DE19604043A1 - Vertical MOS field effect transistor device - Google Patents

Abstract

The semiconductor element has a drain zone (1,2) of given conductivity type with at least one relatively insulated polycrystalline gate electrode (6) and at least one source zone of opposite conductivity type. The drain zone incorporates regions (7,8 ; 9,10 ; 11,12 ; 13,14) of opposite conductivity type, with the n-type regions (8,9,1,14) and the p-type regions (7,10,12,13) exhibiting an equal overall doping conc.

Description

The invention relates to a field controllable half Head component according to the preamble of claim 1.

Such controllable by field effect semiconductor devices are such. B. MOS field effect transistors. These transistors have been known for a long time and z. B. in the Siemens data book 1993/94 SIPMOS semiconductors, power transistors and diodes, on page 29ff described. Fig. 4 on page 30 of this data book shows the basic structure of such a power transistor. The transistor shown there represents a vertical n-channel SIPMOS transistor. In such a transistor, the n⁺ substrate serves as a carrier with the underlying drain metallization. Above the n⁺ substrate is followed by an n⁻ epitaxial layer which, depending on the blocking voltage, has different thicknesses and is appropriately doped. The overlying gate made of n⁺-polysilicon is embedded in insulating silicon dioxide and serves as an implantation mask for the p-well and for the n⁺-source zone. The source metalization covers the entire structure and switches the individual transistor cells of the chip in parallel. Further details of this vertical power transistor can be found on page 30ff of the data book.

A disadvantage of such an arrangement is that the transmission resistance R _{on of} the drain-source load path increases with increasing dielectric strength of the semiconductor component, since the thickness of the epitaxial layer must increase. At 50 V, the area-related forward resistance R _on is approximately 0.20 Ohm / m² and increases at a reverse voltage of 1000 V, for example, to a value of approximately 10 Ohm / m².

A semiconductor component is known from US Pat. No. 5,216,275, in which the drain layer applied to the substrate consists of vertical, alternately p-doped and n-doped layers. US 5,216,275 shows these layers, for example in Fig. 4 of the description. The p-layers are denoted by 7 and the n-layer by 6 . The description, in particular from column 2 , line 8 shows that the alternating p and n layers must be connected to the p region 8 and the n region 4 , respectively. However, this leads to a severe limitation in the design of a semiconductor component, since the edge regions can no longer be designed freely.

The object of the present invention is a by Feldef Specifically controllable semiconductor device to specify which despite the high reverse voltage, a low forward resistance provides and does not have the disadvantages shown.

This task is performed by the characteristic part of the To spell 1 solved. Further training is a hallmark of the Un claims.

The invention has the advantage that by a simple one bring paired n or p areas, especially ent long of the current path, on the one hand a good one due to the n-layer Conductivity is guaranteed and on the other hand at Er increasing the drain voltage, the paired areas mutually clear out, which ensures a high reverse voltage.

A particularly advantageous arrangement results from Verwen of a trench area, the edge areas of which be doped in such a way that n- or p- Areas result.

Another advantage arises when using approximately V-shaped isolation trenches because the walls ion implantation with 0 ° angle of incidence and high accuracy at the same time can be placed and thus the n or p ranges in each because it can be produced in one operation.  

The invention is based on the figures he he purifies.

Show it:

Fig. Possibilities 1 is a partial section through an inventive ver tical MOSFET, ge in accordance with A, B, C marked areas, different realization shows,

FIGS. 2a-2d respectively show partial sections based de rer the characteristic process steps for manufacturing a vertical MOSFET according to the invention are shown,

Fig. 3 shows a partial section through a vertical MOSFET having a grave structure,

Fig. 4 shows a partial section through a further vertical MOSFET with trench structure, and

Fig. 5 shows a partial section through a vertical MOSFET having a V-shaped grave structure.

In Fig. 1 shows various embodiments of an inventive arrangement, which are shown for clarity in a figure.

This Fig. 1 represents a vertical MOSFET. The n Substrat-doped substrate 1 forms part of the drain zone and is contacted on the back via a conventional metallization, which forms the drain terminal D. An n⁻-doped epitaxial layer 2 is deposited over this layer 1 , which likewise forms part of the drain zone and in which p-doped source regions 3 are introduced. These p-doped source regions 3 have embedded n + regions 4 . The Sourcemetalli tion 5 forms a short circuit between this n⁺- and p-source region 3 , 4th In the figure, a plurality of source regions 3 , 4 are shown, which are spaced from one another and two of which each define an intermediate region in connection with the drain zone 1 , 2 , above which a gate 6 is arranged, embedded in gate oxide 17 .

