JP6337725B2 - Semiconductor device - Google Patents

Description

  The present invention relates to a semiconductor device.

  In a metal oxide semiconductor field effect transistor (MOSFET) using silicon carbide, it is necessary to increase a gate threshold voltage in order to prevent malfunction due to noise. In addition, in order to reduce conduction loss, it is necessary to increase channel mobility. However, a high-density interface state is generated at the interface between the gate insulating film and the silicon carbide semiconductor layer in the MOS structure portion, and the channel mobility is significantly lowered as compared with the bulk mobility. In addition, channel mobility and gate threshold voltage have a trade-off relationship.

  In order to improve this trade-off, the gate threshold voltage is changed to 1 V with a difference in work function by changing the material of the gate electrode from the N-type polycrystalline silicon generally used conventionally to the P-type polycrystalline silicon. A technique for improving channel mobility by increasing the level and adjusting the type and concentration of impurities in the channel is known (see, for example, Patent Document 1).

JP 2011-146426 A

  However, when the gate electrode is made P-type, the gate resistance increases, so that there is a problem that the switching loss of the MOSFET increases.

  In view of the above problems, an object of the present invention is to provide a semiconductor device capable of increasing the gate threshold voltage and reducing the switching loss as in the case where the gate electrode is a P-type. .

According to one aspect of the present invention, the second conductivity type well region formed in the first conductivity type drift region, the first conductivity type source region formed in the well region, the source region and the well A gate insulating film in contact with the region, and a gate electrode formed so as to be in contact with the source region and the well region through the gate insulating film, the gate electrode having a first gate region and a second gate region, The gate region is made of a semiconductor material of the first conductivity type, at least part of the second gate region is in contact with the well region through the gate insulating film, and the carrier concentration of the first gate region is higher than the carrier concentration of the second gate region. A high semiconductor device is provided.

  According to the present invention, it is possible to provide a semiconductor device capable of increasing the gate threshold voltage and reducing the switching loss as in the case where the gate electrode is P-type.

It is sectional drawing which shows an example of the semiconductor device which concerns on the 1st Embodiment of this invention. FIG. 2 is a band diagram of the AA portion in FIG. 1 of the semiconductor device according to the first embodiment of the present invention. 4 is a graph showing the relationship between the gate-source voltage and the gate-source capacitance of the semiconductor device according to the first embodiment of the present invention. It is process sectional drawing which shows an example of the manufacturing method of the semiconductor device which concerns on the 1st Embodiment of this invention. FIG. 4B is a process cross-sectional view subsequent to FIG. 4A, illustrating an example of the semiconductor device manufacturing method according to the first exemplary embodiment of the present invention. FIG. 4D is a process cross-sectional view subsequent to FIG. 4B, illustrating an example of the method for manufacturing the semiconductor device according to the first embodiment of the present invention. FIG. 4D is a process cross-sectional view subsequent to FIG. 4C, illustrating an example of the method for manufacturing the semiconductor device according to the first embodiment of the present invention. FIG. 4D is a process cross-sectional view subsequent to FIG. 4D illustrating an example of the method for manufacturing the semiconductor device according to the first embodiment of the present invention. FIG. 4D is a process cross-sectional view subsequent to FIG. 4E illustrating an example of the method for manufacturing the semiconductor device according to the first embodiment of the present invention. It is sectional drawing which shows an example of the semiconductor device which concerns on the 1st modification of the 1st Embodiment of this invention. It is process sectional drawing which shows an example of the manufacturing method of the semiconductor device which concerns on the 2nd Embodiment of this invention. It is process sectional drawing which shows an example of the manufacturing method of the semiconductor device which concerns on the 2nd Embodiment of this invention. FIG. 7B is a process cross-sectional view subsequent to FIG. 7A, illustrating an example of a semiconductor device manufacturing method according to the second embodiment of the present invention. FIG. 7D is a process cross-sectional view subsequent to FIG. 7B, illustrating an example of a semiconductor device manufacturing method according to the second embodiment of the present invention. FIG. 7D is a process cross-sectional view subsequent to FIG. 7C, illustrating an example of a method for manufacturing a semiconductor device according to the second embodiment of the present invention. FIG. 7D is a process cross-sectional view subsequent to FIG. 7D, illustrating an example of a method for manufacturing a semiconductor device according to a second embodiment of the present invention. FIG. 7E is a process cross-sectional view subsequent to FIG. 7E, illustrating an example of a semiconductor device manufacturing method according to the second embodiment of the present invention. It is sectional drawing which shows an example of the semiconductor device which concerns on the 1st modification of the 2nd Embodiment of this invention. It is sectional drawing which shows an example of the semiconductor device which concerns on the 2nd modification of the 2nd Embodiment of this invention.

