EP0657066A1

EP0657066A1 - Field-effect-controlled semiconductor component

Info

Publication number: EP0657066A1
Application number: EP93919100A
Authority: EP
Inventors: Horst Neubrand; Jacek Korec; Erhard Stein; Dieter Silber
Original assignee: Daimler Benz AG
Current assignee: Mercedes Benz Group AG
Priority date: 1992-08-29
Filing date: 1993-08-19
Publication date: 1995-06-14
Also published as: WO1994006158A1; JPH08502858A; DE4228832C2; DE4228832A1; US5587595A

Abstract

The invention concerns a field-effect-controlled semiconductor component with at least four zones of alternating opposite conduction types, an emitter region at the anode end, a first and a second base region adjacent to the emitter region, an emitter region at the cathode end and an additional adjacent emitter region, plus an anode contact, a contact with the emitter region at the cathode end and a MOS field-effect transistor control-electrode contact. The cathode-end emitter region and the adjacent emitter region form the source and drain of a MOS field-effect transistor. The part (34, 36) of the cathode-end base region which is adjacent to the emitter region (44) of a main thyristor, or a separate highly p-doped region (38) adjacent to the cathode-end base region, is connected to the cathode contact (72) by an integrated component (D) with a non-linear current/voltage characteristic.

Description

Field effect controlled semiconductor device

description

The invention relates to a field-effect-controlled semiconductor component with at least four zones of alternately opposite conductivity types, in which an anode-side emitter zone, an adjoining first and second base zone, a cathode-side emitter zone and a further adjacent emitter zone are formed, the latter two emitter zones being source and drain a MOS field-effect transistor, with an anode contact, a contact on the cathode-side emitter zone and a control electrode contact of the MOS field-effect transistor.

A field effect controlled semiconductor device of the type described above is known from US Pat. No. 4,847,671. Such a semiconductor component, which is mentioned in the patent specification “Emitter Switched Thyristor” (EST), is illustrated in FIGS. 5 and 6 and is explained in more detail below. 5 and 6 in its structure, field-effect-controlled semiconductor component consists of an anode-side emitter zone 10, two adjoining base zones 20, 30 and two cathode-side emitter zones 40, 44. On an Iosier layer 50, which is a part of the Covered on the cathode-side base zone 30, there is a gate called control electrode contact 60, which forms a field effect transistor with the cathode-side emitters 40, 44 and a channel region 42, 43. The component is equipped with two power connections, a cathode 72 and an anode 74.

ERSAT76LATT Two thyristor structures can be seen in the described component. The first, parasitic thyristor structure consists of one cathode-side emitter zone 40, the two adjoining base zones 30, 20 and the anode-side emitter zone 10 and must not be ignited in any operating state. The second thyristor structure with the other cathode-side emitter structure 44, the two base zones 30, 20 adjoining it and the anode-side emitter zone 10 forms the main current path in the switched-on state.

The cathode-side emitter 40 is short-circuited with the cathode-side base zone 30 via the cathode contact 72. In order to make this shunt low-resistance, the base zone 30 is heavily doped in a partial area 32. The main thyristor structure 44, 30, 20, 10 is controlled by a field effect transistor 40, 50, 60, 44 and channel region 42, 43.

In the one embodiment of the known semiconductor component shown in FIG. 5, the doping in a weakly doped partial region 34 of the base zone 30 determines the threshold voltage of the field effect transistor and the injection efficiency of the cathode-side emitter 44. If the semiconductor component is polarized in the forward direction and the gate connection 60 of the latter Driven by field effect transistors with positive potential with respect to the cathode, a conductive channel 42 is formed in the p-base zone 34, which connects the two cathode-side emitters 40, 44 with low resistance.

