DE10124115A1 - Semiconductor arrangement for switching inductive loads such as motor, has Schottky diode that is formed by Schottky contact between source electrode and drift zone of semiconductor surface - Google Patents

Abstract

The arrangement has a gate electrode (40) arranged in a trench extending in vertical direction of semiconductor surface (100). The gate electrode is insulated from the semiconductor surface and a source electrode (60). A Schottky diode connected in parallel with a drain-source path of the MOS transistor, is formed by the Schottky contact between source electrode and drift zone (12) of semiconductor surface.

Description

The present invention relates to a semiconductor device, with a mos transistor and one parallel to the drain Source path of the MOS transistor switched Schottky Diode.

Such a semiconductor arrangement is for example from the US 4,811,065 known. The known semiconductor arrangement has a transistor designed as a DMOS transistor with a gate electrode arranged above the semiconductor body, where a conductive when a control voltage is applied Channel in the lateral direction of the semiconductor body in one body area located below the gate electrode between a source zone and a drain zone. In the Drain current flows in the vertical direction of the Semiconductor body to one on the back of the semiconductor body arranged drain electrode. The Schottky diode is in the known semiconductor arrangement by a metal semiconductor Transition between a source electrode and the drain zone educated.

Such semiconductor devices are used as power Components for switching loads, especially for Switching inductive loads, such as motors, Use. As long as the transistor is operating in the forward direction is, that is, if with n-type MOSFET a positive The Schottky diode blocks drain-source voltage. The Schottky diode conducts and acts as a freewheeling element when the Transistor with a voltage in the reverse direction, so a negative drain-source voltage in the case of an n- conductive MOSFET, is operated. Such "Reverse voltage" can occur when switching inductive loads using the MOSFET by the induced in the load after the MOSFET is turned off Tension occur.

The Schottky diode is parallel to one in the MOSFET body diode present parallel to the drain-source path, through a pn junction between the body area and the Drain zone and by short-circuiting the body area with the Source zone is formed. The forward voltage of the Schottky Diode is less than the forward voltage of this body diode, so the Schottky diode always conducts before the body diode passes. Unlike the body diode, the Schottky Diode no charge carriers during the conductive state saved, which are removed again to block the diode have to. The use of the Schottky diode as a freewheel element reduces the compared to the body diode as a freewheel element when switching an inductive load - especially at high ones Switching frequencies not inconsiderable - switching losses.

WO 00/51167 discloses a semiconductor arrangement which realizes a MOSFET with a parallel Schottky diode is known. The MOSFET is a trench MOSFET with a A plurality of similar transistor cells, formed, wherein each of the cells one in a trench one Has semiconductor body formed gate electrode, wherein adjacent to side faces of these gate electrodes source, body and drain zones are formed. To realize the Schottky diode special "Schottky cells" are provided, which are formed in that in semiconductor areas, no source and body between some of the gate electrodes Zones are provided and the drain zone in these Areas from the back to the front of the Semiconductor body extends to the front with a Metal layer to form a Schottky contact.

A similar semiconductor arrangement is known from US 6,049,108 known. This semiconductor arrangement also has one Parallel connection of a MOSFET and a Schottky diode realized, the MOSFET as a trench MOSFET with a variety similarly constructed transistor cells is realized. to Formation of the Schottky diode are here also separate "Schottky Cells "where the drain zone is between adjacent gate electrodes to the front of the Semiconductor body extends.

The provision of separate "Schottky cells" in the cell field of one On the one hand, transistor requires additional Procedural steps because these cells do not go through the same processes as that Transistor cells can be formed, and also increases the to realize a transistor with a given Current resistance area required.

The aim of the present invention is therefore a Semiconductor arrangement with a MOS transistor and one to the MOS Transistor parallel Schottky diode available too places that can be realized to save space.

This goal is achieved by a semiconductor device according to the Features of claim 1 solved.