P- and n-doped regions 7 , 8 and 9 , 10 and 11 , 12 and 13 , 14 are planted within the weakly doped n⁻ drain zone 2 . These do not have to, but can touch each other and form a pn junction.

The p / n regions 7 , 8 can, as shown in the region A, be of spherical design and extend along the current path of the drain-source load path. In area B, these p / n areas 10 , 11 or 11 , 12 form, for example, threads, strips or vertically extending planes. These areas can, as indicated by the areas 9 and 10 within the epitaxial layer 2 "floating", ie floating, lie and fill only part of the epitaxial layer 2 or, as indicated by 11 , 12 , from the upper surface of the epitaxial layer 2 extend to substrate 1 and / or into substrate 1 . As shown in area B, the distance d between the layers 9 , 10 and 11 , 12 can be greater than or equal to 0.

A further embodiment is shown in area C in which a statistical distribution of the p- and n-doped regions 13 , 14 is provided. The cross section of the water p / n regions 13 , 14 and also the doping distribution can be irregular.

It is essential that the number of p regions 7 , 10 , 12 , 13 introduced is approximately equal to the number of n regions 8 , 9 , 11 , 14 introduced . It should also be noted that the sum of the volume expansions of the introduced p regions 7 , 10 , 12 , 13 is approximately equal to or less than that of the n regions 8 , 9 , 11 , 14 .

Likewise, in the case of the arrangement according to area C, the average concentration of the distributed p-areas in be approximately equal to or greater than that of the introduced n regions.

The distance d between the individual p and n areas should te is preferably smaller than the width of the space charge zone between the p / n areas at the breakdown voltage between the neighboring p / n areas, but can be like him also thinks to be zero.

In the following, the mode of operation of such a device is invented structure according to the invention explained in more detail.

If the drain voltage is low, the conductivity is good since the n-zone 15 , 25 or the zones formed by the n-doped regions 8 , 9 , 11 , 14 have a low resistance. If the drain voltage is increased, at a moderate voltage, e.g. B. a voltage less than 30 V, the p- or n-doped layers 9 , 10 ; 11 , 12 or areas 7 , 8 ; 13 , 14 mutually cleared. With a further increase in voltage, the vertical field strength is now increased further and the epitaxial layer 2 absorbs the voltage.

In detail, this process takes place as follows. The evacuation starts from the surface under the gate electrode 6 and the source regions 3 , 4 . She then strides into Ge 9 , 10 ; 11 , 12 or areas 7 , 8 ; 13 , 14 ahead. If the space charge zone reaches the first p regions 7 , 10 , 12 , 13 , these regions remain at the voltage which has reached the potential of the space charge zone. Then the next environment is cleared in the direction of the drain connection D. This process is repeated from layer to layer.

In this way, the space charge zone proceeds until the zone below the introduced dopings within the epitaxial layer 2 is reached. Overall, the space charge zone is then constructed as if the additionally introduced p / n regions 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 were not present.

The dielectric strength is only determined by the thickness of the epitaxial layer 2 . Thus, the arrangement according to the invention can meet both requirements, namely a low, raw forward resistance R _on with a high dielectric strength.

In a modification, such a structure is also functional as an IGBT if, for. B. the lower n⁺ zone 1 according to FIG. 1 is switched to p⁺.

The structures according to the invention can be used both with vertical and with laterally constructed semiconductor structures. In the case of lateral structures, p-shaped and n-shaped areas should then be aligned in horizontal planes. These can e.g. B. can be buried as buried layer in the n⁻ layer 2 .

FIGS. 2a to 2d show a possible method of manufacturing an arrangement according to FIG. 3. A first thin n⁻-doped epitaxial layer 2 is grown on an n⁺-doped substrate 1 . This is doped, for example, by appropriate masking and ion implantation with alternating n or p regions 28 and 29 . The doping can of course also be followed by other known methods.

Then, as can be seen in Fig. 2b, another epi taxis layer is applied, which is doped in the same way as before.

By repeating this step, the n⁻-doped zone 2 is finally completed by a multi-stage epitaxial deposition up to the source regions 3 , 4 to be introduced.

