Abstract:
A semiconductor device includes: a semiconductor substrate; a vertical type trench gate MOS transistor; a Schottky barrier diode; multiple trenches having a stripe pattern to divide an inner region into first and second separation regions; and a poly silicon film in each trench. The first separation region includes a first conductive type region for providing a source and a second conductive type layer for providing a channel region. The first conductive type region is adjacent to a first trench. The poly silicon film in the first trench is coupled with a gate wiring. A second trench is not adjacent to the first conductive type region. The poly silicon film in the second trench is coupled with a source or gate wiring. The substrate in the second separation region is coupled with the source wiring for providing a Schottky barrier.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is based on Japanese Patent Applications No. 2006-194527 filed on Jul. 14, 2006, and No. 2007-115581 filed on Apr. 25, 2007, the disclosures of which are incorporated herein by reference. 
       FIELD OF THE INVENTION 
       [0002]    The present invention relates to a semiconductor device. 
       BACKGROUND OF THE INVENTION 
       [0003]    Inverter circuits for driving a load such as a motor for use in a vehicle are DC to AC converters; that is, they convert a DC voltage to an AC voltage and supply the latter to a load such as a motor. An inverter circuit for driving a motor which is inductive is composed of a MOS transistor (hereinafter abbreviated as MOS) or an insulated-gate bipolar transistor (hereinafter abbreviated as IGBT) as a switching element and a free-wheel diode (hereinafter abbreviated as FWD). The FWD bypasses and returns a current that flows through the motor while the MOS is off so that the current flowing through the motor is not varied by switching of the MOS. More specifically, when the MOS which has connected a DC power source to the motor and has applied a voltage to the motor is turned off, a current that has flown through the motor causes a reverse flow of a DC current through the FWD because of energy that is stored in the inductance L of the motor, establishing a state that is equivalent to a state that a reverse DC voltage is applied to the motor. This makes it possible to supply an AC voltage from the DC power source to the motor by switching without cutting off the motor current abruptly by switching of the MOS. To enable such an operation, the inverter circuit requires the FWD which is connected to the MOS in parallel in opposite direction. In the above inverter circuit, the MOS which functions as the switching element is required to be low in both on-resistance and switching loss. As for the FWD, the recovery characteristic and the forward loss are important characteristics. 
         [0004]    Where a MOSFET or an IGBT which is a switching element is formed as a vertical MOS transistor having a trench gate structure (switching element), a p-type layer to serve as a channel forming region of the transistor is formed in a main-surface-side surface layer of an n-type semiconductor substrate. It is therefore possible to form a (body) diode utilizing an interface pn junction and use it as a FWD. In this structure, the vertical MOS transistor and the body diode are disposed adjacent to each other, as a result of which the semiconductor device is basically given a good switching characteristic. However, the body diode which is formed in the above manner has problems of a long recovery time and a large forward loss. 
         [0005]    To solve the problems of the body diode which utilizes the pn-junction, the use of a Schottky barrier diode (hereinafter abbreviated as SBD) is being studied. For example, JP-A-2002-373989 (corresponding to U.S. Pat. No. 6,707,128) discloses a semiconductor device in which a vertical MOS transistor having a trench gate structure and an SBD are formed adjacent to each other on a semiconductor substrate. 
         [0006]      FIG. 18  shows the configuration of the conventional semiconductor device disclosed in JP-A-2002-373989, that is, it is a schematic sectional view of a semiconductor device  90 .  FIG. 18  shows several cells of an NMOSFET (hereinafter abbreviated as MOS) transistor having a trench gate structure and an SBD which are formed on an n + /n −  substrate. 
         [0007]    In the semiconductor device  90  of  FIG. 18 , a p-type base layer  12  is selectively formed in a surface layer of an n −  layer  11  of the n + /n −  substrate in a MOS forming area  14  and an n +  source region  13  is selectively formed in a surface layer of the p-type base layer  12 . Gate trenches are formed so as to extend in the depth direction from the surface of the n +  source region  13  and to reach the n −  layer  11 . An SBD forming area  28  is disposed so as to surround the p-type base layer  12  of the MOS forming area  14  continuously, for example. A guard ring region  17  is formed so as to surround the SBD forming area  28  by the same process as the p-type base layer  12  is formed. 
         [0008]    An interlayer insulating film  19  is deposited on the substrate in the MOS forming area  14 , and plural contact holes are formed through the interlayer insulating film  19  at prescribed positions. A barrier metal  21  is formed on the surface of the n −  layer  11  in the SBD forming area  28  and the surfaces of those portions of the n +  source region  13  which correspond to the contact holes formed through the interlayer insulating film  19 . The barrier metal  21  is in Schottky contact with the surface of the n −  layer  11  in the SBD forming area  28  and is in ohmic contact with the surfaces (high-concentration regions) of the portions of the n +  source region  13 . Furthermore, a first main electrode  1  made of a metal to serve as both of an anode electrode of the SBD and a source electrode of the MOS is formed on the barrier metal  21 . A second main electrode  22  to serve as both of a cathode electrode of the SBD and a drain electrode of the MOS is formed on almost the entire chip back surface. 
         [0009]    Configured in such a manner that the MOS and the SBD are connected to each other in parallel in opposite directions, the semiconductor device  90  of  FIG. 18  can be applied to the above-described inverter circuit with the SBD used as an FWD. Having a lower threshold voltage than pn-junction diodes such as the above-described body diode, when used as the FWD, the SBD is superior in the recovery characteristic and can lower the forward loss. 
         [0010]    On the other hand, whereas the above-described body diode is formed by utilizing the p-type layer (corresponding to the p-type base layer  12  shown in  FIG. 18 ) to serve as the MOS channel forming area, in the semiconductor device  90  of  FIG. 18  the independent SBD forming area  28  is provided so as to continuously surround the p-type base layer  12  which exists in the MOS forming area  14 . Therefore, the semiconductor device  90  has problems that the switching characteristic is basically bad and the chip cost is high because of an increased chip area. 
         [0011]    One method for suppressing the increase of the chip area of the semiconductor device  90  is to increase the intervals between the gate trenches in the MOS forming area  14  and dispose an SBD between the adjoining gate trenches. However, this configuration raises another problem that the increased intervals between the gate trenches lower the breakdown voltage of the MOS. Furthermore, in this configuration, since the MOS and the SBD are disposed in a limited area, the individual regions of the p-type base layer  12  of the MOS need to be sufficiently narrow taking lateral diffusion into consideration. However, since the p-type base layer  12  of the MOS corresponds to the bases of parasitic bipolar transistors, parasitic operations tend to occur unless the individual regions of the p-type base layer  12  are sufficiently wide. This means a problem that the L load surge resistance is low. 
         [0012]    Thus, it is desired to provide a semiconductor device in which a vertical MOS transistor having a trench gate structure and a Schottky barrier diode are formed adjacent to each other on a single semiconductor substrate, and which is superior in the diode recovery characteristic and can lower the forward loss, is free of reduction in transistor breakdown voltage and surge resistance, is superior in the switching characteristic, and is small in size and inexpensive. 
         [0013]      FIG. 28  is a sectional view of a conventional semiconductor device which is equipped with a vertical MOSFET having a trench gate structure. As shown in  FIG. 28 , an n −  drift layer J 2  and a p-type base layer J 3  are formed on an n +  silicon substrate J 1 . Plural n +  source regions J 4  are formed in surface portions of the base layer J 3 . The silicon substrate J 1 , the drift layer J 2 , the base layer J 3 , and the source regions J 4  constitute a semiconductor substrate J 5 . Trenches J 6  are formed in the semiconductor substrate J 5  so as to penetrate through the base layer J 3  and reach the drift region J 2 . Silicon oxide films (gate oxide films) J 7  are formed so as to cover the inner wall surfaces of the trenches J 6 , respectively, and gate electrodes J 8  are formed on the surfaces of the silicon oxide films J 7  so as to be buried in the trenches J 6 , respectively. Trench gates are thus formed. 
