Semiconductor device and method for fabricating the same

In a semiconductor substrate of a first conductivity type, first to third drain offset regions of a second conductivity type are formed in that order in a bottom up manner. A body region of the first conductivity type is formed partly in the second drain offset region and partly in the third drain offset region. The second drain offset region has a lower impurity concentration than the first and third drain offset regions. A curvature portion of the body region is located in the second drain offset region.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to Japanese Patent Application No. 2008-292592 filed on Nov. 14, 2008, the disclosure of which including the specification, the drawings, and the claims is hereby incorporated by reference in its entirety.

BACKGROUND

The present disclosure relates to semiconductor devices, such as high voltage MOS (metal oxide semiconductor) FETs (field effect transistors), and methods for fabricating the same.

In recent years, as the number of elements integrated into a single semiconductor integrated circuit device has been increased, semiconductor integrated circuit devices have been required to integrate high voltage MOS devices, low voltage CMOS (complementary metal oxide semiconductor) devices, bipolar devices, and the like on a single substrate. Characteristics required for high voltage MOS devices include high breakdown voltage, and, in view of shrinking chips, reducing costs, etc., low on-resistance.

Conventionally, high voltage MOS transistors employ a technique for increasing static breakdown voltage (drain breakdown voltage when the gate is in the “off” condition) by forming an electric-field limiting layer in a drain region. However, an electric-field limiting layer formed in a drain region acts as a resistive component during operation of the transistor, causing an increase in on-resistance per unit area of the device. In this way, there is a trade-off between static breakdown voltage and on-resistance.

As one of the techniques for improving such a trade-off between static breakdown voltage and on-resistance, a method is disclosed in which, e.g., in a conventional high voltage MOS transistor, a source region is formed in the surface of a body layer in a self-aligned manner with respect to a sidewall spacer to effectively suppress “surface punch-through” and increase breakdown voltage and current carrying capacity (see Japanese Laid-Open Publication No. 7-176640, for example).

Characteristics of a conventional high voltage MOS transistor will be described below with reference toFIG. 7. As shown inFIG. 7, a P-well4and an N-well5are formed spaced away from each other in surface portions of an N-type epitaxial layer3formed in an upper part of a P-type semiconductor substrate1. An N+-type buried layer2is formed between the P-type semiconductor substrate1and the N-type epitaxial layer3to suppress operation of a parasitic transistor formed by the P-well4, the N-type epitaxial layer3, and the P-type semiconductor substrate1.

A gate electrode12is formed over the P-well4with a gate insulating film11interposed therebetween. With this gate electrode12used as a mask, a P-type base region (channel diffusion region)7is formed in a surface portion of the P-well4in a self-aligned manner. The P-type base region7has a greater diffusion depth than a channel ion bombardment layer6underlying the gate electrode12. The gate electrode12extends out over the N-well5, and a local oxidation film17is formed between the extended part of the gate electrode12and the P-type semiconductor substrate1.

An insulating sidewall spacer10of an oxide film or the like is formed on the sides of the gate electrode12by a CVD (chemical vapor deposition) process. By double diffusion using this insulating sidewall spacer10and the gate electrode12as a mask, an N+-type source region8is formed in the P-type base region7in a self-aligned manner, and an N+-type well contact (drain) region9is formed in the N-well5.

An interlayer dielectric film16is formed on the P-type semiconductor substrate1as well as over the gate electrode12, and contact plugs13and14, which are respectively coupled to the N+-type well contact region9and the N+-type source region8, are formed in contact holes made in the interlayer dielectric film16. On the interlayer dielectric film16, extraction electrodes15are formed, which are coupled to the respective contact plugs13and14and serve as a source electrode and a drain electrode. A passivation film (not shown) is formed on the interlayer dielectric film16as well as on the extraction electrodes15.

The conventional example set forth above is characterized in that the N+-type source region8is formed in a self-aligned manner by double diffusion using the insulating sidewall spacer10and the gate electrode12as a mask, rather than only using the gate electrode12as a mask, thereby increasing the size of the channel region formed of the P-type base region7in a lateral direction by the width of the insulating sidewall spacer10. This provides effective suppression of “surface punch-through”, thereby increasing both breakdown voltage and current carrying capacity.

