evaporated gate structure including a layer of tantalum nitride (TaNx), a layer of titanium (Ti) and a layer of gold (Au).

Abstract: Systems, devices and methods related to reactive evaporation of refractory materials. In some embodiments, a method for performing reactive evaporation can include positioning a volume of refractory material such as tantalum within an evaporation chamber and forming a vacuum environment therein. The method can further include providing a beam of electrons to the volume of refractory material to evaporate the refractory material into evaporated particles. The method can further include introducing a flow of reactive gas such as nitrogen into the evaporation chamber to allow at least some of the reactive gas to react with at least some of the evaporated particles of the refractory material. The flow of reactive gas can be selected such that a layer such as tantalum nitride formed on a substrate by deposition of the evaporated particles includes a range of a desirable property.

Abstract: Gate metallization structures and methods for semiconductor devices are disclosed, wherein a refractory metal barrier is implemented to provide performance improvements. Transistor devices are disclosed having a compound semiconductor substrate and an electron-beam evaporated gate structure including a layer of tantalum nitride (TaNx), a layer of titanium (Ti) and a layer of gold (Au).