A semiconductor device includes a polysilicon substrate, a first oxide layer formed on the polysilicon substrate, an oxygen-rich nitride layer formed on the first oxide layer, a second oxide layer formed on the oxygen-rich nitride layer, and an oxygen-poor nitride layer formed on the second oxide layer.

A method of controlling the thickness of gate oxides in an integrated CMOS process which includes performing a two-step gate oxidation process to concurrently oxidize and therefore consume at least a first portion of the cap layer of the NV gate stack to form a blocking oxide and form a gate oxide of at least one metal-oxide-semiconductor (MOS) transistor in the second region, wherein the gate oxide of the at least one MOS transistor is formed during both a first oxidation step and a second oxidation step of the gate oxidation process.

A memory film and a semiconductor channel can be formed within each memory opening that extends through a stack including an alternating plurality of insulator layers and sacrificial material layers. After formation of backside recesses through removal of the sacrificial material layers selective to the insulator layers, a metallic barrier material portion can be formed in each backside recess. A cobalt portion can be formed in each backside recess. Each backside recess can be filled with a cobalt portion alone, or can be filled with a combination of a cobalt portion and a metallic material portion including a material other than cobalt.

To enhance the performance of a semiconductor device. In a method for manufacturing a semiconductor device, a metal film is formed over a semiconductor substrate having an insulating film formed on a surface thereof, and then the metal film is removed in a memory cell region, whereas, in a part of a peripheral circuit region, the metal film is left. Next, a silicon film is formed over the semiconductor substrate, then the silicon film is patterned in the memory cell region, and, in the peripheral circuit region, the silicon film is left so that an outer peripheral portion of the remaining metal film is covered with the silicon film. Subsequently, in the peripheral circuit region, the silicon film, the metal film, and the insulating film are patterned for forming an insulating film portion formed of the insulating film, a metal film portion formed of the metal film, and a conductive film portion formed of the silicon film.

An MISFET has a gate electrode formed on a semiconductor substrate via a gate insulating film, and a source region and a drain region formed inside the semiconductor substrate so as to sandwich the gate electrode. And, a first silicide layer is formed on surfaces of the source region and the drain region, and a second silicide layer is formed on a surface of the gate electrode. Each of the first silicide layer and the second silicide layer is made of a first metal and silicon, and further contains a second metal different from the first metal. And, a concentration of the second metal inside the second silicide layer is lower than a concentration of the second metal inside the first silicide layer.

A semiconductor manufacturing method includes forming a first film on an upper surface of a substrate. The semiconductor manufacturing method includes forming concave portions extending from an upper surface of the first film to below the upper surface of the substrate. The method includes forming a second film from bottom surfaces of the concave portions to a first position in the concave portions between the upper surface of the first film and the upper surface of the substrate. The method includes forming a third film in the concave portions to cover side walls of the concave portions and an upper surface of the second film. The method includes grinding the third film to expose the second film. The method includes removing the second film. The method includes forming a fourth film from the bottom surfaces of the concave portions to at least a lower surface of the third film.

The present invention provides a semiconductor device that has a shorter distance between the bit lines and easily achieves higher storage capacity and density. The semiconductor device includes: first bit lines and an insulating layer that is provided between the first bit lines and in a groove. First faces of the first bit lines are aligned on a first line and second faces of the first bit lines are aligned on a second line. A first face of the insulating layer is disposed at a third line that is a first distance from the first line in a first direction and a second face of the insulating layer is disposed at a fourth line that is a second distance from the second line in a second direction.

A non-volatile memory includes a substrate region, a barrier layer, an N-type well region, an isolation structure, a first gate structure, a first sidewall insulator, a first P-type doped region, a second P-type doped region and an N-type doped region. The isolation structure is arranged around the N-type well region and formed over the barrier layer. The N-type well region is surrounded by the isolation structure and the barrier layer. Consequently, the N-type well region is an isolation well region. The first gate structure is formed over a surface of the N-type well region. The first sidewall insulator is arranged around the first gate structure. The first P-type doped region, the second P-type doped region and the N-type doped region are formed under the surface of the N-type well region.

An example memory device includes a channel positioned between and electrically connecting a first diffusion region and a second diffusion region, and a tunnel dielectric layer, a multi-layer charge trapping layer, and a blocking dielectric layer disposed between the gate structure and the channel. The multi-layer charge trapping layer includes a first dielectric layer disposed abutting a second dielectric layer and an anti-tunneling layer disposed between the first and second dielectric layers. The anti-tunneling layer includes an oxide layer. The first dielectric layer includes oxygen-rich nitride and the second dielectric layer includes oxygen-lean nitride.

Unwanted erosion of dielectric materials around a backside contact trench can be avoided or minimized employing an aluminum oxide liner. An aluminum oxide liner can be formed inside an insulating material layer in a backside contact trench to prevent collateral etching of the insulating material at an upper portion of the backside contact trench during an anisotropic etch that forms an insulating spacer. Alternatively, an aluminum oxide layer can be employed as a backside blocking dielectric layer. An upper portion of the aluminum oxide layer can be converted into an aluminum compound layer including aluminum and a non-metallic element other than oxygen at an upper portion of the trench, and can be employed as a protective layer during formation of a backside contact structure.