A method of forming an arrangement of active and inactive fins on a substrate, including forming at least three vertical fins on the substrate, forming a protective liner on at least three of the at least three vertical fins, removing at least a portion of the protective liner on the one of the at least three of the at least three of vertical fins, and converting the one of the at least three of the at least three vertical fins to an inactive vertical fin.

A system and method for treating a substrate in a reaction chamber. A transfer chamber is arranged between a first lock and a second lock, wherein the second lock is provided between the transfer chamber and the reaction chamber. A substrate is transferred into the transfer chamber through the first lock, and the first lock is closed. In a next step, the transfer chamber is flooded with the same gas as in the reaction chamber and the pressure and temperature of the gaseous atmosphere in the transfer chamber is controlled to be the same as in the reaction chamber. Then, the second lock is opened and the substrate is transferred from the transfer chamber into the reaction chamber to treat the substrate. A computer program product for carrying out the above method.

A nonplanar circuit device having a strain-producing structure disposed under the channel region is provided. In an exemplary embodiment, the integrated circuit device includes a substrate with a first fin structure and a second fin structure disposed on the substrate. An isolation feature trench is defined between the first fin structure and the second fin structure. The circuit device also includes a strain feature disposed on a horizontal surface of the substrate within the isolation feature trench. The strain feature may be configured to produce a strain on a channel region of a transistor formed on the first fin structure. The circuit device also includes a fill dielectric disposed on the strain feature within the isolation feature trench. In some such embodiments, the strain feature is further disposed on a vertical surface of the first fin structure and on a vertical surface of the second fin structure.

A method of fabricating transistors with a vertical gate in trenches includes lithographing to form wide trenches; forming dielectric in the trenches and filling the trenches with flowable material; and lithography to form narrow trenches within the wide trenches thereby exposing well or substrate before epitaxially growing semiconductor strips atop substrate exposed by the narrow trenches; removing the flowable material; growing gate oxide on the semiconductor strip; forming gate conductor over the gate oxide and into gaps between the epitaxially-grown semiconductor strips and the dielectric; masking and etching the gate conductor; and implanting source and drain regions. The transistors formed have semiconductor strips extending from a source region to a drain region, the semiconductor strips within trenches, the trench walls insulated with a dielectric, a gate oxide formed on both vertical walls of the semiconductor strip; and gate material between the dielectric and gate oxide.

Embodiments described herein relate to plasma processes. A plasma process includes generating a plasma containing negatively charged oxygen ions. A substrate is exposed to the plasma. The substrate is disposed on a pedestal while being exposed to the plasma. While exposing the substrate to the plasma, a negative direct current (DC) bias voltage is applied to the pedestal to repel the negatively charged oxygen ions from the substrate.

A double-RESURF LDMOS transistor has a gate dielectric structure including a shallow field “bump” oxide region and an optional raised dielectric structure that provides a raised support for the LDMOS transistor's polysilicon gate electrode. Fabrication of the shallow field oxide region is performed through a hard “bump” mask and controlled such that the bump oxide extends a minimal depth into the LDMOS transistor's drift (channel) region. The hard “bump” mask is also utilized to produce an N-type drift (N-drift) implant region and a P-type surface effect (P-surf) implant region, whereby these implants are “self-aligned” to the gate dielectric structure. The N-drift implant is maintained at Vdd by connection to the LDMOS transistor's drain diffusion. An additional Boron implant is utilized to form a P-type buried layer that connects the P-surf implant to the P-body region of the LDMOS transistor, whereby the P-surf implant is maintained at 0V.

Systems and methods for performing depth-dependent oxidation modeling and depth-dependent etch modeling in a virtual fabrication environment are discussed. More particularly, a virtual fabrication environment models, as part of a process sequence, oxidant dispersion in a depth-dependent manner and simulates the subsequent oxidation reaction based on the determined oxidant thickness along an air/silicon interface. Further the virtual fabrication environment performs depth-dependent etch modeling as part of a process sequence to determine etchant concentration and simulate the etching of material along an air/material interface.

A method for manufacturing a semiconductor device includes forming a semiconductor layer on a substrate, the semiconductor layer including a first semiconductor material and a second semiconductor material, patterning the semiconductor layer to form a preliminary active pattern, oxidizing at least two sidewalls of the preliminary active pattern to form an oxide layer on each of the at least two sidewalls of the preliminary active pattern, at least two upper patterns and a semiconductor pattern being formed in the preliminary active pattern when the oxide layers are formed, the semiconductor pattern being disposed between the at least two upper patterns, and removing the semiconductor pattern to form an active pattern, the active pattern including the at least two upper patterns. A concentration of the second semiconductor material in each of the at least two upper patterns is higher than a concentration of the second semiconductor material in the semiconductor pattern.

Methods of forming integrated circuit devices containing memory cells over a first region of a semiconductor substrate and gate structures over a second region of the semiconductor substrate recessed from the first region. The methods include forming a metal that is common to both the memory cells and the gate structures.

A semiconductor substrate (1) includes a region (AR3) between a region (AR1) and a region (AR2), a control gate electrode (CG) is formed on an upper surface (TS1) of the region (AR1), and a memory gate electrode (MG) is formed on an upper surface (TS2) of the region (AR2). The upper surface (TS2) is lower than the upper surface (TS1), and the region (AR3) has a connection surface (TS3) connecting the upper surface (TS1) and the upper surface (TS2). An end (EP1) of the connection surface (TS3) which is on the upper surface (TS2) side is arranged closer to the memory gate electrode (MG) than an end (EP2) of the connection surface (TS3) which is on the upper surface (TS1) side, and is arranged lower than the end (EP2).