         [0014]    A BPSG film J 9  is formed so as to cover the gate electrodes J 8 , and a source electrode J 10  is formed so as to be electrically connected to the source regions J 4  and the base layer J 3  through contact holes that are formed through the BPSG film J 9 . A drain electrode J 11  is formed on the back-surface side of the semiconductor substrate J 5 . The semiconductor device which is equipped with the MOSFET having the trench gate structure is thus constructed (refer to JP-A-2005-333112, for example). 
         [0015]    In the MOSFET having the above structure, since the base layer J 3  necessarily exists between the trenches, body diodes which are formed by the pn junctions of the p-type base layer J 3  and the combination of the n-type drift layer J 2  and the silicon substrate J 1  are disposed between the trenches. Where the semiconductor devices having the above structure are applied to an H-bridge circuit such as a motor drive circuit and the individual MOSFETs are on/off-driven by a PWM control, a return current flows through the body diodes of the MOSFETs located on the high side, which causes a return current loss which is mainly due to Vf of the body diodes. 
         [0016]    Thus, it ie required for a semiconductor device to reduce a return current loss which is mainly due to Vf of a body diode. 
       SUMMARY OF THE INVENTION 
       [0017]    In view of the above-described problem, it is an object of the present disclosure to provide a semiconductor device having variable operating information. 
         [0018]    According to a first aspect, a semiconductor device includes: a semiconductor substrate having a first conductive type, wherein the substrate has a principal surface and a backside surface, and wherein the substrate includes an inner region and a periphery region; a vertical type trench gate MOS transistor disposed in a surface portion of the principal surface in the inner region of the substrate; a Schottky barrier diode disposed in another surface portion of the principal surface in the inner region of the substrate; a plurality of trenches disposed on the principal surface of the substrate; and a poly silicon film filled in each trench through an insulation film between the poly silicon film and an inner wall of the trench. The plurality of trenches have a stripe pattern without crossing each other so that the inner region on the principal surface of the substrate is divided into a plurality of separation regions by the plurality of trenches. The plurality of separation regions includes a first separation region and a second separation region. The first separation region includes a first conductive type region and a second conductive type layer disposed on the principal surface of the substrate. The second conductive type layer provides a channel region of the MOS transistor. The first conductive type region is disposed on a surface portion of the second conductive type layer, and adjacent to one trench so that the one trench provides a first trench. The first conductive type region provides a source of the MOS transistor. The poly silicon film in the first trench is coupled with a gate wiring of the MOS transistor. The plurality of trenches further includes a second trench, which is not adjacent to the first conductive type region. The poly silicon film in the second trench is coupled with a source wiring or the gate wiring of the MOS transistor. The substrate in the second separation region is exposed on the principal surface in such a manner that the substrate is coupled with the source wiring of the MOS transistor. The source wiring and the substrate in the second separation region provide a Schottky barrier in the Schottky barrier diode. 
         [0019]    In the device, the MOS transistor and the Schottky barrier diode are reversely coupled with each other. Accordingly, the device can provide a switching element in an inverter circuit. In this case, the Schottky barrier diode has a low threshold voltage, compared with a PN junction diode. Thus, a recovery property and a forward direction loss in the Schottky barrier diode are improved. 
         [0020]    Further, since the MOS transistor and the Schottky barrier diode are proximately arranged, so that a switching property is improved, and further, dimensions and a manufacturing cost of the device are reduced. Furthermore, by designing a width between two trenches appropriately, a withstand voltage of the MOS transistor is improved. Further, since the second conductive type layer for providing the channel region of the MOS transistor is limited to diffuse in a lateral direction of the substrate by the trench, impurity concentration is easily controlled, and a parasitic operation of a parasitic bipolar transistor is reduced so that a load surge breakdown voltage is improved. 
         [0021]    Thus, the recovery property and the forward direction loss are improved, and the withstand voltage and the surge breakdown voltage in the transistor are also improved. Thus, the switching property in the device is improved, and the dimensions of the device are small. 
         [0022]    According to a second aspect, a semiconductor device includes: a semiconductor substrate having a first conductive type, wherein the substrate includes a first surface and a second surface, and has a first portion and a second portion; a drift layer having the first conductive type, wherein the drift layer is disposed in a surface portion of the first surface of the substrate; a vertical MOSFET disposed in the first portion of the substrate; and an accumulation FET for operating in an accumulation mode and disposed in the second portion of the substrate. The vertical MOSFET includes: the drift layer; a base layer having a second conductive type, wherein the base layer is disposed in the drift layer; a source region having the first conductive type, wherein the source region is disposed in the base layer in such a manner that the source region is separated from the drift layer by the base layer; a first gate insulation film disposed between the source region and the drift layer through the base layer; a first gate electrode disposed on the first gate insulation film, wherein the first gate electrode provides a channel in a part of the base layer, which contacts the first gate insulation film; a source electrode electrically coupling with the source region and the base layer; and a drain electrode disposed on the second surface of the substrate. The accumulation FET includes: a second trench disposed in the drift layer; a second gate insulation film disposed on an inner wall of the second trench; and a second gate electrode disposed on the second gate insulation film in the second trench, wherein a part of the drift layer contacting the second trench is coupled with the source electrode of the vertical MOSFET. 
         [0023]    In the above device, a return current flows through the accumulation FET instead of the MOSFET. Thus, loss caused by a Vf of a body diode is reduced. 
         [0024]    According to a third aspect, a semiconductor device includes: a semiconductor substrate having a first conductive type, wherein the substrate includes a first surface and a second surface, and has a first portion and a second portion; a drift layer having the first conductive type, wherein the drift layer is disposed in a surface portion of the first surface of the substrate; a vertical MOSFET disposed in the first portion of the substrate; and a J-FET disposed on the second portion of the substrate. The vertical MOSFET includes: the drift layer; a base layer having a second conductive type, wherein the base layer is disposed in the drift layer; a source region having the first conductive type, wherein the source region is disposed in the base layer in such a manner that the source region is separated from the drift layer by the base layer; a first gate insulation film disposed between the source region and the drift layer through the base layer; a first gate electrode disposed on the first gate insulation film, wherein the first gate electrode provides a channel in a part of the base layer, which contacts the first gate insulation film; a source electrode electrically coupling with the source region and the base layer; and a drain electrode disposed on the second surface of the substrate. The J-FET includes: a second trench disposed in the drift layer; a second conductive type layer disposed in the drift layer and surrounding the second trench; and a second gate electrode coupled with the second conductive type layer, wherein a part of the drift layer contacting the second trench is coupled with the source electrode of the vertical MOSFET. 