  The first and second embodiments will be described with reference to the drawings. In the description of the drawings, the same portions are denoted by the same reference numerals, and description thereof is omitted.

As shown in FIG. 1, the semiconductor device according to the first embodiment of the present invention includes a first conductive type (N ⁺ -type) semiconductor substrate (silicon carbide substrate) 1 and one main surface of the silicon carbide substrate 1. A first conductivity type (N-type) drift region 2 formed in the first region, a second conductivity type (P-type) well region 3 formed in the drift region 2, and a first region formed in the well region 3. A conductive type (N ⁺ -type) source region 4, a gate insulating film 7 in contact with the source region 4 and the well region 3, and a gate formed in contact with the source region 4 and the well region 3 through the gate insulating film 7. An electrode 8, an interlayer insulating film 9 covering the gate electrode 8, a source electrode 13 electrically connected to the well region 3 and the source region 4, and a drain electrode 12 electrically connected to the drift region 2 Prepare.

N type drift region 2 is, for example, a silicon carbide epitaxial growth layer. The impurity concentration of drift region 2 is lower than the impurity concentration of N ⁺ -type silicon carbide substrate 1 and is about 1 × 10 ¹⁴ to 1 × 10 ¹⁸ cm ⁻³ . On the main surface side of the drift region 2, a P-type well region 3 and an N ⁺ -type source region 4 are formed. The impurity concentration of the well region 3 is about 1 × 10 ¹⁷ cm ⁻³ . The impurity concentration of the source region 4 is about 1 × 10 ²⁰ cm ⁻³ .

  A gate insulating film 7 is formed on the surface of silicon carbide substrate 1 so as to be in contact with drift region 2, well region 3 and source region 4. A gate electrode 8 is formed in contact with the drift region 2, the well region 3 and the source region 4 through the gate insulating film 7.

The gate electrode 8 has a first gate region 81 and a second gate region 82. The first gate region 81 is electrically connected to the second gate region 82. The first gate region 81 is in contact with the drift region 2 and the source region 4 through the gate insulating film 7. The second gate region 82 is in contact with the well region 3 through the gate insulating film 7. The carrier concentration of the second gate region 82 is lower than the carrier concentration of the first gate region 81. For example, the second gate region 82 is made of a semiconductor material having an impurity concentration lower than that of the first gate region 81. In the first embodiment of the present invention, the first gate region 81 is made of N ⁺ type polycrystalline silicon having an impurity concentration of 1 × 10 ²⁰ cm ⁻³ , and the second gate region 82 is an impurity concentration of 1 × 10 ¹⁶ cm ^−3. N ^- type polycrystalline silicon.

The source electrode 13 is in contact with the gate electrode 8 through the interlayer insulating film 9 and is electrically connected to the source region 4 in an ohmic manner with a low resistance. The source electrode 13 is also in contact with the well region 3. The source region 4 and the well region 3 take the same potential via the source electrode 13. If necessary, the source electrode 13 may be in contact with the well region 3 through a high-concentration P-type semiconductor region (not shown) in order to improve conductivity. A drain electrode 12 is electrically ohmically connected to the back surface of the N ⁺ type silicon carbide substrate 1 with low resistance.

  Next, an example of a basic operation of the semiconductor device according to the first embodiment of the present invention will be described.

  As for the on / off operation of the semiconductor device shown in FIG. 1, the potential of the gate electrode 8 is controlled with a predetermined positive potential applied to the drain electrode 12 with the potential of the source electrode 13 as a reference. Function. That is, when the voltage between the gate electrode 8 and the source electrode 13 is set to a predetermined gate threshold voltage or more, an inversion layer is formed in the channel portion of the P-type well region 3 on the side surface of the gate electrode 8, so A current flows to the source electrode 13. On the other hand, when the voltage between the gate electrode 8 and the source electrode 13 is set to a predetermined gate threshold voltage or less, the inversion layer disappears and is turned off, thereby interrupting the current. At this time, a high voltage is instantaneously applied between the drain and the source. As a result, a depletion layer is formed in the drift region 2.