At the same time, a conductive channel 46 is formed between the emitter 44 and the first base zone 20. The resulting electron current acts as a control current for a pnp transistor on the anode side and provides the starting or holding current for the main thyristor 44, 34, 20, 10. The hole punch flowing over the partial area 34 of the base zone 30 to the cathode contact 72 poles the n ⁺ emitter 44 in the forward direction and the injected electrons increase the conductance modulation of the weakly doped n base zone 20. The regenerative activation of the thyristor can be interrupted by daε Gate potential is equated to the cathode potential, so that the n-channel of the field effect transistor disappears and the electron current is interrupted. This process leads to the semiconductor component being switched off. The building structure according to 5 must be optimized very carefully, since the n ⁺ emitter of the parasitic thyristor structure 40, 30, 20, 10 is partially embedded in the same partial area 34 of the base zone 30 as the emitter 44, but is not poled in the forward direction in any operating state may be. This restriction increases the ignition current and limits the maximum switchable current of the component.

A more suitable, known embodiment is shown in FIG. 6. In the structure acc. FIG. 6 divides the cathode-side base region 34 from FIG. 5 into two subregions 34, 36, the subregions 34, 36 being separated by an n-doped region 22 of the first n base region 20.

The heavily doped portion 32 provides a median resistance

Shunt of the anode-side emitter 40. The other sub-region 34 defines the threshold voltage of the channel region 42, and the field effect transistor 40, 42, 22 supplies the ignition current for the main thyristor. The independently produced section 36 can be optimized with regard to the injection efficiency of the n ⁺ emitter 44 and the resistance of a shunt. This shunt of the emitter 44 is realized via an ohmic coupling of the partial area 36 to the cathode contact 72. The main thyristor structure 44, 36, 20, 10 is connected to the cathode 72 by a conductive channel 42, 22, 43 of the field effect transistor.

An equivalent circuit diagram of the semiconductor component acc. 6 is illustrated in FIG. 7. The separation of the partial areas 32, 36 facilitates the design of shorting resistors Ri and R2. The resistance Ri should be kept as low as possible, and the value of the resistance R2 must be optimized with regard to the switching properties of the component. In the optimization, however, a compromise between the forward voltage and the maximum switchable Strc must be accepted.

The invention is based on the problem of further developing a field-effect-controlled semiconductor component of the type described at the outset in such a way that the conduction behavior of a thyristor increases extended safe working area (SOA) is ensured.

According to the invention, the problem is solved in that the portion of the cathode-side base zone which adjoins the emitter zone one, the first and second base zone and the anode-side emitter zone and the main thyristor adjoining the cathode side base zone via a separate p ⁺ -doped region integrated component with a non-linear voltage / voltage characteristic is connected to the cathode contact

In this arrangement, as in the previously known solution, the main thyristor emitter is bound to the potential of the cathode by switching on the field effect transistor. The non-linear coupling of the base zone adjoining the main thyristor meter shows a high level

Resistance in the range of small current densities. This brings about a rapid increase in the potential of this area and a forward polarity of the main thyristor emitter, which leads to the regenerative control of the thyristor. When the field effect transistor is switched off, the electrical potential of the base region will exceed the loop voltage of the coupling element; the load flow flowing off via this path meets a low dynamic resistance on the way to the cathode contact.

In the case of transmission, the connection according to the invention of the partial regions of the cathode-side base zone near the emitter increases the transmission polarity of the thyristor emitter and improves the transmission behavior of the component. The low dynamic resistance of the base coupling at high current densities on the other hand makes it easier to switch off the component and expands the safe working range.

An expedient embodiment consists in an electrical connection of the emitter region of the cathode-side base zone to the cathode contact via a reverse-polarized, monolithically integrated zener diode or avalanche diode

A second embodiment uses the existing layer of polycrystalline silicon to produce a polarized in transmission Diode chain, which is then used as a coupling element with a non-linear current / voltage characteristic.

The invention is described in more detail below with reference to an exemplary embodiment shown in a drawing, from which further details, features and advantages result.

Show Eε

1 shows a structure of a field-effect-controlled semiconductor component in cross section;

2a shows a structure of another embodiment of a field effect-controlled semiconductor component in cross section; 2b shows a structure of a further embodiment of a field-effect-controlled semiconductor component with a cross section; 2c shows a structure of an additional embodiment of a field-effect-controlled semiconductor component in cross section; 3 shows an equivalent circuit diagram for the semiconductor component shown in FIG. 2; 4 shows a structure in cross section of a further embodiment of a field-effect-controlled semiconductor component;

5 shows a structure of a known field-effect-controlled semiconductor component with a cross section; 6 shows a structure of a further known field-effect-controlled semiconductor component with a cross section, and FIG. 7 shows an equivalent circuit diagram for the semiconductor component shown in FIG. 5.