The semiconductor arrangement according to the invention has one Semiconductor body with a first connection zone of a first Line type, a second connection zone of the first Line type and one between the first and second connection zone trained body zone of a second conduction type, wherein the first connection zone, the body zone and the second Connection zone at least in sections in the vertical direction of the semiconductor body are arranged one above the other. A Control electrode is insulated from the semiconductor body is formed in a trench that is vertical Direction of the semiconductor body from the second connection zone extends through the body zone into the first connection zone. The second connection zone and the body zone are through one Connection electrode contacts the opposite Control electrode is insulated. Furthermore, the invention Semiconductor device a Schottky contact between which Connection electrode and the first connection zone formed, wherein this Schottky contact adjacent to in a space-saving manner the body zone, or adjacent to the contact area between the connecting electrode and the body zone is formed.

The first, n-doped in an n-type MOS transistor The connection zone forms the drain zone of the transistor and on the other hand the anode through the first connection zone and the connection electrode that forms the source electrode Schottky diode formed. The second connection zone forms the source zone of the MOS transistor and the control electrode forms the gate electrode of the MOS transistor. The source Zone and the body zone are through the connection electrode short-circuited to one in a well known manner to render parasitic bipolar transistor ineffective by the sequence of the drain zone leading to the drain zone complementary body zone and the source zone is formed and the otherwise reduce the maximum reverse voltage of the transistor would.

The arrangement of the control electrode in a vertical Trench extending in the direction of the semiconductor body enables a particularly space-saving implementation of the Semiconductor arrangement with the MOS transistor and the Schottky diode. When a control voltage is applied between the gate Electrode and the source zone or the the source zone Contacting source electrode forms in the body zone along the gate electrode a vertical vertical channel Direction of the semiconductor body between the source zone and the drain zone.

The semiconductor component according to the invention is preferred constructed like a cell and thus has a large number of similar structures, each with a gate electrode and sequences of a formed adjacent to the gate electrode Source zone, a body zone and a drain zone. each this cell is adjacent to the body zone the Schottky source electrode and the drain zone Contact us.

In addition, each of these structures is adjacent to that Contact between the connection electrode and the body zone Schottky contact available. All cells are with the semiconductor device according to the invention thus constructed and can be made by the same process steps. In addition, the electricity is distributed through the large number of Schottky contacts formed Schottky diode more uniform the component as in such semiconductor devices the state of the art, where only a few Schottky Contact are provided in the cell field of the transistor.

In one embodiment of the invention it is provided that the first connection zone, or the drain zone, in sections up to a front side of the semiconductor body extends, with the Schottky contact on the front of the Semiconductor body between the source electrode and the Drain zone next to the contact between the source electrode and the body zone or the contact between the source Electrode and the source zone is formed.

In a further embodiment it is provided that the Source electrode in sections in a vertical Direction of the semiconductor body extending second trench is formed, the Schottky contact in the second trench formed between the source electrode and the drain zone is. In this embodiment, the body zone and the Source zone on the side walls of the second trench through the Source electrode contacted and short-circuited.

The semiconductor body consists for example of silicon, the doping of the drain zone following the source electrode to form the Schottky contact is preferably less than 1.10 ¹⁷ cm ^-3 .

As the metal of the source electrode to form the Schottky Contacts are particularly suitable for aluminum, tungsten, Tantalum, titanium, platinum or cobalt silicide. The source Electrode can be made entirely from the above Materials exist or even multi-layered with a thin one Layer of this material in the area of the Schottky contact and an overlying thicker layer of aluminum or a highly doped n-polysilicon.