SUMMARY

However, in the conventional high voltage MOS transistor, although breakdown voltage and current carrying capacity are increased by the above-described method, the low-impurity-concentration N-type epitaxial layer serving as an electric-field limiting layer is interposed between the N-well serving as a drain region and the P-well. This increases the resistive component occurring during operation of the transistor, causing an increase in on-resistance. To address this, in this conventional structure, if the impurity concentration in the N-type epitaxial layer is increased in order to reduce the resistive component of the N-type epitaxial layer, breakdown voltage in the junction between the P-well layer and the N-type epitaxial layer will decrease. In this case, a decrease in static breakdown voltage is likely to occur in the curvature portion of the PN junction, because the electric field tends to particularly concentrate in that curvature portion.

In view of the above respects, it is an object of the present disclosure to provide a semiconductor device in which increased static breakdown voltage and decreased on-resistance are both achieved, and a method for fabricating the same.

In order to achieve the object, a first semiconductor device according to the present disclosure includes: a semiconductor substrate of a first conductivity type; a first drain offset region of a second conductivity type formed in the semiconductor substrate; a second drain offset region of the second conductivity type formed on the first drain offset region in the semiconductor substrate; a third drain offset region of the second conductivity type formed on the second drain offset region in the semiconductor substrate; a body region of the first conductivity type formed partly in the second drain offset region and partly in the third drain offset region; a gate electrode formed over part of the body region and part of the third drain offset region with a gate insulating film interposed therebetween; a source region of the second conductivity type formed in a surface portion of the body region, the surface portion being located laterally outwardly of and beneath the gate electrode; and a drain region of the second conductivity type, having a higher impurity concentration than the third drain offset region, formed in a surface portion of the third drain offset region at a distance from the gate insulating film, the surface portion being located on an opposite side of the gate electrode from the source region. An impurity concentration in the second drain offset region is lower than impurity concentrations in the first and third drain offset regions; and a curvature portion and bottom of the body region are both located in the second drain offset region.

In the first semiconductor device according to the present disclosure, the curvature portion of the body region is located in the second drain offset region in the middle part of the substrate, and the second drain offset region has a lower impurity concentration than the underling first and overlying third drain offset regions. This reduces the strength of the electric field in the curvature portion of the body region, that is, in the curvature portion of the PN junction between the second drain offset region and the body region, thereby enabling static breakdown voltage to increase.

Furthermore, in the first semiconductor device according to the present disclosure, a reduction in on-resistance is achievable by increasing the impurity concentration in the third drain offset region located in the upper part of the substrate. Even when the impurity concentration is increased in the third drain offset region in the upper part of the substrate, the increased impurity concentration does not cause a decrease in static breakdown voltage, because the third drain offset region is located away from the curvature portion of the PN junction between the second drain offset region and the body region.

Also, in the first semiconductor device according to the present disclosure, the impurity concentration in the first drain offset region located in the lower part of the substrate is not reduced. This makes it possible to suppress operation of a parasitic transistor formed by the semiconductor substrate of the first conductivity type, the first and second drain offset regions of the second conductivity type, and the body region of the first conductivity type, thereby avoiding deterioration of the semiconductor device.

Accordingly, the first semiconductor device according to the present disclosure achieves both increased static breakdown voltage and lowered on-resistance.

A first method for fabricating a semiconductor device according to the present disclosure includes the steps of: (a) forming, in a semiconductor substrate of a first conductivity type, a first drain offset region of a second conductivity type, a second drain offset region of the second conductivity type, and a third drain offset region of the second conductivity type in that order in a bottom-up manner; (b) forming a gate electrode over part of the third drain offset region with a gate insulating film interposed therebetween; (c) forming a body region of the first conductivity type in an area located partly in the second drain offset region and partly in the third drain offset region and located laterally outwardly of and beneath a side of the gate electrode, so that the body region is partially overlapped by the gate electrode: and (d) forming a source region of the second conductivity type in a surface portion of the body region, the surface portion being located laterally outwardly of and beneath the gate electrode, and forming a drain region of the second conductivity type having a higher impurity concentration than the third drain offset region, in a surface portion of the third drain offset region at a distance from the gate insulating film, the surface portion being located on an opposite side of the gate electrode from the source region. An impurity concentration in the second drain offset region is lower than impurity concentrations in the first and third drain offset regions; and a curvature portion and bottom of the body region are both located in the second drain offset region.

