A patterned backside stress compensation film having different stress in different sectors is formed on a backside of a substrate to reduce combination warpage of the substrate. The film can be formed by employing a radio frequency electrode assembly including plurality of conductive plates that are biased with different RF power and cause local variations in the plasma employed to deposit the backside film. Alternatively, the film may be deposited with uniform stress, and some of its sectors are irradiated with ultraviolet radiation to change the stress of these irradiated sectors. Yet alternatively, multiple backside deposition processes may be sequentially employed to deposit different backside films to provide a composite backside film having different stresses in different sectors.

Embodiments described and discussed herein provide methods for selectively depositing a metal oxides on a substrate. In one or more embodiments, methods for forming a metal oxide material includes positioning a substrate within a processing chamber, where the substrate has passivated and non-passivated surfaces, exposing the substrate to a first metal alkoxide precursor to selectively deposit a first metal oxide layer on or over the non-passivated surface, and exposing the substrate to a second metal alkoxide precursor to selectively deposit a second metal oxide layer on the first metal oxide layer. The method also includes sequentially repeating exposing the substrate to the first and second metal alkoxide precursors to produce a laminate film containing alternating layers of the first and second metal oxide layers. Each of the first and second metal alkoxide precursors contains a different metal selected from titanium, zirconium, hafnium, aluminum, or lanthanum.

The present disclosure describes a semiconductor structure and a method for forming the same. The semiconductor structure can include a substrate, first and second fin structures formed over the substrate, and an isolation structure between the first and second fin structures. The isolation structure can include a lower portion and an upper portion. The lower portion of the isolation structure can include a metal-free dielectric material. The upper portion of the isolation structure can include a metallic element and silicon.

A method includes providing a structure having a first channel member and a second channel member over a substrate. The first channel member is located in a first region of the structure and the second channel member is located in a second region of the structure. The method also includes forming a first oxide layer over the first channel member and a second oxide layer over the second channel member, forming a first dielectric layer over the first oxide layer and a second dielectric layer over the second oxide layer, and forming a capping layer over the second dielectric layer but not over the first dielectric layer. The method further includes performing an annealing process to increase a thickness of the second oxide layer under the capping layer.

A method for fabricating semiconductor device includes the steps of: forming a fin-shaped structure on a substrate; forming a gate dielectric layer on the fin-shaped structure; forming a gate electrode on the fin-shaped structure; performing a nitridation process to implant ions into the gate dielectric layer adjacent to two sides of the gate electrode; and forming an epitaxial layer adjacent to two sides of the gate electrode.

Methods of depositing a film using a plasma enhanced process are described. The method comprises providing continuous power from a power source connected to a microwave plasma source in a process chamber and a dummy load, the continuous power split into pulses having a first time and a second time defining a duty cycle of a pulse. The continuous power is directed to the microwave plasma source during the first time, and the continuous power is directed to the dummy load during the second time.

A semiconductor memory device includes a gate stack structure and a plurality of channel structures. The gate stack structure includes an insulating interlayer and a gate conductive layer that are alternately stacked. The plurality of channel holes is formed in the gate stack structure. The plurality of channel holes includes a fluorine-containing layer, a first blocking layer, and a charge-trapping layer. The fluorine-containing layer is formed on surfaces of the channel holes for forming the plurality of channel structures. The first blocking layer is formed on the fluorine-containing layer along the surfaces of the channel holes. The charge-trapping layer is formed on the first blocking layer along the surfaces of the channel holes.

Gate-all-around integrated circuit structures having fin stack isolation, and methods of fabricating gate-all-around integrated circuit structures having fin stack isolation, are described. For example, an integrated circuit structure includes a sub-fin structure on a substrate, the sub-fin structure having a top and sidewalls. An isolation structure is on the top and along the sidewalls of the sub-fin structure. The isolation structure includes a first dielectric material surrounding regions of a second dielectric material. A vertical arrangement of horizontal nanowires is on a portion of the isolation structure on the top surface of the sub-fin structure.

The present technology relates to an imaging element and a semiconductor chip that enable the imaging element to be shorter. A first chip including a photodiode, and a second chip including a circuit configured to process a signal from the photodiode are laminated, and an impurity layer is provided on a second surface opposite to a first surface of the second chip on which the first chip is laminated. The impurity layer is formed to have an impurity concentration higher than an impurity concentration of a semiconductor substrate constituting the second chip. In the present technology, for example, an imaging element that is configured by laminating a plurality of chips and is shorter and smaller can be applied.

A method for depositing an oxide film on a substrate by a cyclical deposition is disclosed. The method may include: depositing a metal oxide film over the substrate utilizing at least one deposition cycle of a first sub-cycle of the cyclical deposition process; and depositing a silicon oxide film directly on the metal oxide film utilizing at least one deposition cycle of a second sub-cycle of the cyclical deposition process. Semiconductor device structures including an oxide film deposited by the methods of the disclosure are also disclosed.