A 3DIC structure includes a die, a conductive terminal, and a dielectric structure. The die is bonded to a carrier through a bonding film. The conductive terminal is disposed over and electrically connected to the die. The dielectric structure comprises a first dielectric layer and a second dielectric layer. The first dielectric layer is disposed laterally aside the die. The second dielectric layer is disposed between the first dielectric layer and the bonding film, and between the die and the boding film. A second edge of the second dielectric layer is more flat than a first edge of the first dielectric layer.

A 3DIC structure includes a die, a conductive terminal, and a dielectric structure. The die is bonded to a carrier through a bonding film. The conductive terminal is disposed over and electrically connected to the die. The dielectric structure comprises a first dielectric layer and a second dielectric layer. The first dielectric layer is disposed laterally aside the die. The second dielectric layer is disposed between the first dielectric layer and the bonding film, and between the die and the boding film. A second edge of the second dielectric layer is more flat than a first edge of the first dielectric layer.

A method of fabricating a semiconductor device includes forming a hard mask layer over a substrate. A multi-layer resist is formed over the hard mask layer. The multi-layer resist is etched to form a plurality of openings in the multi-layer resist to expose a portion of the hard mask layer. Ion are directionally provided at an angle to the multi-layer resist to predominately contact sidewalls of the plurality of openings in the multi-layer resist rather than the hard mask layer. In one embodiment, the multi-layer resist is directionally etched by directing etch ions at an angle to predominately contact sidewalls of the plurality of openings in the multi-layer resist rather than the hard mask layer. In another embodiment, the multi-layer resist is directionally implanted by directing implant ions at an angle to predominately contact sidewalls of the plurality of openings in the multi-layer resist rather than the hard mask layer.

Techniques for generating enhanced inductors and other electronic devices are presented. A device generator component (DGC) performs directed-self assembly (DSA) co-polymer deposition on a circular guide pattern formed in low-k dielectric film, and DSA annealing to form two polymers in the form of alternating concentric rings; performs a loop cut in the concentric rings to form concentric segments; fills the cut portion with insulator material; selectively removes first polymer, fills the space with low-k dielectric, and planarizes the surface; selectively removes the second polymer, fills the space with conductive material, and planarizes the surface; deposits low-k film on top of the concentric segments and insulator material that filled the loop cut portion; forms vias in the low-k film, wherein each via spans from an end of one segment to an end of another segment; and fills vias with conductive material to form conductive connectors to form substantially spiral conductive structure.

A bipolar transistor is supported by a single-crystal silicon substrate including a collector contact region. A first epitaxial region forms a collector region of a first conductivity type on the collector contact region. A second epitaxial region forms a base region of a second conductivity type. Deposited semiconductor material forms an emitter region of the first conductivity type. The collector region, base region and emitter region are located within an opening formed in a stack of insulating layers that includes a sacrificial layer. The sacrificial layer is selectively removed to expose a side wall of the base region. Epitaxial growth from the exposed sidewall forms a base contact region.

A semiconductor structure includes a substrate; first and second fins extending from the substrate and oriented lengthwise generally along a first direction; an isolation feature over the substrate and separating bottom portions of the first and the second fins; first and second epitaxial semiconductor features over the first and the second fins, respectively; and a first dielectric feature sandwiched between the first and the second epitaxial semiconductor features. A maximum width of the first dielectric feature is smaller than a width of the isolation feature between the first and the second fins along a second direction perpendicular to the first direction.

A method for modeling planarization performance of a given material includes patterning a first photoresist layer over a first material deposited over a substrate. The method also includes etching portions of the first material exposed by the patterned first photoresist layer to create a patterned topography of the first material comprising two or more different design macros in two or more different regions. The method further includes coating the given material over the patterned topography of the first material, patterning a second photoresist layer over the given material, measuring the critical dimension of a metrology feature in each of the two or more different regions, and utilizing the measured critical dimensions of the metrology feature in the two or more different regions to generate a model of the planarization performance of the given material by relating the measured critical dimensions to focal planes of the given material.

Provided is a silicon carbide semiconductor device that is further reduced in resistance. Silicon carbide semiconductor device includes silicon carbide semiconductor layer disposed on a first main surface of substrate, electrode layer containing polysilicon disposed on the silicon carbide semiconductor layer with first insulating layer interposed between the electrode layer and the silicon carbide semiconductor layer, second insulating layer that covers the silicon carbide semiconductor layer and the electrode layer, first silicide electrode that is located in first opening part formed in the first insulating layer and the second insulating layer and forms ohmic contact with a part of the silicon carbide semiconductor layer, and second silicide electrode that is located in second opening part formed in the second insulating layer and is in contact with a part of the electrode layer.

A method of forming semiconductor devices includes providing a substrate with a patterned material layer formed thereon, forming a material layer on the patterned material layer, wherein the material layer has a first region with a lower top surface and a second region with a higher top surface, forming a flowable material layer on the material layer, wherein the flowable material layer exposes at least a portion of the second region of the material layer, removing the exposed portion of the second region of the material layer with the flowable material layer as a stop layer, removing the flowable material layer, and planarizing the material layer.

Techniques for generating enhanced inductors and other electronic devices are presented. A device generator component (DGC) performs directed-self assembly (DSA) co-polymer deposition on a circular guide pattern formed in low-k dielectric film, and DSA annealing to form two polymers in the form of alternating concentric rings; performs a loop cut in the concentric rings to form concentric segments; fills the cut portion with insulator material; selectively removes first polymer, fills the space with low-k dielectric, and planarizes the surface; selectively removes the second polymer, fills the space with conductive material, and planarizes the surface; deposits low-k film on top of the concentric segments and insulator material that filled the loop cut portion; forms vias in the low-k film, wherein each via spans from an end of one segment to an end of another segment; and fills vias with conductive material to form conductive connectors to form substantially spiral conductive structure.