According to the first semiconductor device fabrication method according to the present disclosure, the curvature portion of the body region of the first conductivity type formed in the step (c) is located in the second drain offset region of the second conductivity type formed in the step (a). Also, the second drain offset region has a lower impurity concentration than the first and third drain offset regions of the second conductivity type formed in the step (a). This reduces the strength of the electric field in the curvature portion of the body region, that is, in the curvature portion of the PN junction between the second drain offset region and the body region, thereby enabling static breakdown voltage to increase.

Moreover, according to the first semiconductor device fabrication method according to the present disclosure, a reduction in on-resistance is achievable by increasing the impurity concentration in the third drain offset region formed in the step (a). Even when the impurity concentration is increased in the third drain offset region located in the upper part of the substrate, the increased impurity concentration does not cause a decrease in static breakdown voltage, because the third drain offset region is located away from the curvature portion of the PN junction between the second drain offset region and the body region.

Hence, according to the first semiconductor device fabrication method according to the present disclosure, increased static breakdown voltage and lowered on-resistance are both achievable.

A second semiconductor device according to the present disclosure includes: a semiconductor substrate of a first conductivity type; a first drain offset region of a second conductivity type formed in the semiconductor substrate; a body region of the first conductivity type formed in the first drain offset region; a gate electrode formed over part of the body region and part of the first drain offset region with a gate insulating film interposed therebetween; a source region of the second conductivity type formed in a surface portion of the body region, the surface portion being located laterally outwardly of and beneath the gate electrode; and a drain region of the second conductivity type, having a higher impurity concentration than the first drain offset region, formed in a surface portion of the first drain offset region at a distance from the gate insulating film, the surface portion being located on an opposite side of the gate electrode from the source region. A second drain offset region having a lower impurity concentration than the first drain offset region is formed by counter doping in an area of the first drain offset region in which a curvature portion and bottom of the body region are located.

In the second semiconductor device according to the present disclosure, the curvature portion of the body region is located in the second drain offset region located in the middle part of the substrate, and the second drain offset region has a lower impurity concentration than the overlying and underling first drain offset region. This reduces the strength of the electric field in the curvature portion of the body region, that is, in the curvature portion of the PN junction between the second drain offset region and the body region, thereby enabling static breakdown voltage to increase.

Furthermore, in the second semiconductor device according to the present disclosure, a reduction in on-resistance is achievable by increasing the impurity concentration in the part of the first drain offset region located in the upper part of the substrate. Even when the impurity concentration is increased in the part of the first drain offset region located in the upper part of the substrate, the increased impurity concentration does not cause a decrease in static breakdown voltage, because the part of the first drain offset region in the upper part of the substrate is located away from the curvature portion of the PN junction between the second drain offset region and the body region.

Also, in the second semiconductor device according to the present disclosure, the impurity concentration in the part of the first drain offset region located in the lower part of the substrate is not reduced. This makes it possible to suppress operation of a parasitic transistor formed by the semiconductor substrate of the first conductivity type, the first and second drain offset regions of the second conductivity type, and the body region of the first conductivity type, thereby avoiding deterioration of the semiconductor device.

Accordingly, the second semiconductor device according to the present disclosure achieves both increased static breakdown voltage and lowered on-resistance.

A second method for fabricating a semiconductor device according to the present disclosure includes the steps of: (a) forming, in a semiconductor substrate of a first conductivity type, a first drain offset region of a second conductivity type; (b) forming a gate electrode over part of the first drain offset region with a gate insulating film interposed therebetween; (c) forming a body region of the first conductivity type in an area of the first drain offset region so that the body region is partially overlapped by the gate electrode, the area being located laterally outwardly of and beneath a side of the gate electrode; (d) forming a source region of the second conductivity type in a surface portion of the body region, the surface portion being located laterally outwardly of and beneath the gate electrode, and forming a drain region of the second conductivity type having a higher impurity concentration than the first drain offset region, in a surface portion of the first drain offset region at a distance from the gate insulating film, the surface portion being located on an opposite side of the gate electrode from the source region; and (e) forming, by counter doping, a second drain offset region having a lower impurity concentration than the first drain offset region, in an area of the first drain offset region in which a curvature portion and bottom of the body region are located, after the step (c) is performed.