The present invention is hereinafter described in Embodiments explained in more detail with reference to figures. In the figures shows

Fig. 1 shows a cross section through a semiconductor body with an inventive semiconductor device according to a first embodiment;

Fig. 2 shows a cross section through the semiconductor body of FIG. 1 in top view in a first embodiment (Fig. 2a), a second embodiment (Fig. 2b) and a third embodiment (FIG. 3c) with respect to an arrangement of the gate electrodes,

Fig. 3 shows a cross section through a semiconductor body with an inventive semiconductor device according to a second embodiment,

Fig. 4 shows a cross section through the semiconductor body of FIG. 3 in top view,

Fig. 5 shows a cross section through a semiconductor body with an inventive semiconductor device according to a third embodiment;

Fig. 6 shows a cross section through a semiconductor body with an inventive semiconductor device according to another embodiment,

Fig. 7 is an electrical equivalent circuit diagram of the semiconductor device according to the invention.

In the figures, unless otherwise stated same reference numerals same parts and areas with the same Importance.

Fig. 1 shows a cross section through an inventive semiconductor component, through which an n-type MOS transistor, and a parallel to the drain-source path DS of the MOS transistor connected Schottky diode are realized. The MOS transistor has a multiplicity of transistor cells of the same structure, which are connected together, two transistor cells of this type being shown in FIG. 1.

The semiconductor component according to the invention has a semiconductor body 100 with a heavily n-doped zone 10 , for example a substrate, and a weakly n-doped zone 12 , for example an epitaxial layer, applied to the heavily n-doped zone 10 . P-doped zones 20 are introduced into the weaker n-doped zone 12 from a front side 101 of the semiconductor body, in which zones heavily n-doped zones 30 are in turn formed, the p-doped zone 20 being the heavily n-doped zone 30 and separates the weaker n-doped zone 12 from one another.

The heavily n-doped zone 10 and the weakly n-doped zone 12 form the drain zone of the MOS transistor, which is contacted on a rear side 102 of the semiconductor body by a metallization 70 , which forms the drain connection D. The p-doped zone 20 forms the body zone and the heavily n-doped zone 30 forms the source zone of the MOS transistor.

Starting from a front side 101 of the semiconductor body, trenches extend in the vertical direction of the semiconductor body 100 through the source zone 30 and the body zone 20 into the weaker n-doped zone 12 , which acts as the drift zone of the MOS transistor. Gate electrodes 40 are formed in the trenches, which likewise extend in the vertical direction 12 , the gate electrodes 40 being insulated from the source, drift and body zones 30 , 12 , 20 by insulation layers 52 . The drift zone 12 , the body zone 20 and the source zone 30 are arranged one above the other on both sides of the trenches in the vertical direction of the semiconductor body 100 .

The source zone 20 is contacted by a source electrode 60 , this source electrode 60 making contact not only with the source zone 30 but also with exposed areas of the body zone 20 in the region of the front side 101 of the semiconductor body. The source electrode 60 short-circuits the source zone 30 and the body zone 20 , as a result of which the sequence of the n-doped drift zone 12 , the p-doped body zone 20 and the n-doped source zone 30 formed parasitic bipolar transistor becomes ineffective. The gate electrode 40 is insulated from the source electrode 60 by means of an insulation layer 50 , which is formed above the gate electrode 40 on the front side 101 of the semiconductor body.

The source electrode also contacts exposed areas of the drift zone 12 adjacent to the body zone 20 in a region 14 of the front side 101 , which forms part of the drain zone. The source electrode 60 and the drift zone 12 form a Schottky contact in the area 14 of the front side of the semiconductor body 101 , the drift zone 12 in this area possibly being less doped than in the other areas. In the region of the Schottky contact, the source electrode 5 consists of a metal, for example aluminum, or of a silicide, such as, for example, tungsten silicide, tantalum silicide, platinum silicide, cobalt silicide or titanium silicide. The source electrode 60 can be made entirely of this material or can be built up in layers, the source electrode 60 then having one of the materials mentioned in the region of the Schottky contact, via which an aluminum layer or a highly doped layer of n- conductive polysilicon can be applied.