         [0025]    In the above device, a return current flows through the J-FET instead of the MOSFET. Thus, loss caused by a Vf of a body diode is reduced. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0026]    The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings: 
           [0027]      FIG. 1  shows an exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  100 ; 
           [0028]      FIG. 2  is a schematic plan view showing an exemplary planar pattern of an important part of the semiconductor device  100  of  FIG. 1 , and a sectional view taken along a chain line I-I in  FIG. 2  corresponds to  FIG. 1 ; 
           [0029]      FIG. 3  shows another exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  101 ; 
           [0030]      FIG. 4  is a schematic plan view showing an exemplary planar pattern of an important part of the semiconductor device  101  of  FIG. 3 , and a sectional view taken along a chain line III-III in  FIG. 4  corresponds to  FIG. 3 ; 
           [0031]      FIG. 5  shows another exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  102 ; 
           [0032]      FIG. 6  is a schematic plan view showing an exemplary planar pattern of an important part of the semiconductor device  102  of  FIG. 5 , and a sectional view taken along a chain line V-V in  FIG. 6  corresponds to  FIG. 5 ; 
           [0033]      FIG. 7  shows another exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  103 ; 
           [0034]      FIG. 8  shows another exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  104 ; 
           [0035]      FIG. 9  shows still another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  100   a,    
           [0036]      FIG. 10  shows another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  101   a;    
           [0037]      FIG. 11  shows another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  102   a;    
           [0038]      FIG. 12  shows yet another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  100   b;    
           [0039]      FIG. 13  shows another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  101   b;    
           [0040]      FIG. 14  shows another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  102   b;    
           [0041]      FIG. 15  shows a further exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  100   c;    
           [0042]      FIG. 16  shows another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  101   c;    
           [0043]      FIG. 17  shows another exemplary semiconductor device, that is, it is a schematic plan view showing an exemplary planar pattern of an important part of a semiconductor device  102   c;    
           [0044]      FIG. 18  shows the configuration of a conventional semiconductor device, that is, it is a schematic sectional view of a semiconductor device  90 ; 
           [0045]      FIG. 19  shows a sectional structure of a semiconductor device according to a second embodiment which is equipped with a DMOS having a trench gate structure; 
           [0046]      FIG. 20A  is a schematic sectional view showing a wiring form of the semiconductor device of  FIG. 19 , and  FIG. 20B  shows its exemplary planar pattern; 
           [0047]      FIG. 21A  is a circuit diagram in which the above-configured semiconductor devices each having the DMOS and an AccuFET are provided on the high side of an H-bridge circuit for motor driving; 
           [0048]      FIG. 21B  is a timing chart showing voltages applied to the gate electrodes of the semiconductor devices located on the high side and voltages applied to the gate electrodes of DMOSs that are located on the low side when motor driving is performed by a PWM-control by means of the H-bridge circuit; 
           [0049]      FIGS. 22A to 22C  are schematic diagrams showing current paths of a case that the semiconductor devices of  FIG. 19  are provided on the high side of the H-bridge circuit and the DMOSs are on/off-controlled by a PWM control; 
           [0050]      FIGS. 23A to 23G  are sectional views showing a manufacturing process of the semiconductor device of  FIG. 19 ; 
           [0051]      FIG. 24  shows a sectional structure of a semiconductor device according to a third embodiment which is equipped with a DMOS having a trench gate structure; 
           [0052]      FIG. 25A  is a schematic sectional view showing a wiring form of the semiconductor device of  FIG. 24 , and  FIG. 25B  shows its exemplary planar pattern; 
           [0053]      FIGS. 26A to 26C  are schematic diagrams showing current paths of a case that the semiconductor devices of  FIG. 24  are provided on the high side of an H-bridge circuit and the DMOSs are on/off-controlled by a PWM control; 
           [0054]      FIGS. 27A to 27H  are sectional views showing a manufacturing process of the semiconductor device of  FIG. 24 ; and 
           [0055]      FIG. 28  is a sectional view of a conventional semiconductor device which is equipped with a vertical MOSFET having a trench gate structure. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     First Embodiment 
       [0056]      FIG. 1  shows an exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  100 .  FIG. 2  is a schematic plan view showing an exemplary planar pattern of an important part of the semiconductor device  100  of  FIG. 1 , and a sectional view taken along a chain line I-I in  FIG. 2  corresponds to  FIG. 1 . 
         [0057]    The semiconductor device  100  shown in  FIGS. 1 and 2  is a semiconductor device in which a vertical MOS transistor (hereinafter abbreviated as MOS) having a trench gate structure and a Schottky barrier diode (hereinafter abbreviated as SBD) are formed adjacent to each other on an n-type (n − ) semiconductor substrate  30 . Although in the following example the vertical MOS transistor is an NMOSFET (n-channel metal oxide semiconductor field-effect transistor), it may be an IGBT (insulated-gate bipolar transistor) in which a p-type layer is provided on the back-surface side of the semiconductor substrate  30 . 
         [0058]    In the semiconductor device  100 , as shown in  FIG. 1 , plural buried trenches T 1  and T 2  in each of which polysilicon  32  is buried via an insulating film  31  are formed adjacent to the main surface of the semiconductor substrate  30 . The polysilicon  32  in each trench is doped so as to exhibit n +  conductivity. The intervals between the buried trenches T 1  and T 2  are 2 to 5 μm, for example. Among the plural buried trenches T 1  and T 2 , the first buried trenches T 1  are buried trenches that function as gate electrodes of the MOS and the second buried trenches T 2  are buried trenches that do not function as gate electrodes of the MOS. 
         [0059]    As shown in  FIG. 2 , the plural buried trenches T 1  and T 2  are formed along plural straight lines that exist in the substrate surface and are parallel with each other. A prescribed inner region (see  FIG. 2 ) adjacent to the main surface of the semiconductor substrate  30  is divided (partitioned) into plural partitioned regions R 1  and R 2  by the plural buried trenches T 1  and T 2 . An outer region which surrounds the inner region (see  FIG. 2 ) is a p-type region  36  which is formed at the same time as p-type layers  33  (described later) or by a process that is separate from a process for forming the p-type layers  33 . 
         [0060]    Among the plural partitioned regions R 1  and R 2 , the first partitioned regions R 1  are regions that are parts of the MOS and the second partitioned regions R 2  are regions that are parts of the SBD. In each first partitioned region R 1 , a p-type layer  33  to serve as a channel-forming region of the MOS is formed in a main-surface-side portion of the semiconductor substrate  30 . An n-type (n + ) region  34  as a source region of the MOS is formed in a surface portion of the p-type layer  33  adjacent to the first buried trench T 1 . On the other hand, in each second partitioned region R 2 , an n-type (n) layer  30   a  which is part of the semiconductor substrate  30  is exposed in the main surface. An n-type (n + ) layer  35  to be connected to a drain (D) electrode of the MOS and a cathode electrode of the SBD which are a common electrode is formed in a back-surface-side surface layer of the semiconductor substrate  30 . Although in  FIG. 1  the n-type (n + ) layer  35  is drawn so as to be thinner than the n-type (n − ) layer  30   a,  the semiconductor substrate  30  may be such as to be obtained by forming a thin n-type (n − ) layer  30   a  by epitaxial growth on a thick wafer as the n-type (n + ) layer  35 . In the semiconductor device  100 , the n-type (n − ) layer  30   a  functions as a carrier drift layer for the MOS and the SBD. 
         [0061]    The polysilicon in the first buried trenches T 1  which function as the gate electrodes of the MOS among the plural buried trenches T 1  and T 2  is connected to a gate (G) interconnection of the MOS. Those portions of the n-type layer  30   a  which are exposed in the surface in the second partitioned regions R 2  are connected together to a source (S) interconnection of the MOS, whereby Schottky barriers of the SBD are formed in contact portions (indicated by a thick line in  FIG. 1 ). In the semiconductor device  100  of  FIG. 1 , the polysilicon in the second buried trenches T 2  which are not adjacent to the n-type (n + ) regions  34  (the source regions of the MOS) and do not function as gate electrodes is connected to the source (s) interconnection of the MOS. 
         [0062]    In the semiconductor device  100 , as shown in  FIG. 2 , a first metal layer M 1  which is the source (S) interconnection of the MOS is formed so as to cover the prescribed inner region from above the main surface of the semiconductor substrate  30 . A second metal layer M 2  which is the gate (G) interconnection of the MOS is formed so as to surround the first metal layer M 1 . This structure allows the first metal layer M 1  as the source interconnection to be connected to the source regions in a shortest length and also allows the first metal layer M 1  to have a large area. As a result, reduced in wiring resistance, the semiconductor device  100  can be made a large-capacity power device. 