According to the second semiconductor device fabrication method according to the present disclosure, the curvature portion of the body region of the first conductivity type formed in the step (c) is located in the second drain offset region of the second conductivity type formed in the step (e). Also, the second drain offset region has a lower impurity concentration than the first drain offset region of the second conductivity type formed in the step (a). This reduces the strength of the electric field in the curvature portion of the body region, that is, in the curvature portion of the PN junction between the second drain offset region and the body region, thereby enabling static breakdown voltage to increase.

Moreover, according to the second semiconductor device fabrication method according to the present disclosure, a reduction in on-resistance is achievable by increasing the impurity concentration in the first drain offset region (the upper part of the substrate) formed in the step (a). Even when the impurity concentration is increased in the part of the first drain offset region located in the upper part of the substrate, the increased impurity concentration does not cause a decrease in static breakdown voltage, because the part of the first drain offset region in the upper part of the substrate is located away from the curvature portion of the PN junction between the second drain offset region and the body region.

Hence, according to the second semiconductor device fabrication method according to the present disclosure, increased static breakdown voltage and lowered on-resistance are both achievable.

As described above, according to the present disclosure, the impurity concentration can be reduced in the drain offset region in the middle part of the substrate where the curvature portion of the body region is located, thereby achieving high static breakdown voltage, while at the same time, the impurity concentration can be increased in the drain offset region in the upper part of the substrate, thereby achieving lowered on-resistance.

Accordingly, the present disclosure, which relates to semiconductor devices and their methods of fabrication, provides both increased breakdown voltage and lowered on-resistance, and is thus very useful.

DETAILED DESCRIPTION

First Embodiment

A semiconductor device and its method of fabrication according to a first embodiment of the present disclosure will be described by providing an N-type high voltage MOS transistor by way of example with reference to the accompanying drawings.

FIG. 1Ais a cross-sectional view illustrating the structure of a semiconductor device according to the first embodiment.

As shown inFIG. 1A, a first N−-type drain offset region112, a second N−-type drain offset region113, a third N−-type drain offset region114are formed in that order in a bottom up manner in a P-type semiconductor substrate111. A P−-type body region115is formed partly in the second drain offset region113and partly in the third drain offset region114. A gate electrode117is formed over part of the body region115and part of the third drain offset region114with a gate insulating film116interposed therebetween. An insulating sidewall spacer124is formed on the sides of the gate electrode117. An N+-type source region118is formed in a surface portion of the body region115that is located laterally outwardly of and beneath the gate electrode117. An N+-type drain region119, which has a higher impurity concentration than the third drain offset region114, is formed at a distance from the gate electrode117in a surface portion of the third drain offset region114located on the other side of the gate electrode117from the source region118. A P+-type body contact region125, which has a higher impurity concentration than the body region115, is formed in a surface portion of the body region115located on the other side of the source region118from the gate electrode117.

Also, as shown inFIG. 1A, an interlayer dielectric film120is formed on the semiconductor substrate111as well as over the gate electrode117, and contact plugs121,122,126, and127are formed through the interlayer dielectric film120. The contact plugs121,122,126, and127are respectively coupled to the source region118, the drain region119, the body contact region125, and the gate electrode117. On the interlayer dielectric film120, extraction electrodes123are formed, which are coupled to the respective contact plugs121,122,126, and127.

A first aspect of the first embodiment of the present disclosure is that the second drain offset region113has a lower impurity concentration than the first and third drain offset regions112and114.

A second aspect of this embodiment is that the curvature portion (the curved portion connecting the side and bottom of the body region115, represented by the reference numeral131in the figure) and bottom of the body region115are both located in the second drain offset region113.