FIG. 2 shows the simulation result of the band diagram at the channel interface indicated by the AA line in FIG. 1 when the gate-source voltage is 0V. In FIG. 2, Ec is a conductor level, Ef is a Fermi level, and Ev is a valence band level. As shown in FIG. 2, P-type silicon carbide well region 3, N ⁺ -type polycrystalline silicon of the first gate region 81, N of the second gate region 82 ^- -type polycrystalline impurity level of silicon required to be the same There is. Therefore, the band is bent at the interface between the gate insulating film 7 and the second gate region 81, and the impurity level of the second gate region 82 is arranged close to the valence band. For this reason, the second gate region 81 in the vicinity of the interface of the gate insulating film 7 can be regarded as P-type, and the gate threshold voltage is 1 V higher than that of the N-type gate electrode.

Further, compared with the gate electrode of complete P ⁺ type polycrystalline silicon described in Patent Document 1, the first gate region 81 is made of N ⁺ type polycrystalline silicon, and the gate resistance is reduced, so that the switching loss is reduced. it can. In addition, a depletion layer spreads in the N ⁻ -type second gate region 82 due to the band bending. For this reason, the capacity | capacitance between gate sources can be reduced.

FIG. 3 is a simulation result of the relationship between the gate-source voltage and the gate-source capacitance. A solid line in FIG. 3 shows the semiconductor device according to the first embodiment of the present invention, in which the first gate region 81 is made of N ⁻ type polycrystalline silicon and the second gate region 82 is made of N ⁺ type polycrystalline silicon. Is. On the other hand, the broken line in FIG. 3 is a comparative example, and is a conventional complete N-type polycrystalline silicon gate MOSFET in which both the first gate region and the second gate region are made of N ⁻ type polycrystalline silicon. FIG. 3 shows that the gate-source capacitance of the present invention is lower than that of the comparative example. In addition, the gate-source capacitance is reduced (not shown) on the same principle as compared with a full P-type polycrystalline silicon gate MOSFET.

In the first embodiment of the present invention, the impurity concentration of the well region 3 is 1 × 10 ¹⁷ cm ^−3, and the impurity concentration of the second gate region 82 is 1 × 10 ¹⁶ lower than the impurity concentration of the well region 3. Although it is cm ⁻³ , the band bending of the gate insulating film 7 and the second gate region 82 changes depending on these two concentration relationships. In particular, the amount of bending is ultimately determined by the impurity levels of the first gate region 81 and the well region 3.

  As can be seen from the band diagram of FIG. 2, the bending of the band is composed of a bending occurring between the well region 3 and the gate insulating film 7 and a bending occurring between the gate insulating film 7 and the second gate region 82. When the impurity concentration of the second gate region 82 is lower than the impurity concentration of the well region 3, the band bending of the gate insulating film 7 and the second gate region 82 is large, and the band bending of the well region 3 and the gate insulating film 7 side is small. Become. Conversely, when the impurity concentration of the second gate region 82 is higher than the impurity concentration of the well region 3, the band bending between the gate insulating film 7 and the second gate region 82 is small, and the band on the well region 3 and the gate insulating film 7 side. Bending increases.

  The gate-source capacitance is a direct capacitance between the capacitance of the gate insulating film 7 and the depletion layer capacitance of the second gate region 82. When the depletion layer is large, the gate-source capacitance is small. If the band bending between the gate insulating film 7 and the second gate region 82 is large, the depletion layer of the second gate region 82 is wide and the capacitance is small. That is, when the impurity concentration of the second gate region 82 is equal to or lower than the impurity concentration of the well region 3, the band bending between the gate insulating film 7 and the second gate region 82 is large. Can be reduced.

