Abstract: A semiconductor device includes: a ferroelectric capacitor that is provided above a base substrate and includes a first electrode, a ferroelectric film provided on the first electrode and a second electrode provided on the ferroelectric film; a stopper film that covers a top surface of the second electrode of the ferroelectric capacitor; a hydrogen barrier film that covers a top surface and a side surface of the stopper film and a side surface of the ferroelectric capacitor; an interlayer dielectric film that covers the hydrogen barrier film and the base substrate; a contact hole that penetrates the interlayer dielectric film, the hydrogen barrier film and the stopper film and exposes the second electrode; a barrier metal that covers the second electrode exposed in the contact hole and an inner wall surface of the contact hole and is composed of a conductive material having hydrogen barrier property; and a plug conductive section that is embedded in the contact hole and conductively connects to the barrier me

Abstract: A semiconductor device includes: a ferroelectric capacitor including a first electrode provided above a substrate, a ferroelectric film provided on the first electrode and a second electrode provided on the ferroelectric film; a hydrogen barrier film that covers a top surface and a side surface of the ferroelectric capacitor; an interlayer dielectric film that covers the ferroelectric capacitor and the substrate; a contact hole that penetrates the interlayer dielectric film and the hydrogen barrier film and exposes the second electrode; a barrier metal that covers a top surface of the second electrode exposed in the contact hole and an inner wall surface of the contact hole and is composed of a conductive material having hydrogen barrier property; and a plug conductive section that is embedded in the contact hole and conductively connects to the barrier metal, wherein the inner wall surface of the contact hole at the hydrogen barrier film includes a concave curved surface facing the interior of the contact ho

Abstract: A method for manufacturing a semiconductor device includes the steps of: forming a ferroelectric capacitor having a first electrode, a ferroelectric film and a second electrode successively laminated on a base substrate; forming a first interlayer dielectric film that covers the ferroelectric capacitor and the base substrate; forming a material film for a second interlayer dielectric film covering the first interlayer dielectric film; exposing the first interlayer dielectric film located on the ferroelectric capacitor by polishing an upper surface side of the material film for the second interlayer dielectric film by a CMP method; forming a contact hole that penetrates the first interlayer dielectric film and exposes the second electrode, after the step of exposing the first interlayer dielectric film; and forming in the contact hole a plug conductive section that conductively connects to the second electrode, wherein the first interlayer dielectric film has a lower polishing rate in the CMP method compared t

Abstract: A semiconductor device is equipped with a plug conductive layer formed in an interlayer dielectric film on a substrate, and a conductive member provided on the plug conductive layer. The semiconductor device further includes a spacer dielectric film formed on the interlayer dielectric film and having a hole section connecting to the plug conductive layer; and a spacer conductive section embedded in the hole section of the spacer dielectric film, connected to the plug conductive layer and connected to the conducive member, wherein the spacer conductive section is formed from a conductive material having self-orientation characteristic, and a top surface of the spacer dielectric film and a top surface of the spacer conductive section are planarized.

Abstract: An alignment mark for a semiconductor device is provided. The alignment mark defines a plane pattern and includes a conductive layer embedded in a recessed section provided in an insulation layer, and an oxidation barrier layer provided on the conductive layer, wherein an area occupancy ratio of the recessed section in the plane pattern is 5% or greater.

Abstract: An alignment mark for a semiconductor device is provided. The alignment mark defines a plane pattern and includes a conductive layer embedded in a recessed section provided in an insulation layer, and an oxidation barrier layer provided on the conductive layer, wherein an area occupancy ratio of the recessed section in the plane pattern is 5% or greater.

Abstract: A method for manufacturing a ferroelectric memory includes the steps of forming a driving transistor on a semiconductor substrate, forming a first interlayer dielectric film that covers the driving transistor on the semiconductor substrate, forming a first hydrogen barrier film on the first interlayer dielectric film, and forming a ferroelectric capacitor electrically connected to the driving transistor on the first hydrogen barrier film, wherein hydrogen sintering treatment is conducted between the step of forming the driving transistor and the step of forming the first hydrogen barrier film.

Abstract: A semiconductor device is provided in which high breakdown voltage transistors and low voltage driving transistors are formed on the same substrate. The device includes a semiconductor layer, first element isolation regions for defining a high breakdown voltage transistor forming region in the semiconductor layer, second element isolation regions including trench dielectric layers for defining a low voltage driving transistor forming region in the semiconductor layer, high breakdown voltage transistors formed in the high breakdown voltage transistor forming region, low voltage driving transistors formed in the low voltage driving transistor forming region, and offset dielectric layers for alleviating the electric field of the high breakdown voltage transistors formed in the high breakdown voltage transistor forming region, wherein upper ends of the offset dielectric layers are beak shaped.