FIG. 2Ashows a concentration profile201in the P−-type body region115and a concentration profile202in the first to third N−-type drain offset regions112to114in the semiconductor device of this embodiment shown inFIG. 1A. InFIGS. 1A and 2A, “a-b” indicates the area in the depth direction where the curvature portion131of the body region115(i.e., the curvature portion of the PN junction between the body region115and the second drain offset region113) is located.

FIG. 1Bis a cross-sectional view illustrating the structure of a semiconductor device according to a comparative example. InFIG. 1B, the same members as those of the semiconductor device of this embodiment shown inFIG. 1Aare identified by the same reference numerals, and the description already presented will not be provided in order to avoid duplication. As shown inFIG. 1B, in the semiconductor device according to the comparative example, a single N−-type drain offset region141is formed in place of the first to third N−-type drain offset regions112to114of the semiconductor device of this embodiment shown inFIG. 1A.

FIG. 2Bshows a concentration profile201in a P−-type body region115and a concentration profile203in the N−-type drain offset region141in the semiconductor device of the comparative example shown inFIG. 1B. As shown inFIG. 2B, the impurity concentration in the drain offset region141is constant in the area where the body region115is formed.

FIG. 3Ashows the distribution of an electric field in and around the curvature portion131of the body region115in the semiconductor device of this embodiment shown inFIG. 1A. In the semiconductor device of this embodiment, the curvature portion131of the body region115is located in the second drain offset region113having a relatively low impurity concentration. This permits expansion of the spacing (the spacing between equipotential lines) in a potential distribution251in the vicinity of the curvature portion131where the electric field is most likely to concentrate, as shown inFIG. 3A. Thus, the strength of the electric field is reduced in the curvature portion131of the body region115, that is, in the curvature portion131of the PN junction between the second drain offset region113and the body region115, thereby enabling static breakdown voltage to increase.

FIG. 3Bshows the distribution of an electric field in and around the curvature portion of the body region115in the semiconductor device of the comparative example shown inFIG. 1B. As shown inFIG. 3B, in the semiconductor device of the comparative example, the curvature portion of the body region115is located in the drain offset region141having a constant impurity concentration. Hence, the spacing (the spacing between equipotential lines) in a potential distribution252near the curvature portion is not expanded, and therefore, it is not possible to reduce the strength of the electric field in the curvature portion to increase static breakdown voltage.

In the semiconductor device according to this embodiment, while static breakdown voltage is increased as described above, the impurity concentration can be increased in the third drain offset region114located in the upper part of the substrate, thereby enabling on-resistance to be reduced. Even when the impurity concentration is increased in the third drain offset region114in the upper part of the substrate, the increased impurity concentration does not cause a decrease in static breakdown voltage, because the third drain offset region114is located away from the curvature portion131of the PN junction between the second drain offset region113and the body region115.

Furthermore, in the semiconductor device of this embodiment, the impurity concentration in the first drain offset region112located in the lower part of the substrate is not reduced. This makes it possible to suppress operation of a parasitic transistor formed by the P-type semiconductor substrate111, the first and second N−-type drain offset regions112and113, and the P−-type body region115, thereby avoiding deterioration of the semiconductor device.

In this way, the semiconductor device of this embodiment achieves high static breakdown voltage and low on-resistance.

Static breakdown voltage and on-resistance in the semiconductor device according to the first embodiment will be described more specifically. In the semiconductor device of this embodiment, the distance between the edge of the gate electrode117and the edge of the N+-type drain region119is 1.0 μm, for example. The impurity concentration in the P−-type body region115is about 5×1017ions/cm3, for example. In the semiconductor device of the comparative example shown inFIG. 1B, the impurity concentration in the N−-type drain offset region141, which is 5×1016ions/cm3, for example, is uniformly low. In contrast, in the semiconductor device of the first embodiment, the impurity concentrations in the first to third N−-type drain offset regions112,113, and114are respectively 5×1016ions/cm3, 1×1016ions/cm3, and 6×1016ions/cm3, for example. The impurity concentration in the second drain offset region113, which is 1×1016ions/cm3, is set lower than that in the first drain offset region112, which is 5×1016ions/cm3. On the other hand, the impurity concentration in the third drain offset region114, which is 6×1016ions/cm3, is set higher than that in the first drain offset region112, which is 5×1016ions/cm3. This prevents on-resistance from increasing.