When a drive voltage is applied between the gate electrode 40 G and the source electrode S, a conductive channel which runs in the vertical direction between the source zone 30 and the drift zone 12 is formed along the trench in the body zone 20 when a voltage is applied between the drain electrode 70 , D and the source electrode 60 , S allows a current to flow. When a positive drain-source voltage is applied, which is below the breakdown voltage of the Schottky contact, the Schottky contact blocks, a current flow between the drain zone and the source zone is then only via the conductive channel shown in dashed lines in the figures possible in body zone 20 .

When a negative drain-source voltage is present, the Schottky contact conducts and enables a current to flow between the source electrode S and the drain electrode D, bypassing the structure with the body zone 20 , the source zone 30 and the gate Electrode 40 .

Due to the pn junction between the body zone 20 and the drift zone 12 , a so-called body diode is present between the source electrode S and the drain electrode D, the circuit symbol of which is shown in FIG. 1. The forward voltage of this diode formed by the pn junction is greater than the forward voltage of the Schottky diode, so that when a negative drain-source voltage is applied, this body diode does not become conductive, that is to say remains ineffective.

Fig. 7 shows the electrical equivalent circuit diagram showing the semiconductor device according to the invention. The equivalent circuit diagram shows a MOS transistor T with a Schottky diode DS connected in parallel with the drain-source path DS of the MOS transistor, which is formed by the Schottky contact between the source electrode 60 and the drift zone 12 , and with a body diode D connected in parallel with the drain-source path DS of the MOSFET and in parallel with the Schottky diode DS, which is formed by the pn junction between the body zone 20 and the drift zone 12 .

Fig. 2 shows a cross section through a semiconductor arrangement according to FIG. 1 in a sectional plane AA, wherein in Fig. 2a shows a first embodiment for forming the gate electrode 40 and in Fig. 2b, a second embodiment for forming the gate electrode 40 is ,

In the exemplary embodiment according to FIG. 2a, the gate electrode 40 and the insulation layer 52 arranged adjacent to the gate electrode 40 , the p-doped body zone 20 and the n-doped source zone 30 extend elongated in the lateral direction of the semiconductor body 100 , ie perpendicular to the plane of the drawing according to FIG. 1.

In the exemplary embodiment according to FIG. 2b, the trench and the gate electrode 40 arranged therein are columnar, the insulation layer 52 , the p-doped body zone 20 and the n-doped source zone 30 surrounding the gate electrode in a ring.

In the exemplary embodiment according to FIG. 2 c, the trench and the gate electrode 40 arranged therein are arranged in a ring around the body zone 30 , the source zone 20 and the drain zone 12 .

Fig. 3 shows another embodiment of a semiconductor device according to the invention in cross section. This semiconductor arrangement differs from that shown in FIG. 1 by the formation of the source electrode 60 . In the exemplary embodiment according to FIG. 3, in addition to the trench in which the gate electrode 40 is formed, a second trench 62 extends from the front side 100 into the semiconductor body, the trench 62 ending below the p-doped body zone 20 , The source electrode 60 is formed in this trench 62 , the Schottky contact being formed in the region of a bottom of this trench 62 between the source electrode 60 and the drift zone 12 . The source electrode S contacts the source zone 30 and the body zone 20 on side surfaces of this trench 62 and thereby short-circuits the body zone 20 and the source zone 30 . In the exemplary embodiment according to FIG. 3, unlike the exemplary embodiment according to FIG. 1, no space for short-circuiting the source zone 30 and the body zone 20 by means of the source electrode 60 has to be provided on the front side 101 of the semiconductor body, since in the case of the embodiment shown in FIG. 6, the short circuit does not take place on the front 101 but on a line extending in the vertical direction of the semiconductor body 100 side surface of the trench 62nd In the embodiment according to FIG. 3 thus a higher packing density is achieved, that is, it can be realized a greater number of transistor cells in a given area.

1 Further, a possible manufacturing method of the semiconductor device of FIG. 3 compared to a method in the semiconductor device of FIG. Simplified.