Depending on the mask used, a wide variety of structures can be formed per layer. The doping of the Be rich 28 and 29 z. B. be chosen such that the individual doped regions 28 , 29 of a layer combine after high-temperature treatment with those of the layer below, so that overall, as shown in Fig. 2c, strip-shaped regions 28 and 29 form. The regions 28 , 29 doped in the individual layers can, however, also be separated from one another, as is shown in regions A and C in FIG. 1. Statistical spatial distributions of the individual areas can also be achieved by appropriate selection of the masks.

Finally, the source regions 3 , 4 z. B. introduced in a white tere applied epitaxial layer, and in the usual areas such. B. a further doping of n / p regions 28 , 29 take place, so that the strip-shaped regions 28 , 29 extend in the zones in which no source region 3 , 4 is provided, to the surface of the epitaxial layer 2 .

The p- and n-doped regions introduced at the edge region, designated 30 and 31 in FIG. 2d, can preferably be less doped than the other regions 28 , 29 .

There now follow further steps for applying the gate electrodes 6 or the edge gate electrode 32 and the metallization 5 in a known manner.

Fig. 4 shows another embodiment of an inventive vertical MOSFET. Identical areas are provided with the same reference symbols in accordance with the preceding figures.

This MOSFET differs from that shown in FIG. 1 or FIG. 3 in the design of the n⁻-doped drain zone 2 . Below the gate electrodes 6 , a vertical trench structure 24 extends from the surface of the epitaxial layer 2 to the substrate layer 1 . This is completely or partially with isolators z. B. padded oxide and / or lightly doped polysilicon. A combination of several superimposed insulation layers with intervening weakly doped polysilicon is also possible.

The trench walls are covered with an n-zone 25 , which in turn is surrounded by a p-zone 26 . The p- and n-doping in the trench cladding is dimensioned such that with a U _D voltage which is less than the breakdown voltage between the regions 25 and 26 , both n and p regions 25 and 26 are almost completely cleared out.

The cross section of the trenches 24 can be round, strip-shaped, ie any. The trench does not have to extend into the substrate zone 1 , rather the depth profile can be freely selected. Is z. B. selects a round trench cross-section, the layers 25 , 26 receive a quasi cylindrical shape.

Of course, as indicated by brackets in FIG. 3, the inner wall region 25 can also be p-doped and the outer wall region 26 surrounding it can be n-doped.

It is also possible to use only part of the trench walls n and the p layer.

A possible production method is described below: First, the trenches are inserted into the epitaxial layer 2 .

Then z. B. a doping source for boron (p) deposited and driven. This is how p-layer 26 is created . The n-dopant source is then deposited. This source is an arbitrary z. B. manufactured by ion implantation, thin surface layer. After the introduction of the n- and p-doping, the trench is filled with insulators. This can e.g. B. by oxidation or deposition. After the trenches are finished, the cell structure can be produced by the usual method. The p-zones 26 can be connected in places with the cell p-zones, this case not being shown in FIG. 3.

FIG. 4 shows a further exemplary embodiment corresponding to the arrangement shown in FIG. 3. The same elements are also provided with the same reference symbols here. The difference to the arrangement according to FIG. 3 consists in the configuration of the gate structure. In contrast to the arrangement shown in FIG. 3, the gate structure here is divided into two or has a central recess 29 which divides the gate into two partial regions 27 and 28 . The purpose of this arrangement is that such a poly gate masks the trench region 24 . As a result, a simplified production of the Grabenbe area can be provided. As in known structures in which the gate is used to mask certain areas during the manufacturing process, the shape of the gate is used here to provide the formation of the trench 24 in accordance with the shape of the recess 29 .

Fig. 5 shows a further embodiment of a vertical MOSFET. The same elements are also provided with the same reference symbols here. The structure shown corresponds essentially to that shown in Fig. 3 with the difference that the trench region is formed here as an approximately V-shaped trench 31 . Accordingly, the p- or n-doped enveloping edge regions 30 , 32 are also V-shaped. In the example shown in FIG. 5, the contacting layer 32 applied to the underside of the component on the substrate layer 1 is also shown .

It can be particularly advantageous to use the crown or um to make the intersection of the trench more U-shaped.