Moreover, since the impurity concentration, i.e., 1×1016ions/cm3, of the second drain offset region113, where the curvature portion131of the body region115is located, is set lower than the impurity concentration, i.e., 5×1016ions/cm3, of the first drain offset region112, the potential distribution251in the vicinity of the curvature portion131is reduced. As a result, static breakdown voltage increases from 27V to 30V. The impurity concentration in the first drain offset region112is not reduced below 5×1016ions/cm3. Therefore, it is possible to suppress operation of the parasitic transistor formed in the depth direction from the P−-type body region115.

As set forth above, in the semiconductor device of this embodiment, the impurity concentration in the second N−-type drain offset region113, where the curvature portion131of the body region115is located, is set lower than those in the underlying first and overlying third drain offset regions112and114, thereby realizing a semiconductor device that inhibits on-resistance from increasing and that has high static breakdown voltage.

The following describes how to fabricate a semiconductor device according to the first embodiment with reference toFIGS. 4A to 4E.FIGS. 4A to 4Eare cross-sectional views illustrating process steps of a method for fabricating a semiconductor device according to the first embodiment.

First, as shown inFIG. 4A, an N-type dopant, e.g., phosphorus, is introduced into a P-type semiconductor substrate111using a known ion implantation technique. The P-type semiconductor substrate111is then subjected to a thermal diffusion process at 1000° C. for 60 minutes, for example, thereby forming a first N−-type drain offset region112having an impurity concentration in the approximate range of 2×1016to 2×1017ions/cm3and having a depth of from about 1.0 μm to about 3.0 μm. Subsequently, similar process steps are performed to form a second N−-type drain offset region113and a third N−-type drain offset region114. The second N−-type drain offset region113has an impurity concentration in the approximate range of 2×1015to 1×1016ions/cm3and has a depth of from about 0.3 μm to about 1.5 μm. The third N−-type drain offset region114has an impurity concentration in the approximate range of 2×1016to 2×1017ions/cm3and has a depth of from about 0.1 μm to about 0.5 μm.

Then, as shown inFIG. 4B, a gate insulating film116, made of silicon dioxide and having a thickness of from 5 to 100 nm, for example, is formed on the third drain offset region114using a known thermal oxidation technique. Next, a gate electrode formation film (not shown) made of a conductive film is deposited over the entire surface of the semiconductor substrate111by a CVD process, for example. Thereafter, a photoresist is formed on the gate electrode formation film. With the photoresist used as a mask, the gate electrode formation film is then patterned, thereby forming a gate electrode117having a thickness of from 0.2 to 1.0 μm, for example, on the gate insulating film116. The gate electrode117may be formed, e.g., of polysilicon, a polycide layer made of WSi or the like, or a silicide layer made of a compound of metal and silicon, such as TiSi or CoSi.

Next, as shown inFIG. 4C, a P-type dopant172, e.g., boron, is introduced into the semiconductor substrate111by ion implantation using, as a mask, a photoresist171having an opening exposing a body region formation area of the semiconductor substrate111, thereby forming a P−-type body region115having an impurity concentration in the approximate range of 1×1017to 1×1018ions/cm3. In this process step, the body region115is formed so that its curvature portion (denoted by the reference numeral131in the figure) and bottom are located in the second drain offset region113.

As shown inFIG. 4D, an insulating sidewall spacer124is subsequently formed on the sides of the gate electrode117. Thereafter, as in typical MOS transistor fabrication methods, ions of an N-type dopant are implanted, thereby forming an N+-type source region118and an N+-type drain region119. The N+-type source region118is formed in a surface portion of the body region115that is located laterally outwardly of and beneath the gate electrode117. The N+-type drain region119, having a higher impurity concentration than the third drain offset region114, is formed at a distance from the gate insulating film116in a surface portion of the third drain offset region114located on the other side of the gate electrode117from the source region118. Also, ions of a P-type dopant are implanted to form a P+-type body contact region125, having a higher impurity concentration than the body region115, in a surface portion of the body region115located on the other side of the source region118from the gate electrode117.