In the production of a semiconductor device shown in Fig. 1 must doped p-type for the production of the body regions 20 and source regions are applied 30 masks on the front side of the semiconductor body 101 to ensure, firstly, that doped p-in diffusion zone 20 n-doped regions of the drift zone 12 remain on the front side 101 , which are later contacted to form the Schottky contact. Furthermore, areas of the body zone 20 exposed on the front side 101 of the semiconductor body must be covered when the source zone 30 is diffused in. In a manufacturing method for manufacturing a semiconductor device according to FIG. 3, the epitaxial layer 12 doped p-from the front side 101 of the semiconductor body forth to form the body zone 20 on the entire surface of p-doped, are being followed on the entire surface of the front side 101 a heavily n-doped zone 30 can be doped. The trench 62 is then produced, which extends through the source zone 30 and the body zone 20 into the drift zone 12 .

Also in the embodiment according to FIG. 3, the Schottky contact in the connection to the contact between the source electrode 60 and the body zone 20 is formed. Thus, in the semiconductor component according to the invention, a Schottky contact is provided adjacent to each connection of the source electrode 60 to the body and source zones 20 , 30 . The cells of the semiconductor component according to the invention are thus constructed in the same way, with each transistor cell being assigned a Schottky contact, which leads to a more uniform current distribution over the component if the Schottky diode formed by the individual Schottky contacts is conductive. In addition, all cells of the semiconductor component can be produced using the same method steps.

FIG. 4 shows a cross section through the semiconductor arrangement according to FIG. 3, wherein in the exemplary embodiment the gate electrode 40 and the insulation layer 52 arranged adjacent to the gate electrode 40 and the body zone 20 or the source zone 30 are elongated are formed in the lateral direction of the semiconductor body 100 . The trench 62 with the source electrode 60 arranged therein can likewise extend in an elongated manner in the lateral direction of the semiconductor body, as the zones hatched in FIG. 4 show. There is also the possibility of providing spaced-apart rectangular trenches into which the source electrode extends, as shown by the dashed lines in FIG. 4, the regions located between these trenches 62 being represented by the p-doped body zone 20 , or lying above by the source zone 30 , are filled.

FIG. 5 shows a further exemplary embodiment of a semiconductor arrangement according to the invention, which differs from the semiconductor arrangement shown in FIG. 4 in that the gate electrode 40 is designed as a field plate 42 in an area of the trench formed in the drift zone 12 . For this purpose, the electrode tapers in this area and is surrounded by a thicker insulation layer 54 than the drift zone 42 than in the area of the body zone 20 and the source zone 30 .

The formation of the gate electrode 40 as a field plate 42 in the area of the drift zone 12 increases the dielectric strength of the MOS transistor, which is largely determined by the thickness of the gate insulation.

Fig. 6 shows a further embodiment of a semiconductor device according to the invention, wherein the MOS transistor is implemented as a so-called drain-up transistor. In this transistor, the drain zone is not contacted on a rear side of the semiconductor body but, like the source zone 30 and the gate electrode 40, is contacted from a front side of the semiconductor body. In this embodiment, the drain zone 10 A is formed as a buried, heavily n-doped layer on a semiconductor substrate 14 , in FIG. 6 a heavily p-doped semiconductor substrate. In addition, a heavily n-doped region 10 B is provided, which extends in the vertical direction of the semiconductor body 100 and which connects the buried layer 10 A to a drain electrode 70 on the front side 101 of the semiconductor body 100 .

A field plate 42 is provided as the edge termination of the cell field, of which only the gate electrode 40 and the source zone 30 are shown, which, like the gate electrode 40, is formed in a trench that extends in the vertical direction and is opposite the semiconductor body 100 an insulation layer 54 is insulated. The field plate 42 is connected to the gate electrode 40 . However, no source zone is arranged in the body zone 22 adjacent to the field plate, so that no conductive channel can form adjacent to the field plate. It is the task of the field plate 42 to influence the field strength curve at the edges of the cell field in such a way that the probability of a breakdown when a reverse voltage is applied is no higher than within the cell field.