Abstract: A semiconductor device manufacturing method is provided including: forming a first impurity layer that becomes first wells in a high breakdown voltage transistor forming region in a semiconductor layer; forming a second impurity layer that becomes offset regions in the high breakdown voltage transistor forming region; forming the first wells and the offset regions by diffusing impurities of the first and second impurity layers by heat treating the semiconductor layer; forming element isolation regions by a trench element isolation method in the semiconductor layer, after forming the first wells and the offset regions; forming first gate dielectric layers in the high breakdown voltage transistor forming region; forming second wells in a low voltage driving transistor forming region in the semiconductor layer; forming second gate dielectric layers in the low voltage driving transistor forming region; and forming gate electrodes in the high breakdown voltage transistor forming region and the low voltage driving

Abstract: A semiconductor device is provided in which high breakdown voltage transistors and low voltage driving transistors are formed on the same substrate. The device includes a semiconductor layer, first element isolation regions for defining a high breakdown voltage transistor forming region in the semiconductor layer, second element isolation regions including trench dielectric layers for defining a low voltage driving transistor forming region in the semiconductor layer, high breakdown voltage transistors formed in the high breakdown voltage transistor forming region, low voltage driving transistors formed in the low voltage driving transistor forming region, and offset dielectric layers for alleviating the electric field of the high breakdown voltage transistors formed in the high breakdown voltage transistor forming region, wherein upper ends of the offset dielectric layers are beak shaped.

Abstract: An alignment mark for a semiconductor device is provided. The alignment mark defines a plane pattern and includes a conductive layer embedded in a recessed section provided in an insulation layer, and an oxidation barrier layer provided on the conductive layer, wherein an area occupancy ratio of the recessed section in the plane pattern is 5% or greater.

Abstract: A semiconductor device includes a semiconductor layer, an insulated-gate field effect transistor provided in the semiconductor layer, an etching stopper film provided above the insulated-gate field effect transistor, and an interlayer insulating layer provided above the etching stopper film; the insulated-gate field effect transistor including a gate insulating layer provided on the semiconductor layer, a gate electrode provided on the gate insulating layer, and an impurity region that constitutes a source region or a drain region provided in the semiconductor layer; wherein a removed region made by removing the etching stopper film is provided in at least part of an area that is located outside the gate insulating layer and above an area at a position other than a position sandwiched by the gate insulating layer and the impurity region.

Abstract: A method for manufacturing the semiconductor device of which a transistor and a MNOS type memory transistor, each of which has a different gate withstand voltage and drain withstand voltage, are included in the same semiconductor layer.

Abstract: A fabrication method of a semiconductor device which has on the same semiconductor layer a transistor with a different high voltage gate as well as a high voltage drain and an MNOS memory transistor.

Abstract: A method of manufacturing a semiconductor device that has a high-breakdown-voltage transistor, a low-voltage driving transistor and a MONOS type memory transistor includes a step of forming a stack film that includes at least an oxide silicon layer and a nitride silicon layer over a high-breakdown-voltage transistor forming region where the high-breakdown-voltage transistor is formed, a low-voltage driving transistor forming region where the low-voltage driving transistor is formed and a MONOS type memory transistor forming region where the MONOS type memory transistor is formed in a semiconductor layer, a step of removing the stack film formed in a first gate insulating layer forming region of the high-breakdown-voltage transistor and a step of forming a first gate insulating layer in the high-breakdown-voltage transistor forming region by thermal oxidation.

Abstract: A fabrication method of a semiconductor device which has on the same semiconductor layer a transistor with a different high voltage gate as well as a high voltage drain and an MNOS memory transistor.

Abstract: A method for manufacturing the semiconductor device of which a transistor and a MNOS type memory transistor, each of which has a different gate withstand voltage and drain withstand voltage, are included in the same semiconductor layer.

Abstract: A semiconductor device of the present invention is provided with a high breakdown voltage transistor 100 and a low voltage driving transistor 200 on a same semiconductor layer 10 comprising: the semiconductor layer 10; an offset insulating layer 20 comprising a LOCOS layer for an electric field relaxation of the high breakdown voltage transistor 100 provided on the semiconductor layer 10; and a trench insulating layer 28 for defining a forming region of the low voltage driving transistor 200 provided on the semiconductor layer 10, wherein at least a part of the upper surface of the offset insulating layer 20 is nearly as high as the surface of the semiconductor layer 10.

Abstract: A first conductive layer, a dielectric layer and a second conductive layer are continuously deposited, the second conductive layer is patterned and the upper electrode 13a of the MIM capacitor C is formed, and subsequently, a protective layer is deposited on the entire face. Next, the protective layer is patterned, and at the same time, the dielectric layer is also patterned with the same mask and the capacitive insulation layer 12a of the MIM capacitor is formed. Next, using the protective layer as a hard mask, the first conductive layer is patterned, and the lower electrode 11a and the wiring 11b of the MIM capacitor are formed. Because the MIM capacitor C is formed as the above, the outer circumferential shape of the lower electrode 11a is generally the same as that of the capacitive insulation layer 12a.

Abstract: A semiconductor device manufacturing method is provided including: forming a first impurity layer that becomes first wells in a high breakdown voltage transistor forming region in a semiconductor layer; forming a second impurity layer that becomes offset regions in the high breakdown voltage transistor forming region; forming the first wells and the offset regions by diffusing impurities of the first and second impurity layers by heat treating the semiconductor layer; forming element isolation regions by a trench element isolation method in the semiconductor layer, after forming the first wells and the offset regions; forming first gate dielectric layers in the high breakdown voltage transistor forming region; forming second wells in a low voltage driving transistor forming region in the semiconductor layer; forming second gate dielectric layers in the low voltage driving transistor forming region; and forming gate electrodes in the high breakdown voltage transistor forming region and the low voltage driving