A laterally diffused MOS (LDMOS) device includes a substrate having a p-epi layer thereon. A p-body region is in the p-epi layer. An ndrift (NDRIFT) region is within the p-body region providing a drain extension region, and a gate dielectric layer is formed over a channel region in the p-body region adjacent to and on respective sides of a junction with the NDRIFT region, and a patterned gate electrode on the gate dielectric. A DWELL region is within the p-body region, sidewall spacers are on sidewalls of the gate electrode, a source region is within the DWELL region, and a drain region is within the NDRIFT region. The p-body region includes a portion being at least one 0.5 m wide that has a net p-type doping level above a doping level of the p-epi layer and a net p-type doping profile gradient of at least 5/m.

The present examples relate to a semiconductor device used in an electric device or high voltage device. The present examples improve R.sub.sp by minimizing drift region resistance by satisfying breakdown voltage by improving the structure of a drift region through which current flows in a semiconductor device to provide optimal results. Moreover, a high frequency application achieves useful results by reducing a gate charge Q.sub.g for an identical device pitch to that of an alternative technology.

A semiconductor integrated circuit device has a first N-channel type high withstanding-voltage MOS transistor and a second N-channel type high withstanding-voltage MOS transistor formed on an N-type semiconductor substrate. The first N-channel type high withstanding-voltage transistor includes a third N-type low-concentration impurity region containing arsenic having a depth smaller than a P-type well region in a drain region within the P-type well region, and the second N-channel type high withstanding-voltage MOS transistor includes a fourth N-type low-concentration impurity region that is adjacent to the P-type well region and has a bottom surface in contact with the N-type semiconductor substrate. In this manner, the high withstanding-voltage NMOS transistors are capable of operating at 30 V or higher and are integrated on the N-type semiconductor substrate.

A semiconductor device manufacturing method improves the yield of manufacturing semiconductor devices. There are provided an insulating film for covering multiple bonding pads, a first protective film over the insulating film, and a second protective film over the first protective film. In semiconductor chips, multiple electrode layers are coupled electrically to each of the bonding pads via first openings formed in the insulating film and second openings formed in the first protective film. Multiple bump electrodes are coupled electrically to each of the electrode layers via third openings formed in the second protective film. In pseudo chips, the second openings are formed in the first protective film and the third openings are formed in the second protective film. The insulating film is exposed at the bottom of the second openings coinciding with the third openings. A protective tape is applied to a principal plane to cover the bump electrodes.

A laterally diffused MOS (LDMOS) device includes a substrate having a p-epi layer thereon. A p-body region is in the p-epi layer. An ndrift (NDRIFT) region is within the p-body region providing a drain extension region, and a gate dielectric layer is formed over a channel region in the p-body region adjacent to and on respective sides of a junction with the NDRIFT region, and a patterned gate electrode on the gate dielectric. A DWELL region is within the p-body region, sidewall spacers are on sidewalls of the gate electrode, a source region is within the DWELL region, and a drain region is within the NDRIFT region. The p-body region includes a portion being at least one 0.5 m wide that has a net p-type doping level above a doping level of the p-epi layer and a net p-type doping profile gradient of at least 5/m.

A semiconductor device includes a P-type semiconductor substrate, a plurality of N-type buried diffusion layers that are arranged in the semiconductor substrate, an N-type first semiconductor layer that is arranged in a first region on a first buried diffusion layer, an N-type second semiconductor layer that is arranged in a second region on a second buried diffusion layer, an N-type first impurity diffusion region that surrounds the first region in plan view, a P-type second impurity diffusion region that is arranged in the second semiconductor layer, an N-type third impurity diffusion region that is arranged in the second semiconductor layer, an N-type fourth impurity diffusion region that is arranged in the first semiconductor layer. The second region is a region in which an N-type impurity diffusion region that has a higher impurity concentration than the second semiconductor layer cannot be arranged.

A semiconductor device according to one embodiment of the present invention comprises: a semiconductor substrate having a main surface; a noise source element formed at the main surface of the semiconductor substrate; a protection target element formed at the main surface of the semiconductor substrate; an n type region disposed between the noise source element and the protection target element; and a p type region disposed between the noise source element and the protection target element and electrically connected to the n type region. The n type region and the p type region are adjacent to each other on the main surface of the semiconductor substrate in a direction intersecting a direction from the noise source element toward the protection target element.

A test key and a method for checking the window of a doped region using the test key are provided in the present invention. The test key includes a P-type first well region on a substrate, a P-type substrate region adjacent to the first well region, a N-type first doped region partially overlapping the first well region, two P-type second doped regions at two opposite sides of the first well region, a N-type second well region surrounding the first doped region, the substrate region and the two second doped regions, and a plurality of test pads above the above-identified region.

A semiconductor device including an insulating film in a first region of a semiconductor substrate; a first impurity region and a second impurity region of a first conductivity type, each of the regions including a part located deeper than the insulating film in contact with each other, and the insulating film being sandwiched by the first and second impurity regions in planar view in the first region of the semiconductor substrate; a metal silicide film on the first impurity region and in Schottky junction with the first impurity region; a first impurity of the first impurity region having a peak of a concentration profile deeper than a bottom of the insulating film; a second impurity of the second impurity region having a concentration higher than a concentration of the first impurity in a part of the first impurity region shallower than the bottom of the insulating film.

A method for fabricating a semiconductor device having a substantially undoped channel region includes providing a substrate having a fin extending from the substrate. An in-situ doped layer is formed on the fin. By way of example, the in-situ doped layer may include an in-situ doped well region formed by an epitaxial growth process. In some examples, the in-situ doped well region includes an N-well or a P-well region. After formation of the in-situ doped layer on the fin, an undoped layer is formed on the in-situ doped layer, and a gate stack is formed over the undoped layer. The undoped layer may include an undoped channel region formed by an epitaxial growth process. In various examples, a source region and a drain region are formed adjacent to and on either side of the undoped channel region.