1 schematically shows the structure of a field-effect-controlled semiconductor component with a strongly p-doped, anode-side emitter layer 10, with a first base zone 20, consisting of an n-doped zone, with a second base zone, which has a partial region 32 with strong p-doping and a partial region 34 with p-doping and a further partial region 36 with p-doping, and with strongly n-doped, cathode-side emitter zones 40, 44.

The semiconductor component is provided with an anode connection A of an anode contact 74, a cathode connection K, a cathode contact 72 and a gate connection G of a gate 60. Daε gate 60 is through an insulating layer 50 is separated from the base zones 20, 32, 34, 36 and the cathode-side emitter zones 40, 44. The subregions 34, 36 of the second base zone are separated from one another by an n-doped region 22 of the first base zone 20.

The semiconductor component contains a main thyristor structure with the emitter zone 44 on the bahode side, the first and second base zones 20, 30 and the emitter layer 10 on the anode side. This main thyristor structure is controlled by a field effect transistor which comprises the emitter zones 40, 44 on the cathode side, the insulating layer 50 and the gate 60.

The cathode contact 72 forms an ohmic contact both with the emitter zone 40 and also with the partial area 32 of the second base zone. The second base zone is divided into the partial areas 32, 34 and 36. As can be seen, in the semiconductor component of FIG. 1 there is broad agreement with the known semiconductor component shown in FIG. 6. The same elements have been given the same reference numerals in FIGS. 1 to 7.

In the semiconductor structure shown in FIG. 1, a strongly p-doped region 38, which is adjacent to the base region on the cathode side and adjoins the emitter zone 44 of the main thyristor, is connected to the cathode contact 72 via an integrated component with a nonlinear current / voltage characteristic.

In the εtark p-doped section 32 of the second base region, a εstarch n-doped region 48 is provided, that is via an ohmic contact and a metallic line, which is designed as a conductor track and, in contrast to the illustration according to FIG. 1 runs in the third dimension, connected to a contact 76 which adjoins the area 38. The pn junction between the n ^{+ region} 48 and the p ^{+ region} 32 acts like a zener diode which is polarized in the reverse direction and which is connected via the contacts 76, 78 and the metal conductor track in the third dimension to the sub-region 36, 38 of the base zone .

Subarea 38 was provided to improve the ohmic metal / semiconductor junction 76, 38, but can be left out, since a Schottky contact at this point does not affect the operation of the component was detected. The subsection 36 can therefore also be connected directly to the contact 78 by means of a contact and a metallic line.

However, it is also possible that in the structure shown in FIG. 5, the partial area 34 corresponds to the area 38 according to FIG. 1 is connected via a contact, a metallic conductor and a further contact to a heavily n-doped region in the partial area 32 and is thus connected to the cathode contact 72, which then does not extend over the entire partial area 32.

FIG. 2 shows an embodiment in which the partial region 36 adjoining the emitter 44 of the main thyristor is connected to the cathode contact 72 via a diode chain which is polarized in the forward direction.

The semiconductor component shown in FIG. 2a has in lateral form the heavily p-doped, anode-side emitter layer 10, the first base zone 20 with n-doping, the second base zone with the heavily p-doped portion 32, the p-doped portion 34 and the partial area 36 separated from these partial areas 32, 34 by an n-layer 22. The emitter zones 40, 44 and the strongly p-doped region 38 are also present. An anode connection A with the anode contact 74 and a cathode connection K with the cathode contact 72 are also present. A gate 60 is located on an insulating layer 50 which covers itself from the area 38, which partially covers it, over the partial area 36, the bitter zone 44, the n-layer 22 of the first basic zone 20 and the partial area 34 to form a strongly n-doped layer Area 40 extends that it is partially covered. The other part of the area 40 and the partial area 32 is covered by the cathode contact 72.

The diode chain which is polarized in the n forward direction is produced by an alternating p ⁺ - 61, 63 and an n ⁺ doping 62, 64 of a semiconductor layer made of polycrystalline silicon on an insulating layer and a corresponding metallization 82, 84, 86.

