A film deposition method for depositing a silicon nitride film of selectively depositing on a flat surface of a substrate between minute recesses including a chlorine radical adsorbing step of supplying a chlorine containing gas that is activated onto a front surface of the substrate to cause the chlorine radical to be adsorbed entirely on the front surface of the substrate, a nitriding step of supplying a nitriding gas that is activated onto the substrate on which the chlorine radical adsorbs, causing the chlorine radical adsorbing on the flat surface, and nitride the flat surface from among the front surface of the substrate so as to form a silicon adsorption site, and a raw gas adsorbing step of supplying a raw gas that contains silicon and chlorine onto the substrate so as to cause the raw gas to adsorb onto the silicon adsorption site.

A semiconductor device includes: a sidewall insulating film; a gate electrode; source and drain regions; a first stress film; and a second stress film.

Warpage and breakage of integrated circuit substrates is reduced by compensating for the stress imposed on the substrate by thin films formed on a surface of the substrate. Particularly advantageous for substrates having a thickness substantially less than about 150 ?m, a stress-tuning layer is formed on a surface of the substrate to substantially offset or balance stress in the substrate which would otherwise cause the substrate to bend. The substrate includes a plurality of bonding pads on a first surface for electrical connection to other component.

In a semiconductor device, an insulating film is disposed between an upper surface of a substrate and a floating gate of a flash memory, a first oxide film is disposed directly above the floating gate, a silicon nitride film is disposed on an upper surface of the first oxide film, and a second oxide film made of silicon oxide film is disposed on an upper surface of the silicon nitride film.

A coating liquid for forming an oxide or oxynitride insulator film, the coating liquid including: A element; at least one selected from the group consisting of B element and C element; and a solvent, wherein the A element is at least one selected from the group consisting of Sc, Y, Ln (lanthanoid), Sb, Bi, and Te, the B element is at least one selected from the group consisting of Ga, Ti, Zr, and Hf, the C element is at least one selected from the group consisting of Group 2 elements in a periodic table, and the solvent includes at least one selected from the group consisting of an organic solvent having a flash point of 21? C. or more but less than 200? C. and water.

Warpage and breakage of integrated circuit substrates is reduced by compensating for the stress imposed on the substrate by thin films formed on a surface of the substrate. Particularly advantageous for substrates having a thickness substantially less than about 150 ?m, a stress-tuning layer is formed on a surface of the substrate to substantially offset or balance stress in the substrate which would otherwise cause the substrate to bend. The substrate includes a plurality of bonding pads on a first surface for electrical connection to other component.

Devices and methods of fabricating integrated circuit devices using semi-bidirectional patterning are provided. One method includes, for instance: obtaining an intermediate semiconductor device having a dielectric layer, a first, a second, and a third hardmask layer, and a lithography stack; patterning a first set of lines; patterning a second set of lines between the first set of lines; etching to define a combination of the first and second set of lines; depositing a second lithography stack; patterning a third set of lines in a direction perpendicular to the first and second set of lines; etching to define the third set of lines, leaving an OPL; depositing a spacer over the OPL; etching the spacer, leaving a vertical set of spacers; and etching the second hardmask layer using the third hardmask layer and the set of vertical spacers as masks.

Oxide growth of a gate dielectric layer that occurs between processes used in the fabrication of a gate dielectric structure can be reduced. The reduction in oxide growth can be achieved by maintaining the gate dielectric layer in an ambient effective to mitigate oxide growth of the gate dielectric layer between at least two sequential process steps used in the fabrication the gate dielectric structure. Maintaining the gate dielectric layer in an ambient effective to mitigate oxide growth also improves the uniformity of nitrogen implanted in the gate dielectric.

Provided is a technique of forming a film on a substrate by performing a cycle a predetermined number of times. The cycle includes: forming a first layer by supplying a gas containing a first element to the substrate, wherein the first layer is a discontinuous layer, a continuous layer, or a layer in which at least one of the discontinuous layer or the continuous layer is overlapped; forming a second layer including the first layer and a discontinuous layer including a second element stacked on the first layer; and forming a third layer by supplying a gas containing a third element to the substrate to modify the second layer under a condition where a modifying reaction of the second layer by the gas containing the third element is not saturated.

Provided is a technique of forming a film on a substrate by performing a cycle a predetermined number of times. The cycle includes: forming a first layer by supplying a gas containing a first element to the substrate, wherein the first layer is a discontinuous layer, a continuous layer, or a layer in which at least one of the discontinuous layer or the continuous layer is overlapped; forming a second layer including the first layer and a discontinuous layer including a second element stacked on the first layer; and forming a third layer by supplying a gas containing a third element to the substrate to modify the second layer under a condition where a modifying reaction of the second layer by the gas containing the third element is not saturated.