According to one embodiment, a semiconductor device 1 includes an Si substrate 11, an inductor 12 formed in wiring layers disposed above the Si substrate 11, and a shield 13 formed so as to surround the inductor 12, in which the shield 13 includes metals 105 to 109 formed in, among the wiring layers, a layer in which the inductor 12 is formed and a layer above that layer, and a silicide 104 formed between the Si substrate 11 and the wiring layers above the Si substrate 11.

Methods of producing metal-containing thin films with low impurity contents on a substrate by atomic layer deposition (ALD) are provided. The methods preferably comprise contacting a substrate with alternating and sequential pulses of a metal source chemical, a second source chemical and a deposition enhancing agent. The deposition enhancing agent is preferably selected from the group consisting of hydrocarbons, hydrogen, hydrogen plasma, hydrogen radicals, silanes, germanium compounds, nitrogen compounds, and boron compounds. In some embodiments, the deposition-enhancing agent reacts with halide contaminants in the growing thin film, improving film properties.

Embodiments herein relate to a package using aluminum oxide as an adhesion and high-thermal conductivity layer with a buildup layer having a first side and a second side opposite the first side, a first trace applied to the first side of the buildup layer, an aluminum oxide layer coupled with the first trace and an exposed area of the first side of the buildup layer, a lamination buildup layer coupled with the aluminum oxide layer on a side of the aluminum oxide layer opposite the buildup layer, wherein the lamination buildup layer includes one or more vias to the trace, and a seed layer coupled with the lamination buildup layer. Other embodiments may be described and/or claimed.

A trench MOSFET with closed cell layout having shielded gate is disclosed, wherein closed gate trenches surrounding a deep trench in each unit cell and the shielded gate disposed in the deep trench. Trenched source-body contacts are formed between the closed gate trenches and the deep trench. The deep trench has square, rectangular, circle or hexagon shape.

A method of making a monolithic three dimensional NAND string which contains a semiconductor channel and a plurality of control gate electrodes, includes selectively forming a plurality of discrete charge storage regions using atomic layer deposition. The plurality of discrete charge storage regions includes at least one of a metal or an electrically conductive metal oxide.

Metallic layers can be selectively deposited on one surface of a substrate relative to a second surface of the substrate. In some embodiments, the metallic layers are selectively deposited on a first metallic surface relative to a second surface comprising silicon. In some embodiments the reaction chamber in which the selective deposition occurs may optionally be passivated prior to carrying out the selective deposition process. In some embodiments selectivity of above about 50% or even about 90% is achieved.

A semiconductor structure includes a first alternating stack of first insulating layers and first electrically conductive layers having first stepped surfaces and located over a substrate, a second alternating stack of second insulating layers and second electrically conductive layers having second stepped surfaces, and memory opening fill structures extending through the alternating stacks. A contact via assembly is provided, which includes a first conductive via structure vertically extending from a top surface of one of the first electrically conductive layers through a subset of layers within the second alternating stack and through the second retro-stepped dielectric material portion, an insulating spacer located within an opening through the subset of layers, and a second conductive via structure laterally surrounding the insulating spacer and contacting a second electrically conductive layer.

Methods of fabricating semiconductor devices, such as monolithic three-dimensional NAND memory string devices, include selectively forming semiconductor material charge storage regions over first material layers exposed on a sidewall of a front side opening extending through a stack comprising an alternating plurality of first and second material layers using a difference in incubation time for the semiconductor material on the first material relative to an incubation time for the semiconductor material on the second material of the stack. In other embodiments, a silicon layer is selectively deposited on silicon nitride on a surface having at least one first portion including silicon oxide and at least one second portion including silicon nitride using a difference in an incubation time for the silicon on silicon nitride relative to an incubation time for the silicon on silicon oxide.

An alkaline etchant containing a quaternary ammonium hydroxide, water, and an inhibitory substance for inhibiting contact between hydroxide ions generated from the quaternary ammonium hydroxide and objects P1 to P3 to be etched is prepared. The prepared etchant is supplied to a substrate in which the polysilicon-containing objects P1 to P3 to be etched and objects O1 to O3 not to be etched, which are different from the objects P1 to P3 to be etched, are exposed, thereby etching the objects P1 to P3 to be etched while preventing the objects O1 to O3 not to be etched from being etched.

A silicon film forming method of forming a silicon film in a recess with respect to a target substrate having on its surface an insulating film in which the recess is formed. The method includes (a) forming a first silicon film filling the recess by supplying a Silicon raw material gas onto the target substrate, (b) subsequently, etching the first silicon film by supplying a halogen-containing etching gas onto the target substrate such that surfaces of the insulating film on the target substrate and on an upper portion of an inner wall of the recess are exposed and such that the first silicon film remains in a bottom portion of the recess, and (c) subsequently, growing a second silicon film in a bottom-up growth manner on the first silicon film that remains in the recess by supplying a Silicon raw material gas onto the target substrate after the etching.