2, a particularly expedient embodiment of the invention was selected as a lateral component on an SOI substrate (Silicon On Inulator). In this case, the active semiconductor layer is from a carrier 5 separated by an insulator layer 55, preferably made of thermally grown silicon oxide. In this lateral embodiment of the component there is no path via a parasitic thyristor structure because the partial regions 34, 36 of the second base zone are separated by the n-doped partial region 22. One sub-area 36 reads upstream and shields the rest of the component. The ignition current can be supplied through a conductive channel of the field effect transistor in a modified part of the semiconductor component.

FIG. 2b shows an embodiment which differs from the embodiment in FIG. 2a only in that the p-base part 36 no longer completely envelops the emitter 44. This results in an even better decoupling between the base sub-areas 36 and 34, which leads to an improvement in the function of the main thyristor.

FIG. 2c shows an embodiment which differs from the embodiment in FIG. 2a only in that the p-base 30 is interrupted by the n ⁺ emitters 40 and 44 which pass through to the insulating layer 55. This leads to an ideal electrical decoupling of the sub-areas 36 and 34 and to an improvement in the function of the main thyristor.

The embodiments described above do not require any additional manufacturing steps and can be implemented in the normal process flow for manufacturing the EST component. 4 shows a third embodiment with a separately located p ^{+ region} .

The embodiment acc. 4 coincides with the position of the heavily p-doped region 38 with the embodiment shown in FIG. 2. The area 38 lies in the first base zone 20 or is separated from it by the partial area 36. As in the arrangement according to FIG. 2 is connected to a metallization 82, which is also connected to the n-doped layer 61 of the diode chain.

3 shows the replacement circuit diagram of the semiconductor components described above. In the replacement circuit diagram, the component with the non-linear current / voltage characteristic is identified by element D. The execution of D as a diode chain corresponds to FIG. 2; however, according to Fig. 1 a Zener diode are listed. It is obvious that this zener diode according to FIG. 2 could also be implemented using polysilicon technology.

All versions Correspondingly for complementary auεgeführte structures, where n and p-regions jeweilε in their Leitfähigkeitεtyp reversed are considered _'.

Claims

. Field-effect-controlled semiconductor component with at least four zones of alternately opposite conductivity types, in which an anode-side emitter zone, an adjoining first and second base zone, a cathode-side emitter zone and a further adjacent emitter zone are formed, the latter two emitter zones being the source and drain of a MOS field-effect transistor image, with an anode contact, a contact on the cathode-side emitter zone and a control electrode contact of the MOS field-effect transistor, characterized in that that portion (34, 36) of the cathode-side base zone that connects to an emitter zone (44) of one of these, the first and second base zones (20, 30) and the main thyristor comprising the anode-side emitter zone (10) are adjacent, or a separate, heavily p-doped region (38) adjacent to the cathode-side base zone via an integrated component (D) with non-linear current / Voltage characteristics to the cath oden contact (72) is connected.

2. Hal conductor component according to claim 1, characterized in that the component (D) is a Zenerd iode or avalanche diode operated in the reverse direction.

3. Semiconductor component according to claim 1, characterized in that the component (D) is a chain of diodes operated in the forward direction.

REPLACEMENT LEAF

4. Semiconductor component according to claim 2, characterized in that the zener or avalanche diode is formed by a heavily n-doped region (48) within the εtark p-doped region (32) of the cathode-side base zone.

5. Semiconductor component according to claim 1, 2 or 3, characterized in that that portion (36) of the cathode-side base zone which adjoins the emitter zone (44) of the main thyristor, or daε separate p-doped region (38) metallic with the beginning of one Insulated semiconductor layer are connected, the alternating ε strong p-and n-doped zones, and that the end of the semiconductor layer is metallically connected to the cathode contact (72).

6. Semiconductor component according to claim 5, characterized in that that partial region (36) of the cathode-side base region, which adjoins the emitter zone (44) of the main thyristor, only partially surrounds the emitter zone (44).

7. Semiconductor component according to claim 5, characterized in that εich the emitter zones (40, 44) extend to an insulating layer (55) and that between the emitter zones (40, 44) there is a p-doped subarea belonging to the base zone (30) .