         [0063]    In the semiconductor device  100 , as described above, the polysilicon in the second buried trenches T 2  is connected to the source (S) interconnection of the MOS. To this end, in the semiconductor device  100 , as shown in  FIG. 2 , the polysilicon in the second buried trenches T 2  is connected to the overlaid first metal layer M 1  as the source interconnection of the MOS via polysilicon layers  37   a  which are formed on the semiconductor substrate  30  outside the prescribed inner region and are connected directly to the polysilicon in the second buried trenches T 2 . The polysilicon in the first buried trenches T 1  is connected to the overlaid second metal layer M 2  as the gate interconnection of the MOS via a polysilicon layer  37   b  which is formed on the semiconductor substrate  30  in the outer region and is connected directly to the polysilicon in the first trenches T 1 . Portions enclosed by thick broken lines in  FIG. 2  are contact portions of the first and second metal layers M 1  and M 2 . 
         [0064]    Next, a manufacturing method of the semiconductor device  100  of  FIGS. 1 and 2  will be described briefly. 
         [0065]    First, an n-type (n − ) layer  30   a  to become the drift layer is formed by epitaxial growth on an n +  semiconductor substrate to become the n-type (n + ) layer  35  shown in  FIG. 1 . Then, a p-type region  36  to become the outer voltage withstanding region shown in  FIG. 2  is formed so as to occupy a prescribed surface portion of the n-type (n − ) layer  30   a.  Then, p-type layers  33  are formed by ion implantation and thermal diffusion. Then, an oxide film to serve as a mask for formation of first buried trenches T 1  and second buried trenches T 2  is deposited by CVD at a thickness of about 1 μm. Subsequently, prescribed portions (where trenches are to be formed) of the oxide film are removed selectively by photolithography and dry etching. At this time, as shown in  FIG. 2 , the patterning is performed so that second buried trenches T 2  become shorter than first buried trenches T 1  and the ends of the former are located inside those of the latter. Dry etching is then performed to form trenches (the depth of the trenches is set at 1 to 3 μm in the case of a MOS and at 4 to 6 μm in the case of an IGBT). Then, after damage elimination treatment (also serves as treatment for rounding the trench corners) such as chemical dry etching or pseudo-oxidation is performed, insulating films  31  (see  FIG. 1 ) are formed by thermal oxidation. Then, polysilicon  32  doped with an impurity is buried in the trenches by CVD and deposited on the substrate  30  (alternatively, the impurity may be introduced after depositing non-doped polysilicon). Then, polysilicon layers  37   a  and  37   b  (see  FIG. 2 ) are formed by patterning by dry etching. At this time, the polysilicon layer  37   b  is formed in such a manner as to cover end portions of the first buried trenches T 1  in the gate lead-out regions of the first buried trenches T 1 . Outside the inner region (cell region), the polysilicon layers  37   a  are formed by patterning so as to cover end portions of the second buried trenches T 2 . The trench mask oxide film is thereafter removed by dry etching. At this time, the patterning is performed so that the trench mask oxide film is removed only in the inner region (cell region), that is, it is not removed in the gate lead-out regions and a field region. Subsequently, p-type layers  33  to become channel forming layers of the MOS are formed in the first partitioned regions R 1  between the first buried trenches T 1  and the second buried trenches T 2 . Then, n-type (n + ) regions  34  to become source regions of the MOS are formed in surface layer portions of the p-type layers  33  in the same first partitioned regions R 1 . Then, an interlayer insulating film is formed and contact holes are formed. At this time, contact holes for connection to the source are formed over the respective polysilicon layers  37   a  which cover the end portions of the second buried trenches T 2 . Then, a first metal layer M 1  and a second metal layer M 2  are formed with aluminum (Al) or the like. As a result, the polysilicon  32  in the second buried trenches T 2  is connected to the source interconnection via the contact holes. Subsequently, the wafer thickness is reduced by grinding the back surface and a back-surface drain electrode (see  FIG. 1 ) is formed. 
         [0066]    In the semiconductor device  100  of  FIGS. 1 and 2 , the MOS and the SBD are formed adjacent to each other on the single semiconductor substrate  30  and are connected to each other in opposite directions. Therefore, as described above, the semiconductor device  100  can be used, as it is, as a switching device of an inverter circuit. In such a case, being lower in threshold voltage than pn-junction diodes, the SBD of the semiconductor device  100  is superior in the recovery characteristic and can reduce the forward loss. 
         [0067]    In the semiconductor device  100  of  FIGS. 1 and 2 , the MOS and the SBD are formed close to each other in the partitioned regions R 1  and R 2 , separated from each other by the buried trenches T 1  and T 2 , of the single inner region rather than in isolated, different areas as in case of the semiconductor device  90  of  FIG. 18 . Therefore, the semiconductor device  100  of  FIGS. 1 and 2  can be a small, inexpensive semiconductor device having a superior switching characteristic. Furthermore, properly setting, in a range of 2 to 5 the intervals between the plural buried trenches T 1  and T 2  which partition the inner region makes it possible to suppress electric field concentration on the bottom portions of the trenches during reverse biasing and to suppress reduction of the breakdown voltage of the MOS formed in the partition regions R 1 . 
         [0068]    As for the p-type layers  33  which serve as the channel forming regions of the MOS, lateral diffusion is restricted by the buried trenches T 1  and T 2  as shown in  FIG. 1 . Therefore, it is not necessary to secure margins for lateral diffusion in forming the p-type layers  33 , which contributes to reduction of the device size. Furthermore, since the impurity concentration of the p-type layers  33  can be controlled easily, reduction of the L load surge resistance can be prevented by suppressing parasitic operations of parasitic bipolar transistors. 
         [0069]    As described above, the semiconductor device  100  of  FIGS. 1 and 2  can be made a small semiconductor device in which the vertical MOS transistor having the trench gate structure and the Schottky barrier diode are formed adjacent to each other on the single semiconductor substrate  30 , and which is superior in the diode recovery characteristic and can lower the forward loss, is free of reduction in transistor breakdown voltage and surge resistance, and is superior in the switching characteristic. 
         [0070]    The plural buried trenches T 1  and T 2  of the semiconductor device  100  are parallel with each other and straight, as a result of which breakdown voltage designing etc. are facilitated and the semiconductor device  100  is made highly reliable and inexpensive. However, semiconductor devices capable of providing the same advantages as the semiconductor device  100  does can be obtained by modifying the semiconductor device  100 . For example, the plural buried trenches may be curved; satisfactory results are obtained as long as the plural buried trenches extend along plural lines that do not intersect each other in the substrate surface. 
         [0071]    In the semiconductor device  100 , among the plural partitioned regions R 1  and R 2 , partitioned by the plural buried trenches T 1  and T 2 , of the inner region (see  FIG. 2 ), first partitioned regions R 1  are disposed on both sides of each second partitioned region R 2 . In this manner, elements of the MOS are disposed on both sides of each SBD. As a result, the time taken by carrier movements between the MOS and the SBD is shortened, whereby the semiconductor device  100  is made superior particularly in the switching characteristic. Alternatively, for example, the plural buried trenches may be curved and the arrangement of the first partitioned regions R 1  where the MOS is formed and the second partitioned regions R 2  where the SBD is formed is arbitrary. 
         [0072]      FIG. 3  shows another exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  101 .  FIG. 4  is a schematic plan view showing an exemplary planar pattern of the semiconductor device  101  of  FIG. 3 , and a sectional view taken along a chain line in  FIG. 4  corresponds to  FIG. 3 . Portions of the semiconductor device  101  of  FIGS. 3 and 4  are given the same symbols as corresponding portions of the semiconductor device  100  of  FIGS. 1 and 2 . 