Next, as shown inFIG. 4E, an interlayer dielectric film120is formed on the semiconductor substrate111as well as over the gate electrode117by performing a predetermined process step. Contact plugs121,122,126, and127are then formed through the interlayer dielectric film120. The contact plugs121,122,126, and127are respectively coupled to the source region118, the drain region119, the body contact region125, and the gate electrode117. Then, extraction electrodes123, which are coupled to the respective contact plugs121,122,126, and127, are formed on the interlayer dielectric film120. According to the above-described method, the semiconductor device of this embodiment can be fabricated.

In accordance with the semiconductor device fabrication method of this embodiment, the curvature portion131of the P−-type body region115formed in the process step shown inFIG. 4Cis located in the second N−-type drain offset region113formed in the process step shown inFIG. 4A. Also, the second drain offset region113has a lower impurity concentration than the first and third N−-type drain offset regions112and114formed in the process step ofFIG. 4A. This allows the spacing (the spacing between equipotential lines) in the potential distribution251in the vicinity of the curvature portion131to be expanded as shown inFIG. 3A, thereby reducing the strength of the electric field in the curvature portion131and increasing static breakdown voltage.

Furthermore, according to the semiconductor device fabrication method of this embodiment, in the process step shown inFIG. 4A, the third N−-type drain offset region114is formed so as to have a relatively high impurity concentration, thereby achieving a reduction in on-resistance.

Accordingly, the semiconductor device fabrication method of this embodiment enables the fabrication of a semiconductor device that inhibits on-resistance from increasing and that has sufficiently high static breakdown voltage.

It should be noted that although an N-type high voltage MOS transistor has been described by way of example in this embodiment, the present disclosure, when applied to a high voltage MOS transistor of the opposite type, i.e., a P-type high voltage MOS transistor, also produces similar effects.

Second Embodiment

A semiconductor device and its method of fabrication according to a second embodiment of the present disclosure will be described below with reference to the accompanying drawings. The semiconductor device of this embodiment differs from that of the first embodiment only in some of its components, and thus, the same components are identified by the same reference numerals and described briefly.

FIG. 5is a cross-sectional view illustrating the structure of the semiconductor device according to the second embodiment.

As shown inFIG. 5, a first N−-type drain offset region301is formed in a P-type semiconductor substrate111. A P−-type body region115is formed in the first drain offset region301. A gate electrode117is formed over part of the body region115and part of the first drain offset region301with a gate insulating film116interposed therebetween. An insulating sidewall spacer124is formed on the sides of the gate electrode117. An N+-type source region118is formed in a surface portion of the body region115that is located laterally outwardly of and beneath the gate electrode117. An N+-type drain region119, which has a higher impurity concentration than the first drain offset region301, is formed at a distance from the gate electrode117in a surface portion of the first drain offset region301located on the other side of the gate electrode117from the source region118. A P+-type body contact region125, having a higher impurity concentration than the body region115, is formed in a surface portion of the body region115located on the other side of the source region118from the gate electrode117.

An aspect of this embodiment is that a second N−-type drain offset region302having a lower impurity concentration than the first drain offset region301is formed by counter-doping (in which a P-type dopant is introduced at a low concentration to reduce the N-type impurity concentration) in a part of the first drain offset region301where the curvature portion (represented by the reference numeral331in the figure) and bottom of the body region115are located.

In the above-described semiconductor device of this embodiment, the curvature portion331of the body region115is located in the second drain offset region302in the middle part of the substrate, and the second drain offset region302has a lower impurity concentration than the overlying and underling first drain offset region301. Hence, it is possible to reduce the strength of the electric field in the curvature portion331(that is, in the curvature portion of the PN junction between the second drain offset region302and the body region115), thereby increasing static breakdown voltage.

Also, in the semiconductor device of this embodiment, while static breakdown voltage is increased as set forth above, the impurity concentration can be increased in the part of the first drain offset region301located in the upper part of the substrate, thereby enabling on-resistance to be lowered. Even when the impurity concentration in the part of the first drain offset region301located in the upper part of the substrate is increased, the increased impurity concentration does not cause a decrease in static breakdown voltage, because the part of the first drain offset region301in the upper part of the substrate is located away from the curvature portion331.