  As described above, according to the semiconductor device of the first embodiment of the present invention, the second gate region 82 of the gate electrode 8 is made of a semiconductor material having a carrier concentration (impurity concentration) lower than that of the first gate region 81. And in contact with the well region 3 through the gate insulating film 7. The gate threshold voltage of the MOSFET is affected by the flat band voltage between the well region 3 and the gate electrode 8. The flat band voltage is determined by the band bending between the well region 3 and the gate electrode 8. In the thermal equilibrium state, the impurity levels of the well region 3 and the first gate region 81 are at the same level. Therefore, the band of the second gate region 82 between the well region 3 and the first gate region 81 is bent accordingly. Therefore, regardless of the conductivity type of the second gate region 82, the impurity level is the same as that of the well region 3 in the vicinity of the interface of the gate insulating film 7. As a result, the flat band voltage is small. Inversion of the well region 3 requires a higher gate-source voltage than a conventional gate having a high impurity concentration. For this reason, the gate threshold can be increased.

  Further, since the impurity level of the second gate region 82 near the interface of the gate insulating film 7 is aligned with the impurity level of the well region 3, the band of the second gate region 82 is bent, and the depletion layer is formed in the second gate region 82. Spread. For this reason, the capacity | capacitance between gate sources can be reduced and a switching loss can be reduced. Therefore, a semiconductor device with a high gate threshold and a small switching loss can be provided.

  Further, since the first gate region 81 is made of the first conductive type (N type) semiconductor material, the impurity levels of the second conductive type (P type) well region 3 and the first gate region 81 need to be aligned. . In the second gate region 82 sandwiched between the first gate region 81 and the well region 3, the vicinity of the gate insulating film 7 has the same impurity level as the well region 3. The vicinity of the first gate region 81 is an impurity level of the first gate region 81. Therefore, when the first gate region 81 and the well region 3 have different conductivity types, the band bending of the second gate region 82 is large. Therefore, the second gate region 82 has a large depletion layer, a small gate-source capacitance, and a low switching loss semiconductor device can be provided.

  Further, by making the second gate region 82 the first conductivity type (N type), the impurity level of the second gate region 82 is the same as the impurity level of the well region 3 when the gate-source voltage is 0V. Because it must be, the band is bent and the depletion layer is widened. Therefore, even when the gate-source voltage is low, the gate-source capacitance is smaller than when the second gate region 82 is of the second conductivity type (P type), and a semiconductor device with low switching loss can be provided.

  In addition, by setting the impurity concentration of the second gate region 82 to be equal to or less than the impurity concentration of the well region 3, the depletion layer spreads more greatly in the second gate region 82 when the gate-source voltage is 0V. For this reason, a lower gate-source capacitance or a gate-drain capacitance can be realized, and a semiconductor device with lower switching loss can be provided.

  Next, an example of a method for manufacturing the semiconductor device according to the first embodiment of the present invention will be described with reference to FIGS.

First, as shown in FIG. 4A, a drift region 2 made of an N ⁻ type silicon carbide epitaxial layer is formed on an N ⁺ type silicon carbide substrate 1. There are several polytypes (crystal polymorphs) in silicon carbide, but here it will be described as representative 4H. N ⁺ type silicon carbide substrate 1 has a thickness of about several tens to several hundreds of μm. The N ⁻ type drift region 2 is formed, for example, with an impurity concentration of 1 × 10 ¹⁴ to 1 × 10 ¹⁸ cm ⁻³ and a thickness of several μm to several tens of μm.

Next, as shown in FIG. 4B, a P-type well region 3 and an N ⁺ -type source region 4 are formed in the drift region 2 by ion implantation. Specifically, in order to pattern the ion implantation region, a mask material such as a silicon oxide film may be formed on the drift region 2 by using a thermal chemical vapor deposition (thermal CVD) method or a plasma CVD method. Good. Next, a resist is patterned on the mask material using a general photolithography method or the like (not shown). The mask material is etched using the patterned resist as a mask. As an etching method, wet etching using hydrofluoric acid or dry etching such as reactive ion etching can be used. Next, the resist is removed with oxygen plasma or sulfuric acid.

P-type and N-type impurities are ion-implanted using the mask material as a mask to form a P-type well region 3 and an N ⁺ -type source region 4. Aluminum (Al) or boron (B) can be used as the P-type impurity, and nitrogen (N) can be used as the N-type impurity. At this time, by performing ion implantation while the substrate temperature is heated to about 600 ° C., it is possible to suppress the occurrence of crystal defects in the implanted region. After the ion implantation, the mask material is removed by wet etching using, for example, hydrofluoric acid. Next, the ion-implanted impurity is activated by heat treatment. A temperature of about 1700 ° C. can be used as the heat treatment temperature, and argon or nitrogen can be suitably used as the atmosphere. For example, it is preferable that the impurity concentration of the well region 3 is 1 × 10 ¹⁷ cm ⁻³ and the impurity concentration of the source region 4 is 1 × 10 ²⁰ cm ⁻³ .