         [0073]    Whereas the semiconductor device  101  of  FIG. 3  has the same sectional structure as the semiconductor device  100  of  FIG. 1 , they are different from each other in the manner of connection of the second buried trenches T 2 . In the semiconductor device  100  of  FIG. 1 , the second buried trenches T 2  are connected to the source (S) interconnection of the MOS. In contrast, in the semiconductor device  101  of  FIG. 3 , the second buried trenches T 2  are connected to the gate (G) interconnection of the MOS. 
         [0074]    The polysilicon in the second buried trenches T 2  of the semiconductor device is connected to the source interconnection or the gate interconnection so that it is given the same potential (zero potential) as the polysilicon in the first buried trenches T 1  as the gate electrodes while the MOS is off. Where the second buried trenches T 2  are connected to the source (S) interconnection of the MOS as in the semiconductor device  100  of  FIG. 1 , an unnecessary parasitic (gate) capacitance is less prone to be attached to the gate of the MOS than in the case where they are connected to the gate (G) interconnection. This is preferable in being able to suppress reduction of the switching speed of the MOS and to reduce the switching loss. 
         [0075]    On the other hand, where the second buried trenches T 2  are connected to the gate (G) interconnection of the MOS like the first buried trenches T 1 , the wiring structure is simplified and hence the semiconductor device can be made smaller. For example, in the semiconductor device  101 , as shown in  FIG. 4 , the polysilicon in the first buried trenches T 1  and the second buried trenches T 2  is connected to the gate (G) interconnection of the MOS via the polysilicon layer  37   b  which is formed on the semiconductor substrate outside the prescribed inner region and is connected directly to the polysilicon in first buried trenches T 1  and the second buried trenches T 2 . 
         [0076]      FIG. 5  shows another exemplary semiconductor device, that is, it is a schematic sectional view of a semiconductor device  102 .  FIG. 6  is a schematic plan view showing an exemplary planar pattern of the semiconductor device  102  of  FIG. 5 , and a sectional view taken along a chain line C-C in  FIG. 6  corresponds to  FIG. 5 . Portions of the semiconductor device  102  of  FIGS. 5 and 6  are given the same symbols as corresponding portions of the semiconductor device  100  of  FIGS. 1 and 2 . 
         [0077]    In the semiconductor device  102  of  FIGS. 5 and 6 , as in the semiconductor device  100  of  FIGS. 1 and 2 , the second buried trenches T 2  are connected to the source (S) interconnection of the MOS. On the other hand, the semiconductor device  102  of  FIGS. 5 and 6  is different from the semiconductor device  100  of  FIGS. 1 and 2  in that, in each set of first partitioned regions R 1  and a second partitioned region R 2  that are adjacent to each other, the n-type (n + ) regions  34 , the p-type layers  33 , the polysilicon  32  in the second buried trenches T 2 , and the n-type (n − ) layer  30   a  which are exposed in the surface of the semiconductor substrate  30  are together connected to the (first) metal layer M 1  as the source interconnection which is formed on the semiconductor substrate  30 . Therefore, in the semiconductor device  102 , forming contact portions in such a manner as to be surrounded by thick broken lines in  FIG. 6  makes it unnecessary to form, as in the semiconductor device  100  (see  FIG. 2 ), the polysilicon layers  37   a  which are connected directly to the polysilicon in the second buried trenches T 2 . 
         [0078]    Next, a description will be made of methods for further increasing the breakdown voltage in the semiconductor devices  100 - 102  of  FIGS. 1-6 . 
         [0079]      FIGS. 7 and 8  show other exemplary semiconductor devices, that is, they are schematic sectional views of semiconductor devices  103  and  104 . Portions of the semiconductor devices  103  and  104  of  FIGS. 7 and 8  are given the same symbols as corresponding portions of the semiconductor device  100  of  FIG. 1 . 
         [0080]    In the semiconductor device  100  of  FIG. 1 , the insulating film  31  of each of the buried trenches T 1  and T 2  is formed at the same thickness in the trench bottom portion and the trench side wall portions. In contrast, in the semiconductor device  103  of  FIG. 7 , to increase the breakdown voltage, the insulating film  31   a  of each of buried trenches T 1   a  and T 2   a  is thicker in the trench bottom portion than in the trench side wall portions. For example, the structure of each of the buried trenches T 1   a  and T 2   a  of the semiconductor device  103  of  FIG. 7  can be obtained by forming an oxide film by thermal oxidation at the same thickness in the bottom portion and the side wall portions after formation of the trench and then depositing an oxide film in the trench bottom portion. 
         [0081]    In the semiconductor device  100  of  FIG. 1 , each of the buried trenches T 1  and T 2  is formed in such a manner that the radius of curvature of the trench bottom portion is equal to ½ of the trench width of the trench top portion. In contrast, in the semiconductor device  104  of  FIG. 8 , to increase the breakdown voltage, each of buried trenches T 1   b  and T 2   b  are formed in such a manner that the radius of curvature of the trench bottom portion is larger than ½ of the trench width of the trench top portion. For example, the structure of each of the buried trenches T 1   b  and T 2   b  of the semiconductor device  104  of  FIG. 8  can be obtained by forming a trench by anisotropic etching and then performing isotropic etching in a state that reaction products that are stuck to the trench side walls are not removed. 
         [0082]    The break down voltage can be increased further by decreasing the width of the second buried trenches R 2  in the semiconductor devices  100 - 102  of  FIGS. 1-6 . 
         [0083]      FIGS. 9-11  show other exemplary semiconductor devices, that is, they are schematic plan views showing exemplary planar patterns of important parts of semiconductor devices  100   a - 102   a.  Portions of the semiconductor devices  100   a - 102   a  of  FIGS. 9-11  are given the same symbols as corresponding portions of the semiconductor devices  100 - 102  of  FIGS. 2 ,  4 , and  6 . 
         [0084]    As shown in  FIGS. 2 ,  4 , and  6 , in the semiconductor devices  100 - 102 , the width of the partitioned regions R 1  is set approximately the same as that of the partitioned regions R 2 , that is, the intervals between the adjoining ones of the straight buried trenches T 1  and T 2  which are parallel with each other are set approximately identical. In contrast, in the semiconductor devices  100   a - 102   a  of  FIGS. 9-11 , the width w 2  of second buried trenches R 2   a  is set smaller than the width w 1  of first buried trenches R 1   a.  With this measure, the breakdown voltage can be made higher than in the semiconductor devices  100 - 102  of  FIGS. 2 ,  4 , and  6 . The reduction in breakdown voltage due to the insertion of the second partitioned regions R 2   a  (i.e., SBD), as compared with the case that the second partitioned regions R 2   a  (i.e., SBD) are not provided, can thus be decreased. 
         [0085]      FIGS. 12-14  and  FIGS. 15-17  show other exemplary semiconductor devices, that is, they are schematic plan views showing exemplary planar patterns of important parts of semiconductor devices  100   b - 102   b  and  100   c - 102   c,  respectively. Portions of the semiconductor devices  100   b - 102   b  of  FIGS. 12-14  and portions of the semiconductor devices  100   c - 102   c  of  FIGS. 15-17  are given the same symbols as corresponding portions of the semiconductor devices  100 - 102  of  FIGS. 2 ,  4 , and  6 . 
         [0086]    The semiconductor devices  100   b - 102   b  of  FIGS. 12-14  are different from the semiconductor devices  100 - 102  of  FIGS. 2 ,  4 , and  6 , respectively, in that plural third buried trenches  13  are formed so as to bridge, in a ladder-like manner, the two adjoining buried trenches T 2  that define each second partitioned region R 2 . Each second partitioned region R 2  is partitioned into plural small regions by the plural third buried trenches T 3 , which makes it possible to decrease the reduction in breakdown voltage due to the insertion of the second partitioned regions R 2  (i.e., SBD). To decrease the reduction in breakdown voltage, it is preferable that the plural small regions be approximately square as shown in  FIGS. 12-14 . 