Such a trench (trench) drain MOSFET is easy to manufacture if the trenches 31 are V-shaped, as shown in FIG. 5, using a very small angle (Φ = approximately 5 ° to 10 °). Then the walls 30 , 32 can be covered with high accuracy and uniformity by ion implantation with 0 ° incidence angle. The n- and p-dopants can be driven from the trench wall by one or more high-temperature treatments into the single-crystalline silicon around layers 1 and 2 .

Optionally, only one side wall could be covered with layers 30 and 32 depending on the design of the trenches.

The trenches 31 can be produced as a first step, but also after the polysilicon deposition. In the latter case, the masking of the trenches 31 is carried out through openings in the polysilicon and the gate oxide. The cells can be designed as columns, but the V-shaped trenches can also be isolated.

The trenches 24 , 31 can run in strips and thus surround the individual cells of a MOSFET. However, they can also have a conical shape and be introduced at the crossing points of cells arranged in a matrix.

Of course, the epitaxial layer can in all cases be either of the n⁻ or p⁻ type.

In summary, it should be noted that the present invention can provide both vertical and lateral MOSFETS with a low forward resistance R _on and a high reverse voltage at the same time. What is essential is the formation of pairs of p-doped or n-doped regions, which are introduced in a structured or statistically distributed manner, preferably strip-shaped regions being provided which are formed along the current path of the load path. The present invention is applicable to both MOSFETS from the p-channel as well as MOSFETS from the n-channel or with corresponding IGBTs.

Claims (12)

1. Semiconductor component controllable by field effect

• - a drain zone of the first conduction type,
• at least one gate electrode made of polycrystalline silicon, which is insulated from the drain zone,
• at least one source region of the second conduction type introduced in the drain zone,

characterized in that areas of the first and second line types ( 7 , 8 ; 9 , 10 ; 11 , 12 ; 13 , 14 ; 28 , 29 ) are introduced in the drain zone ( 1 , 2 ), the total amount of the doping being introduced n- areas ( 8 , 9 , 11 , 14 , 28 ) corresponds approximately to the total amount of the dosing of the introduced p-areas ( 7 , 10 , 12 , 13 , 29 ). 2. Controllable by field effect semiconductor device according to claim 1, characterized in that the loading areas of the first and second conductivity type ( 7 , 8 ; 9 , 10 ; 11 , 12 ; 13 , 14 ; 28 , 29 ) in the drain zone ( 1 , 2 ) are arranged in pairs. 3. Controllable by field effect semiconductor device according to claim 1 or 2, characterized in that the few wise introduced areas of the first and second line type ( 7 , 8 ; 9 , 10 ; 11 , 12 ; 13 , 14 ; 28 , 29 ) in the drain zone ( 1 , 2 ) has a distance from one another of greater than or equal to 0 and less than or equal to the width of the space charge zone. 4. Controllable by field effect semiconductor device according to one of claims 2 to 3, characterized in that the pair of wise arranged areas ( 9 , 10 ; 11 , 12 ; 28 , 29 ) are each strip or thread-shaped. 5. The field effect controllable semiconductor component according to one of claims 2 to 3, characterized in that the areas introduced into the drain zone ( 7 , 8 ; 13 , 14 ; 28 , 29 ) are spherical. 6. Field effect controllable semiconductor component according to one of claims 1 to 4, characterized in that within the drain zone ( 1 , 2 ) a trench ( 24 , 31 ) is provided which extends from the surface into the drain zone ( 1 , 2 ) , wherein the trench ( 24 , 31 ) is filled with at least one insulator and the trench ( 24 , 31 ) has a first vertically running edge region ( 25 , 30 ) which is at least partially doped by the first or second conductivity type and which is at least partially surrounded by a second vertically parallel edge region ( 26 , 32 ) which is of the other type of conduction. 7. Controllable by field effect semiconductor device according to claim 6, characterized in that the trenches ( 31 ) are approximately V-shaped. 8. Controllable by field effect semiconductor device according to claim 7, characterized in that the point around the trenches ( 31 ) is U-shaped. 9. Semiconductor component controllable by field effect according to one of claims 6 to 8, characterized in that the Iso a combination of insulation material and polysili zium is. 10. Controllable by field effect semiconductor device according to one of claims 6 to 9, characterized in that the trenches ben ( 24 , 31 ) extend in strip form. 11. Controllable by field effect semiconductor device according to one of claims 6 to 9, characterized in that the trenches ben ( 24 , 31 ) are conical.