Furthermore, in the semiconductor device of this embodiment, the impurity concentration in the part of the first drain offset region301located in the lower part of the substrate is not reduced. This makes it possible to suppress operation of a parasitic transistor formed by the P-type semiconductor substrate111, the first and second N−-type drain offset regions301and302, and the P−-type body region115, thereby avoiding deterioration of the semiconductor device.

In this way, the semiconductor device of this embodiment achieves high static breakdown voltage and low on-resistance.

The following describes how to fabricate a semiconductor device according to the second embodiment with reference toFIGS. 6A to 6E.FIGS. 6A to 6Eare cross-sectional views illustrating process steps of a method for fabricating a semiconductor device according to the second embodiment.

First, as shown inFIG. 6A, an N-type dopant, e.g., phosphorus, is introduced into a P-type semiconductor substrate111using a known ion implantation technique. The P-type semiconductor substrate111is then subjected to a thermal diffusion process at 1000° C. for 60 minutes, for example, thereby forming a first N−-type drain offset region301having an impurity concentration in the approximate range of 2×1016to 2×1017ions/cm3and having a depth of from about 0 μm to about 3 μm. In this process step, the first drain offset region301is formed so as to have a uniform impurity concentration distribution.

Then, as shown inFIG. 6B, a gate insulating film116, made of silicon dioxide and having a thickness of from 5 to 100 nm, for example, is formed on the first drain offset region301using a known thermal oxidation technique. A gate electrode117is subsequently formed in the same manner as in the first embodiment.

Next, as shown inFIG. 6C, a P-type dopant172, e.g., boron, is introduced into the first drain offset region301by ion implantation using, as a mask, a photoresist171having an opening exposing a body region formation area of the semiconductor substrate111, thereby forming a P−-type body region115having an impurity concentration in the approximate range of 1×1017to 1×1018ions/cm3.

As shown inFIG. 6D, an insulating sidewall spacer124is then formed on the sides of the gate electrode117. Thereafter, ions of a P-type dopant, e.g., boron, are implanted at a low dose into a part of the first drain offset region301where the curvature portion (denoted by the reference numeral331in the figure) and bottom of the body region115are located, thereby forming a second N−-type drain offset region302having a lower impurity concentration than the first drain offset region301; the impurity concentration in the second N−-type drain offset region302is in the approximate range of 5×1015to 1×1016ions/cm3, while the impurity concentration in the first drain offset region301is in the approximate range of 2×1016to 2×1017ions/cm3.

Then, as shown inFIG. 6E, an N+-type source region118, an N+-type drain region119, a P+-type body contact region125, an interlayer dielectric film120, contact plugs121,122,126, and127, and extraction electrodes123are formed in the same manner as in the first embodiment. According to the above-described method, the semiconductor device of this embodiment can be fabricated.

In accordance with the semiconductor device fabrication method of this embodiment, the curvature portion331of the P−-type body region115formed in the process step shown inFIG. 6Cis located in the second N−-type drain offset region302formed in the process step shown inFIG. 6D. Also, the second drain offset region302has a lower impurity concentration than the first N−-type drain offset regions301formed in the process step shown inFIG. 6A. This reduces the strength of the electric field in the curvature portion331, thereby increasing static breakdown voltage.

Furthermore, according to the semiconductor device fabrication method of this embodiment, in the process step shown inFIG. 6A, the first N−-type drain offset region301is formed so that its upper part located in the upper part of the substrate has a relatively high impurity concentration, thereby achieving a reduction in on-resistance.

Accordingly, the semiconductor device fabrication method of this embodiment enables the fabrication of a semiconductor device that inhibits on-resistance from increasing and that has sufficiently high static breakdown voltage.

It should be noted that although an N-type high voltage MOS transistor has been described by way of example in this embodiment, the present disclosure, when applied to a high voltage MOS transistor of the opposite type, i.e., a P-type high voltage MOS transistor, also produces similar effects.