         [0087]    In addition to decreasing the reduction in breakdown voltage, the third buried trenches T 3  can be used for preventing lateral diffusion toward the second partitioned regions R 2  in forming the outer p-type region  36  as well as for increasing the contact areas of the polysilicon in the buried trenches T 2  and the polysilicon layers  37   a  or the polysilicon layer  37   b  which are or is formed on the substrate. In the semiconductor devices  100   c - 102   c  of  FIGS. 15-17 , third buried trenches T 3   a  that are formed at the ends of the respective second partitioned regions R 2  are used for preventing lateral diffusion toward the second partitioned region R 2  in forming the outside p-type region  36 . In the semiconductor devices  100   c  and  101   c  of  FIGS. 15 and 16 , third buried trenches T 3   b  that are located right under the respective polysilicon layers  37   a  or the polysilicon layer  37   b  are used for increasing the contact areas of the polysilicon in the buried trenches T 2  and the polysilicon layers  37   a  or the polysilicon layer  37   b  which are or is formed on the substrate. 
         [0088]    In the semiconductor devices  100 - 104 ,  100   a - 102   a,    100   b - 102   b,  and  100   c - 102   c  of  FIGS. 1-17 , the n-type (n − ) semiconductor substrate  30  is used and the p-type layers (P)  33  to serve as the channel forming regions of the MOS and the portions of the n-type layer  30   a  to form the Schottky barriers of the SBD are formed in main-surface-side surface portions. For the MOS as the component of each of the semiconductor devices  100 - 104 ,  100   a - 102   a,    100   b - 102   b,  and  100   c - 102   c  to exhibit good characteristics, it is preferable to employ the conductivity types of the individual portions of the semiconductor devices  100 - 102  of  FIGS. 1 ,  3 ,  5 . Alternatively, semiconductor devices are possible in which the conductivity types of all the individual portions are reversed from those of the semiconductor devices  100 - 104 ,  100   a - 102   a,    100   b - 102   b,  and  100   c - 102   c.    
         [0089]    As described tin the above examples, the semiconductor device is a semiconductor device in which a vertical MOS transistor having a trench gate structure and a Schottky barrier diode are formed adjacent to each other on a single semiconductor substrate, and which is superior in the diode recovery characteristic and can lower the forward loss, is free of reduction in transistor breakdown voltage and surge resistance, is superior in the switching characteristic, and is small in size and inexpensive. 
         [0090]    As such, the semiconductor device can be used suitably as a semiconductor device which is an inverter circuit that is a combination of a vertical MOS transistor and a free-wheel diode (FWD). In this case, the Schottky barrier diode serves as the FWD. 
         [0091]    Being small in size and capable of securing a high breakdown voltage, the semiconductor device is suitably used as a vehicular semiconductor device. 
       Second Embodiment 
       [0092]    A second embodiment will be hereinafter described.  FIG. 19  shows a sectional structure of a semiconductor device according to this embodiment which is equipped with a DMOS having a trench gate structure.  FIG. 20A  is a schematic sectional view showing a wiring form of the semiconductor device of  FIG. 19 , and  FIG. 20B  shows its exemplary planar pattern. The configuration of the semiconductor device according to the embodiment will be described below with reference to  FIG. 19  and  FIGS. 20A and 20B . 
         [0093]    The semiconductor device according to the embodiment is configured in such a manner that a DMOS having a trench gate structure and an AccuFET are formed adjacent to each other in a single chip. The AccuFET is a field-effect transistor which operates in an accumulation mode, that is, a MOSFET which is used for controlling a current flowing between trench by adjusting the widths of depletion layers formed between the trenches (refer to U.S. Pat. No. 4,903,189, for example). 
         [0094]    As shown in  FIG. 19 , an n −  drift layer  202  is formed on an n +  silicon substrate  201 . P-type base layers  203  are formed in portions of the drift layer  202  from its surface to a prescribed position in the depth direction in regions where a DMOS is formed (hereinafter referred to as “DMOS forming regions”). In the DMOS forming regions, plural n +  source regions  204  are formed in surface portions of the base layer  203  so as to be separated from the drift layer  202  by the base layer  203 . The silicon substrate  201 , the drift layer  202 , the base layer  203 , and the source regions  204  constitute the semiconductor substrate  205 . 
         [0095]    In each DMOS forming region of the semiconductor substrate  205 , a first trench  206   a  is formed so as to penetrate through the source regions  204  and the base layer  203  and reach the drift layer  202 . In the region where the AccuFET is formed (hereinafter referred to as “AccuFET forming region”), second trenches  206   b  are formed at the same depth and width as the first trenches  206   a  formed in the DMOS forming regions. Each side wall of the first trench  206   a  in each DMOS forming region consists of walls of the base layer  203  and a source region  204 . On the other hand, one or both of the side walls of each second trench  6   b  in the AccuFET forming region are walls of only the drift layer  202  rather than walls of the base layer  203  and a source region  204 . 
         [0096]    A silicon oxide film (gate insulating film)  207   a  or  207   b  is formed in each of the first and second trenches  206   a  and  206   b.  Each silicon oxide film  207   a  or  207   b  is formed so as to cover the inner wall surfaces of the first trench  206   a  or the second trench  206   b  and to be in contact with the portion(s), located between the source region  204  and the drift layer  202 , of the base layer  203 . A gate electrode  208   a  or  208   b  is formed on the surface of each silicon oxide film  207   a  or  207   b  so as to be buried in the first trench  206   a  or the second trench  206   b.  The trench gates are thus formed. 
         [0097]    A BPSG film  209  is formed so as to cover the gate electrodes  208   a  and  208   b.  A source electrode  210  is formed so as to be electrically connected to the source regions  204  and the base layers  203  in the DMOS forming regions and the portion of the drift layer  202  in the AccuFET region through contact holes  209   a  that are formed through the BPSG film  209 . A drain electrode  211  is formed on the back-surface side of the semiconductor substrate  205 . 
         [0098]    In the semiconductor device having the above sectional structure, as shown in  FIG. 20A , the gate electrodes  208   a  and the gate electrodes  208   b  are electrically connected to different gate interconnections  212   a  and  212   b  in cross sections that are different from  FIG. 19 . More specifically, as shown in  FIG. 20B , the first trenches  206   a  and the second trenches  206   b  extend in the same direction in the form of stripes. One (in this embodiment, the first trenches  206   a ) of the first trenches  206   a  and the second trenches  206   b  project from the tips of the other (in this example, the second trenches  206   b ), and the gate electrodes  208   a  and the gate electrodes  208   b  are electrically connected to the different gate interconnections  212   a  and  212   b  via gate contact holes  9   b  and gate contact holes  209   c  that are formed through the BPSG film  209 , respectively. To facilitate understanding of the layout of the gate interconnections  212   a  and  212   b,  the gate interconnections  212   a  and  212   b  are hatched in  FIG. 20B  though it is not a sectional view. 
         [0099]    The semiconductor device according to the embodiment which is equipped with the DMOS having the trench gate structure and the AccuFET are constructed in the above-described manner. The structure can thus be obtained in which no body diode is formed in the region other than the DMOS forming regions, that is, in the AccuFET forming region. 