The field plate, which forms the end of the cell field, is formed in the lateral direction at a distance from the region 10 B or the drain connection 70 . The semiconductor region between the field plate 42 and the drain connection 70 , like the drift zone 12, is weakly n-doped.

Otherwise, the structure of the semiconductor arrangement corresponds to the structure of the semiconductor arrangement according to FIG. 3 with regard to the Schottky contact between the source electrode 60 and the drift zone 12 , with regard to the source electrode 60 and with respect to the gate electrode 40 , to which reference is made becomes.

Of course, there is also the possibility of using the structures according to FIGS. 1 and 4 in a drain-up transistor according to FIG. 6. LIST OF REFERENCE NUMBERS T MOS transistor
D drain connector
S source connector
G gate connector
DS Schottky diode
DI body diode
100 semiconductor bodies
70 metallization
10 substrate
12 epitaxial layer
60 source electrode
62 trench
50 , 52 insulation layer
20 body zone
30 source zone
40 gate electrode
42 field plate
54 insulation layer

Claims (7)

1. A semiconductor device which has the following features: - A semiconductor body ( 100 ) with a first connection zone ( 10 , 12 ; 10 A, 12 ), a first conductivity type (n), a second connection zone ( 30 ) of the first power type (n) and one between the first and second connection zone ( 10 , 12 , 30 ; 10 A, 12 , 30 ) formed body zone ( 20 ) of a second conduction type, the first connection zone ( 10 , 12 ; 10 A, 12 ), the body zone ( 20 ) and the second connection zone ( 30 ) are arranged at least in sections in the vertical direction of the semiconductor body ( 100 ) one above the other, - A control electrode ( 40 ) which is isolated from the semiconductor body ( 100 ) in a trench which extends in the vertical direction of the semiconductor body ( 100 ) from the second connection zone ( 30 ) through the body zone ( 20 ) to the first Connection zone ( 10 , 12 ; 10 A, 12 ) extends, a connection electrode ( 60 ) which contacts the second connection zone ( 30 ) and the body zone ( 20 ) and is insulated from the control electrode ( 40 ), - A Schottky contact, which is formed between the connection electrode ( 60 ) and the first connection zone ( 12 ) adjacent to the body zone ( 20 ). 2. The semiconductor arrangement as claimed in claim 1, in which the first connection zone ( 12 ) extends in sections to a front side ( 101 ) of the semiconductor body ( 100 ), the Schottky contact being formed on the front side ( 101 ) of the semiconductor body ( 100 ). 3. The semiconductor arrangement as claimed in claim 1, in which the first connection electrode ( 60 ) is formed in sections in a second trench ( 62 ) running in the vertical direction of the semiconductor body ( 100 ), the Schottky contact being formed in the second trench ( 62 ). 4. The semiconductor arrangement as claimed in claim 3, in which the body zone ( 20 ) and the second connection zone ( 30 ) are exposed on side walls of the trench ( 62 ) and are contacted by the connection electrode ( 60 ). 5. Semiconductor arrangement according to one of the preceding claims, in which the semiconductor body ( 100 ) consists of silicon and that to form the Schottky contact, the doping of the first connection zone ( 12 ) in the region of the Schottky contact is less than 1.10 ¹⁷ . 6. Semiconductor arrangement according to one of the preceding claims, in which the connection electrode ( 60 ) in the region of the Schottky contact comprises aluminum, tungsten silicide, tantalum silicide, platinum silicide, cobalt silicide or titanium silicide. 7. Semiconductor arrangement according to one of the preceding claims, in which the control electrode ( 40 ) in the region of the first connection zone ( 12 ) is designed as a field plate ( 42 ) which in this region has a thicker insulation layer ( 54 ) than in the region of the body zone ( 20 ) and the second connection zone ( 20 ) is surrounded.