A method of making a semiconductor structure includes depositing a first passivation material between adjacent conductive elements on a substrate, wherein a bottommost surface of the first passivation material is coplanar with a bottommost surface of each of the adjacent conductive elements. The method further includes depositing a second passivation material on the substrate, wherein the second passivation material contacts a sidewall of each of the adjacent conductive elements and a sidewall of the first passivation material, a bottommost surface of the second passivation material is coplanar with the bottommost surface of each of the adjacent conductive elements, and the second passivation material is different from the first passivation material.

Semiconductor device including first semiconductor layer of a first conductivity type, second semiconductor layer of a second conductivity type at a surface of the first semiconductor layer, third semiconductor layer of the first conductivity type selectively provided at a surface of the second layer, and gate electrode embedded in a trench via a gate insulating film. The trench penetrates the second and third layers, and reaches the first layer. A thermal oxide film on the third layer has a thickness less than that of the gate insulating film. Also are an interlayer insulating film on the thermal oxide film, barrier metal on an inner surface of a contact hole selectively opened in the thermal oxide film and the interlayer insulating film, metal plug embedded in the contact hole on the barrier metal, and electrode electrically connected to the second and third layers via the barrier metal and the metal plug.

There is provided a technique that includes selectively doping a metal film with a dopant by performing: supplying a dopant-containing gas containing the dopant to a substrate in which the metal film and a film other than the metal film are formed on a film in which the dopant is doped; and removing the dopant-containing gas from above the substrate.

A method for fabricating a semiconductor device includes forming a line structure including a first contact plug on a semiconductor substrate and a conductive line on the first contact plug, forming a low-k layer having a first low-k, which covers a top surface and side walls of the line structure, performing a converting process on the low-k layer to form a non-converting portion adjacent to side walls of the first contact plug and maintains the first low-k and a converting portion adjacent to side walls of the conductive line and having a second low-k that is lower than the first low-k, and forming a second contact plug which is adjacent to the first contact plug with the non-converting portion therebetween while being adjacent to the conductive line with the converting portion therebetween.

Provided are a semiconductor device and a manufacturing method thereof. The semiconductor device includes a substrate, a semiconductor device structure, a doped dielectric layer and an interlayer dielectric layer. The substrate has a first surface and a second surface opposite to each other. The semiconductor device structure is disposed on the first surface. The doped dielectric layer is disposed on the second surface. The interlayer dielectric layer is disposed on the doped dielectric layer.

In a plasma processing method for plasma etching a silicon film or polysilicon film containing boron, the polysilicon film containing boron is etched by using a mixed gas of a halogen gas, a fluorine-containing gas, and a boron trichloride gas. According to plasma processing method, it is possible to improve the etching rate and reduce etching defects when plasma etching a silicon film or polysilicon film containing boron.

In a variety of processes for forming electronic devices that use spin-on dielectric materials, properties of the spin-on dielectric materials can be enhanced by curing these materials using plasma doping. For example, hardness and Young's modulus can be increased for the cured material. Other properties may be enhanced. The plasma doping to cure the spin-on dielectric materials uses a mechanism that is a combination of plasma ion implant and high energy radiation associated with the species ionized. In addition, physical properties of the spin-on dielectric materials can be modified along a length of the spin-on dielectric materials by selection of an implant energy and dopant dose for the particular dopant used, corresponding to a selection variation with respect to length.

A semiconductor device according to the present disclosure includes a bottom dielectric feature on a substrate, a plurality of channel members directly over the bottom dielectric feature, a gate structure wrapping around each of the plurality of channel members, two first epitaxial features sandwiching the bottom dielectric feature along a first direction, and two second epitaxial features sandwiching the plurality of channel members along the first direction.

In a variety of processes for forming electronic devices that use spin-on dielectric materials, properties of the spin-on dielectric materials can be enhanced by curing these materials using plasma doping. For example, hardness and Young's modulus can be increased for the cured material. Other properties may be enhanced. The plasma doping to cure the spin-on dielectric materials uses a mechanism that is a combination of plasma ion implant and high energy radiation associated with the species ionized. In addition, physical properties of the spin-on dielectric materials can be modified along a length of the spin-on dielectric materials by selection of an implant energy and dopant dose for the particular dopant used, corresponding to a selection variation with respect to length.

According to one embodiment, a semiconductor device includes first and second electrodes, first, second and third semiconductor regions, a first conductive portion, a gate electrode, and a second insulating portion. The first and second semiconductor regions are provided on the first semiconductor region. The third semiconductor regions are selectively provided respectively on the second semiconductor regions. The first conductive portion is provided inside the first semiconductor region with a first insulating portion interposed. The gate electrode is provided on the first conductive portion and the first insulating portion and separated from the first conductive portion. The gate electrode includes first and second electrode parts. The second insulating portion is provided between the first and second electrode parts. The second insulating portion includes first and second insulating parts. The second electrode is provided on the second and third semiconductor regions.