         [0100]    Next, a description will be made of the operation of the above-configured semiconductor device which is equipped with the DMOS having the trench gate structure and the AccuFET.  FIG. 21A  is a circuit diagram in which the above-configured semiconductor devices TR( 1 ) and TR( 2 ) each having the DMOS and the AccuFET are provided on the high side of an H-bridge circuit for motor driving.  FIG. 21B  is a timing chart showing voltages applied to the gate electrodes  8   a  and  8   b  and voltages applied to the gate electrodes of DMOSs that are located on the low side when motor driving is performed by a PWM-control by means of the H-bridge circuit. In  FIGS. 21A and 21B , symbols G 1  and G 2  denote the gate electrodes  8   a  of the DMOS and the gate electrodes  208   b  of the AccuFETs, respectively, of each of the high-side semiconductor devices TR( 1 ) and TR( 2 ). Symbol G denotes the gate electrodes of each of low-side semiconductor devices TR( 3 ) and TR( 4 ). The waveforms correspond to a case that the AccuFETs are of a normally-off type. Although the gate electrodes  208   a  of the semiconductor device TR( 2 ) are kept at the low level, they may be supplied with the same waveform as the gate electrodes  208   b  are supplied. 
         [0101]      FIGS. 22A to 22C  are schematic diagrams showing current paths of a case that the semiconductor devices of  FIG. 19  are arranged as shown in  FIG. 21A  and the DMOSs are on/off-controlled by a PWM control.  FIG. 22A  shows energization current paths of the DMOS of the semiconductor devices TR( 1 ) or TR( 2 ),  FIG. 22B  shows return current paths of the DMOS of the semiconductor devices TR( 1 ) or TR( 2 ), and  FIG. 22C  shows current paths when the DMOS is off. 
         [0102]    Assume a case that the semiconductor devices according to the embodiment are provided on the high side of the H-bridge circuit as shown in  FIG. 21A  and that an energization current flow as indicated by arrows in  FIG. 22A  and a return current flow as indicated by broken-line arrows in  FIG. 22B . Energization is started by switching the voltage applied to the gate electrodes  208   a  of the DMOS of the semiconductor device TR( 1 ) (shown at the top-left position in  FIG. 21A ) from low to high as shown in  FIG. 21B . At this time, the voltage of the gate electrodes  208   b  of the AccuFET of the TR( 1 ) is set at the low level. The gate voltage of the low-side semiconductor device TR( 4 ) which is diagonally opposite to the semiconductor device TR( 1 ) is switched repeatedly between the high level and the low level. The voltage applied to the gate electrodes  208   b  of the AccuFET of the other high-side semiconductor device TR( 2 ) is switched repeatedly between the low level and the high level in a phase that is approximately opposite to the phase of the gate voltage applied to the low-side semiconductor device TR( 4 ) though dead times exist. A return period starts when the gate voltage applied to the DMOS of the semiconductor device TR( 4 ) is switched from high to low. The operations shown in  FIGS. 22A and 22B  are performed in the energization period and the return period, respectively. 
         [0103]    First, as shown in  FIG. 22A , during the energization period, a voltage is applied to the gate electrodes  208   a  of the semiconductor device TR( 1 ), whereby channels are formed in the base layers  203  that are in contact with the silicon oxide films  207   a  and hence the DMOS is turned on. While this DMOS is on, a current flows from the drain electrode  211  to the source electrode  210  as indicated by arrows in  FIG. 22A . During the return period when the DMOS of the semiconductor device TR( 4 ) is switched from on to off, as shown in  FIG. 22B  a current flows in the direction opposite to the direction in the energization period, that is, from the source electrode  210  to the drain electrode  211 . At this time, since the AccuFET is provided in addition to the DMOS and the voltage applied to the gate electrodes  208   b  of the AccuFET of the semiconductor device TR( 2 ) is switched from low to high, a return current flows through the AccuFET but almost no return current flows through the DMOS. As a result, the loss that is mainly due to Vf of the body diodes can be reduced. 
         [0104]    When the flow of the return current is finished after the DMOS of the semiconductor device TR( 4 ) was switched from on to off, as shown in  FIG. 22C  the portion of the drift layer  202  between the second trenches  206   b  of the AccuFET is pinched off by depletion layers extending from the second trenches  206   b  into the drift layer  202  and the current path leading to the drift layer  202  is interrupted. In this manner, current flow can be prevented while the DMOS and the AccuFET are off. Current leakage can thus be prevented while the AccuFET is off. 
         [0105]    As described above, the semiconductor device according to the embodiment is configured in such a manner that not only the DMOS but also the AccuFET is formed in the single chip. Therefore, a return current is allowed to flow through the AccuFET rather than the DMOS, which provides the advantage that the loss that is mainly due to Vf of the body diodes can be reduced. 
         [0106]    Next, a manufacturing method of the above-configured semiconductor device will be described with reference to sectional views of  FIGS. 23A to 23G  showing a manufacturing process of the semiconductor device according to the embodiment. 
         [0107]    First, in a step of  FIG. 23A , an n +  silicon substrate  201  is prepared and an n −  drift layer  202  is formed on the silicon substrate  201  by epitaxial growth. Then, a silicon oxide film  220  to become a first mask is deposited by CVD and then patterned by photolithography and dry etching, whereby openings are formed through the silicon oxide film  220 . Then, first and second trenches  206   a  and  206   b  are formed in the DMOS forming regions and the AccuFET forming region by anisotropic dry etching with the thus-patterned silicon oxide film  220  used as a mask. 
         [0108]    In a step of  FIG. 23B , the silicon that forms the first and second trenches  206   a  and  206   b  is etched isotropically by about 0.1 μm by chemical dry etching using a CF 4  or O 2  gas. Then, pseudo-oxide films are formed by thermal oxidation in an H 2 O or O 2  atmosphere. The pseudo-oxide films are thereafter removed by wet etching using diluted hydrofluoric acid, whereby etching damage is eliminated and the corner portions of the first and second trenches  206   a  and  206   b  are rounded. Then, thermal oxidation is performed again in an H 2 O or O 2  atmosphere, whereby silicon oxide films  207   a  and  207   b  are formed. 
         [0109]    In a step of  FIG. 23C , doped polysilicon films for formation of gate electrodes  8   a  and  208   b  are formed by LPCVD and then etched back so as to have a desired thickness. Naturally, instead of forming doped polysilicon films, an impurity may be introduced after depositing non-doped polysilicon films. Subsequently, the doped polysilicon films are patterned into gate electrodes  208   a  and  208   b.  Trench gates are thus completed. 
         [0110]    In a step of  FIG. 23D , the silicon oxide film  220  as the first mask is removed. As a result, the drift layer  202  is exposed except in the trench gates. 
         [0111]    In a step of  FIG. 23E , after an ion implantation mask etc. are formed if necessary, the regions other than the regions where base layers  203  will be formed are covered with a second mask. In this state, p-type impurity ions are implanted, whereby base layers  203  are formed in the DMOS forming regions. Then, after the second mask is removed, the regions other than the regions where source regions  204  will be formed are covered with a third mask. In this state, n-type impurity ions are implanted, whereby source regions  204  are formed in the DMOS forming regions. 
         [0112]    In a step of  FIG. 23G , a BPSG film  209  is formed as an interlayer insulating film on the entire surface of the semiconductor substrate  205  and then etching is performed by using a fourth mask (not shown), whereby contact holes  209   a  are formed through the BPSG film  209  (contact holes  209   b  and  209   c  (not shown) are also formed at the same time). The fourth mask is removed thereafter. 
         [0113]    In a step of  FIG. 23G , a metal film is formed on the BPSG film  9  and patterned, whereby a source electrode  210  is formed which is connected to the source regions  204  and the base layers  203  in the DMOS regions and is connected to the drift layer  202  in the AccuFET region and gate interconnections that are electrically connected to the gate electrodes  208   a  and the gate electrodes  208   b  in cross sections that are different from  FIG. 23G  are formed. 
