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 die is provided. The semiconductor die comprises a plurality of transistors arranged at a front side of a semiconductor substrate and an electrically conductive structure. A top surface of the electrically conductive structure is contacted at the front side of the semiconductor substrate and a bottom surface of the electrically conductive structure is contacted at a backside of the semiconductor substrate. Further, the semiconductor die comprises a backside metallization layer stack attached to the backside of the semiconductor substrate. A first portion of a wiring structure is formed in a first metallization layer of the backside metallization layer stack and a second portion of the wiring structure is formed in a second metallization layer of the backside metallization layer stack. Further, a tapered vertical connection is formed between the first portion of the wiring structure and the second portion of the wiring structure, wherein the first metallization layer is closer to the semiconductor substrate than the second metallization layer. A width of the tapered vertical connection increases towards the first metallization layer.

A system for printing metal interconnects on a substrate includes an anode substrate. A plurality of anodes are arranged on one side of the anode substrate with a first predetermined gap between adjacent ones of the plurality of anodes. A first plurality of fluid holes have one end located between the plurality of anodes. A plurality of control devices is configured to selectively supply current to the plurality of anodes, respectively. The anode substrate is arranged within a second predetermined gap of a work piece substrate including a metal seed layer. A ratio of the second predetermined gap to the first predetermined gap is in a range from 0.5:1 and 1.5:1. An array controller is configured to energize selected ones of the plurality of anodes using corresponding ones of the plurality of control devices while electrolyte solution is supplied through the first plurality of fluid holes between the anode substrate and the work piece substrate.

The present invention relates to a resist composition, especially for use in the production of electronic components via electron beam lithography. In addition to the usual base polymeric component (resist polymer), a secondary electron generator is included in resist compositions of the invention in order to promote secondary electron generation. This unique combination of components increases the exposure sensitivity of resists in a controlled fashion which facilitates the effective production of high-resolution patterned substrates (and consequential electronic components), but at much higher write speeds.

The present disclosure relates to a method to form an integrated chip including a filament via. In some embodiments, a lower metal layer comprising a first metal line and a second metal line is formed over a substrate. A filament dielectric layer is formed over the lower metal layer. An upper metal layer comprising a first metal line and a second metal line is formed over the filament dielectric layer. A first contact is formed over the upper metal layer. A filament formation bias is applied through the first contact to form a first filament via through the filament dielectric layer and electrically connecting the first metal line of the lower metal layer and the first metal line of the upper metal layer.

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.

A system and method for creating chip layout are described. In various implementations, a standard cell uses unidirectional tracks for power connections and signal routing. A single track of the metal one layer that uses a minimum width of the metal one layer is placed within a pitch of a single metal gate. The single track of the metal one layer provides a power supply reference voltage level or ground reference voltage level. This placement of the single track provides a metal one power post contacted gate pitch (CPP) of 1 CPP. To further reduce voltage droop, a standard cell uses dual height and half the width of a single height cell along with placing power posts with 1 CPP. The placement of the multiple power rails of the dual height cell allows alignment of the power rails with power rails of other standard cells.

A method includes forming a first multilayer interconnection structure over a carrier substrate. A first interlayer dielectric (ILD) layer is deposited over the first multilayer interconnection structure. A first source/drain contact is formed in the first ILD layer. After forming the first source/drain contact, a semiconductive layer is formed over the first source/drain contact and the first ILD layer. The semiconductive layer is patterned to form a semiconductor fin over the first source/drain contact. A gate structure is formed across the semiconductor fin. The semiconductor fin is patterned to form a first recess and a second recess in the semiconductor fin, such that the first recess exposes the first source/drain contact. First and second source/drain epitaxial structures are respectively formed in the first and second recesses of the semiconductor fin such that the first source/drain epitaxial structure is electrically connected to the first source/drain contact.

Semiconductor devices are provided. A semiconductor device includes a substrate. The semiconductor device includes a stack structure on the substrate. The stack structure includes a first insulating material and a second insulating material that is on the first insulating material. The semiconductor device includes a spacer that extends from a sidewall of the first insulating material of the stack structure to a portion of a sidewall of the second insulating material of the stack structure. Moreover, the semiconductor device includes a conductive line that is on the spacer. Methods of forming semiconductor devices are also provided.

A dielectric layer and a method of forming thereof. An opening defined in a dielectric layer and a wire deposited within the opening, wherein the wire includes a core material surrounded by a jacket material, wherein the jacket material exhibits a first resistivity ρ1 and the core material exhibits a second resistivity ρ2 and ρ2 is less than ρ1.