A method of manufacturing a radio frequency switch includes the steps of: forming a first silicide layer on a second conductive or semiconductor layer; forming a third insulating layer on the first layer; forming a cavity in the third insulating layer reaching the first silicide layer; forming a fourth metal layer in the cavity in contact with the first silicide layer; performing a non-oxidizing annealing; and filling the cavity with a conductive material. The first silicide layer is provided on one or more of the gate, source, and drain of a transistor forming the radio frequency switch.

In the present disclosure, a semiconductor structure includes an Mx-1 layer including a first dielectric layer and first metal features, wherein the first metal features include a first set of first metal features in a first region and a second set of first metal features in a second region, wherein the first set has a first pattern density and the second set has a second pattern density being greater than the first pattern density. The structure further includes a Vx layer disposed over the Mx-1 layer, the Vx layer including first vias contacting the first set of the first metal features. The structure further includes an Mx layer disposed over the Vx layer, the Mx layer including a fuse element, wherein the fuse element has a first thickness in the first region less than a second thickness in the second region.

A method includes forming a dielectric layer on a substrate; forming a first spiral electrode, a second spiral electrode, and a spiral common electrode in the dielectric layer, the first spiral electrode extending in a first spiral path, the second spiral electrode extending in a second spiral path, and the spiral common electrode extending in a third spiral path laterally between the first and second spiral paths.

A semiconductor device includes a capacitor. The capacitor includes a first electrode and a second electrode disposed in a first metal layer. The first electrode has a first end and a second end, and the first electrode has a spiral pattern extending outwards from the first end to the second end. The first electrode and the second electrode have a substantially equal spacing therebetween.

In a described example, an apparatus includes: a semiconductor die having a device side surface; bond pads on the semiconductor die on the device side surface; post connects having a proximate end on the bond pads and extending from the bond pads to a distal end, the diameter of the post connects at the proximate end being the same as the diameter of the post connects at the distal end; polyimide material covering sides of the post connects and covering at least a portion of the bond pads; and solder bumps on the distal end of the post connects.

A semiconductor device includes a capacitor. The capacitor includes a first electrode and a second electrode disposed in a first metal layer. The first electrode has a first end and a second end, and the first electrode has a spiral pattern extending outwards from the first end to the second end. The first electrode and the second electrode have a substantially equal spacing therebetween.

In the present disclosure, a semiconductor structure includes an Mx-1 layer including a first dielectric layer and first metal features, wherein the first metal features include a first set of first metal features in a first region and a second set of first metal features in a second region, wherein the first set has a first pattern density and the second set has a second pattern density being greater than the first pattern density. The structure further includes a Vx layer disposed over the Mx-1 layer, the Vx layer including first vias contacting the first set of the first metal features. The structure further includes an Mx layer disposed over the Vx layer, the Mx layer including a fuse element, wherein the fuse element has a first thickness in the first region less than a second thickness in the second region.

The present disclosure describes methods of forming a colored conductive ribbon for a solar module which includes combining a conductive ribbon with a channeled ribbon holder, applying a color coating to at least the conductive ribbon within the channel, curing the color coating on the conductive ribbon, and separating the conductive ribbon from the channeled holder.

The present disclosure describes methods of forming a colored conductive ribbon for a solar module which includes combining a conductive ribbon with a channeled ribbon holder, applying a color coating to at least the conductive ribbon within the channel, curing the color coating on the conductive ribbon, and separating the conductive ribbon from the channeled holder.

According to one embodiment, a wiring fabrication method includes pressing a first template including a first recessed portion and a second recessed portion provided at a bottom of the first recessed portion against a first film to form a first pattern including a first raised portion, corresponding to the first recessed portion, and a second raised portion, corresponding to the second recessed portion. The second raised portion protrudes from the first raised portion once formed. After forming the first pattern, a first wiring, corresponding to the first raised portion, and a via, corresponding to the second raised portion, is formed using the first pattern.