         [0114]    In subsequent manufacturing steps which are not shown in any drawings, the thickness of the silicon substrate  201  is reduced by grinding its back surface and a metal layer as a drain electrode  211  is formed on the back surface. The semiconductor device of  FIG. 19  in which the DMOS having the trench gate structure and the AccuFET are formed is completed. 
       Third Embodiment 
       [0115]      FIG. 24  shows a sectional structure of a semiconductor device according to this embodiment which is equipped with a DMOS having a trench gate structure.  FIG. 25A  is a schematic sectional view showing a wiring form of the semiconductor device of  FIGS. 24 , and  25 B shows its exemplary planar pattern. The semiconductor device according to this embodiment is different from that according to the second embodiment only in that a J-FET is provided in place of the AccuFET. Therefore, only features that are different than in the second embodiment will be described. 
         [0116]    The semiconductor device according to the embodiment is configured in such a manner that a DMOS having a trench gate structure and a J-FET are formed adjacent to each other in a single chip. 
         [0117]    As shown in  FIG. 24 , second trenches  206   c  are formed in a J-FET forming region by digging the drift layer  202  from its surface. A p-type layer  213  is formed in a portion having a prescribed width around the inner wall surface of each second trench  206   c,  that is, in a portion of the drift layer  202  that surrounds each second trench  206   c.  Gate electrodes  208   c  are formed so as to be buried in the respective second trenches  206   c.    
         [0118]    In the semiconductor device having the above sectional structure, as shown in  FIG. 25A , the gate electrodes  208   a  and the gate electrodes  8   c  are electrically connected to different gate interconnections  212   a  and  212   c  in cross sections that are different from  FIG. 24 . More specifically, as shown in  FIG. 25B , the first trenches  206   a  and the second trenches  206   c  extend in the same direction in the form of stripes. One (in this embodiment, the first trenches  206   a ) of the first trenches  206   a  and the second trenches  206   c  project from the tips of the other (in this example, the second trenches  206   c ), and the gate electrodes  208   a  and the gate electrodes  208   c  are electrically connected to the different gate interconnections  212   a  and  212   c  via gate contact holes  209   b  and gate contact holes  9   d  that are formed through the BPSG film  209 , respectively. To facilitate understanding of the layout of the gate interconnections  212   a  and  212   c,  the gate interconnections  212   a  and  212   c  are hatched in  FIG. 25B  though it is not a sectional view. 
         [0119]    The semiconductor device which is equipped with the DMOS having the trench gate structure and the J-FET are constructed in the above-described manner. The structure can thus be obtained in which no body diode is formed in the region other than the DMOS forming regions, that is, in the J-FET forming region. 
         [0120]    Next, the operation of the above-configured semiconductor device which is equipped with the DMOS having the trench gate structure and the J-FET will be described by using a circuit in which the semiconductor devices having the J-FET according to the embodiment and semiconductor devices having only a DMOS are arranged similarly to the arrangement of  FIG. 21A . 
         [0121]      FIGS. 26A to 26C  are schematic diagrams showing current paths of a case that the semiconductor devices of  FIG. 24  are provided on the high side of an H-bridge circuit and the DMOSs are on/off-controlled by a PWM control.  FIG. 26A  shows current paths when a DMOS is on,  FIG. 26B  shows return current paths at an instant when the DMOS is turned off, and  FIG. 26C  shows current paths when the DMOS is off. 
         [0122]    First, as shown in  FIG. 26A , during the energization period, a current flows from the drain electrode  211  to the source electrode  210  as indicated by arrows in  FIG. 26A . During the return period when the DMOS of a low-side semiconductor device is switched from on to off, as shown in  FIG. 26B  a current flows in the direction opposite to the direction in the energization period, that is, from the source electrode  210  to the drain electrode  211 . At this time, since the J-FET is provided in addition to the DMOS and the voltage applied to the gate electrodes  208   c  of the J-FET of the high-side semiconductor device through which a return current is to flow is switched from low to high, a return current flows through the J-FET but almost no return current flows through the DMOS. As a result, the loss that is mainly due to Vf of the body diodes can be reduced. 
         [0123]    When the flow of the return current is finished after the DMOS was switched from on to off, as shown in Fig,  26 C the portion of the drift layer  202  between the p-type layers  213  of the J-FET is pinched off by depletion layers extending from the p-type layers  213  into the drift layer  202  and the current path leading to the drift layer  202  is interrupted. In this manner, current flow can be prevented while the DMOS and the J-FET are off. Current leakage can thus be prevented while the J-FET is off. 
         [0124]    As described above, the semiconductor device according to the embodiment is configured in such a manner that not only the DMOS but also the J-FET is formed in the single chip. Therefore, a return current is allowed to flow through the J-FET rather than the DMOS, which provides the advantage that the loss that is mainly due to Vf of the body diodes can be reduced. 
         [0125]    Next, a manufacturing method of the above-configured semiconductor device will be described with reference to process diagrams of  FIGS. 27A to 27H . The manufacturing method of the semiconductor device according to this embodiment is the same as that according to the second embodiment as far as the process for forming the DMOS is concerned. Therefore, a process for forming the J-FET, which is different than in the second embodiment, will mainly be described below. 
         [0126]    First, steps of  FIGS. 27A to 27D  are executed which are the same as the steps of  FIGS. 23A to 23D  according to the second embodiment. Trench gates are thereby formed in the DMOS forming regions. 
         [0127]    In a step of  FIG. 27E , a silicon oxide film  221  to become a mask is deposited by CVD on the drift layer  202  including the trench gates and then patterned by photolithography and dry etching, whereby openings are formed through the silicon oxide film  221 . Then, second trenches  6   c  are formed in the drift layer  202  in the J-FET forming region by anisotropic dry etching with the thus-patterned silicon oxide film  221  used as a mask. Then, p-type layers  13  are formed so as to surround the trenches  6   c  by, for example, oblique ion implantation using the silicon oxide film  221  as a mask. 
         [0128]    In a step of  FIG. 27F , gate electrodes  208   c  are formed with doped poly silicon in the same manner as in the step of  FIG. 23C . Then, after the silicon oxide film  221  is removed, a step that is the same as the step of  FIG. 23E  of the second embodiment is executed, whereby base layers  203  and source regions  204  are formed. Then, steps of  FIGS. 27G and 27H  are executed which are the same as the steps of  FIG. 23F and 23G  of the second embodiment, respectively. Finally, a drain electrode  11  is formed on the back surface of the silicon substrate  201 . The semiconductor device of  FIG. 24  in which the DMOS having the trench gate structure and the J-FET are formed is completed. 
       Other Embodiments 
       [0129]    Although the above embodiments are directed to the case of using the n-channel transistor having the trench gate structure, naturally the embodiments can also be applied to a case of using a p-channel transistor in which the conductivity types of the individual portions are opposite to those of the embodiments. 
         [0130]    Although the above embodiments are directed to the case that the vertical MOSFET is a DMOS having a trench gate structure, the same advantages as described above can be obtained by forming an AccuFET or a J-FET together with a planar DMOS or an LDMOS. 
         [0131]    The third embodiment is directed to the case that the gate electrodes  8   c  of the J-FET are made of doped polysilicon. Alternatively, for example, trench gates may be formed by forming, in the drift layer  202 , trenches  206   c  and p-type layers  213  surrounding the respective trenches  206   c  and then forming metal layers such as tungsten plugs in the respective trenches  206   c.  In this case, the metal layers may be formed with tungsten in a later step of forming interconnections. 
         [0132]    While the invention has been described with reference to preferred embodiments thereof, it is to be understood that the invention is not limited to the preferred embodiments and constructions. The invention is intended to cover various modification and equivalent arrangements. In addition, while the various combinations and configurations, which are preferred, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the invention.