Next, as shown in FIG. 4C, the gate insulating film 7 is formed on the drift region 2. In this step, a thermal oxidation method or a deposition method may be used. For example, in the case of thermal oxidation, by heating the substrate in an oxygen atmosphere at a temperature of about 1100 ° C., a silicon oxide film is formed in all portions where the substrate is exposed to oxygen. The thickness of the gate insulating film 7 is preferably several tens of nm. After the gate insulating film 7 is formed, annealing at about 1000 ° C. may be performed in an atmosphere of nitrogen, argon, N ₂ O or the like in order to reduce the interface state between the P-type well region 3 and the gate insulating film 7 interface. Good.

Next, a gate electrode 8 is formed on the gate insulating film 7. First, as shown in FIG. 4D, a second gate region 82 is formed on the gate insulating film 7 so as to be in contact with the well region 3 through the gate insulating film 7. Here, as an example, the second gate region 82 is formed of N ⁻ type polycrystalline silicon. Low pressure CVD may be used as the polycrystalline silicon deposition method. By introducing PCl ₃ gas during deposition, the polycrystalline silicon can be made N-type. Further, the impurity concentration of the polycrystal can be controlled by the flow rate ratio of PCl ₃ , and 1 × 10 ¹⁶ cm ⁻³ is preferable here. Next, a resist is applied on the N ⁻ -type polycrystalline silicon, and the resist is patterned using a general photolithography method (not shown). Using the patterned resist as a mask, the N ⁻ -type polycrystalline silicon is etched using dry etching such as reactive ion etching.

Next, as shown in FIG. 4E, a first gate region 81 is formed on the gate insulating film 7 so as to cover the second gate region 82. The first gate region 81 can be formed by the same method as the second gate region 82. For example, the first gate region 81 is preferably made of N ⁺ polycrystalline silicon and has an impurity concentration of 1 × 10 ²⁰ cm ⁻³ . As a result, the gate electrode 8 having the first gate region 81 and the second gate region 82 is formed.

  Next, an interlayer insulating film 9 is formed so as to cover the gate electrode 8. A silicon oxide film can be used as the interlayer insulating film 9, and a thermal CVD method or a plasma CVD method can be used as a deposition method. After the interlayer insulating film 9 is deposited, a resist is patterned on the interlayer insulating film 9 by using a general photolithography method or the like (not shown). The mask material is etched using the patterned resist as a mask. As an etching method, wet etching using hydrofluoric acid or dry etching such as reactive ion etching can be used. In this etching, the interlayer insulating film 9 and the gate insulating film 7 exposed on the substrate surface are simultaneously removed. The cross-sectional structure after removal is shown in FIG. 4F.

Next, the source electrode 13 and the drain electrode 12 are formed. The source electrode 13 is formed so as to be in ohmic contact with the P-type well region 3 and the N ⁺ -type source region 4 with low electrical resistance. Although nickel silicide (NiSi) is preferably used as the source electrode 13, a metal such as cobalt silicide (CoSi) or titanium silicide (TiSi) may be used. As a deposition method, an evaporation method, a sputtering method, a CVD method, or the like can be used. Further, a laminated structure in which titanium or aluminum is laminated on the source electrode 13 may be employed.

In addition, drain electrode 12 is formed on the back surface of N ⁺ type silicon carbide substrate 1. For example, similarly to the source electrode 13, nickel is deposited on the back surface of the N ⁺ type silicon carbide substrate 1. Next, annealing is performed at about 1000 ° C. to alloy silicon carbide (SiC) and nickel (Ni) to form nickel silicide (NiSi), and the source electrode 13 and the drain electrode 12 are formed. Through the above steps, the semiconductor device according to the first embodiment of the present invention shown in FIG. 1 is completed.

(First modification)
As shown in FIG. 5, the semiconductor device according to the first modification of the first embodiment of the present invention is that the second gate region 82 is in contact with the drift region 2 through the gate insulating film 7. 1 is different from the semiconductor device shown in FIG. Other configurations of the semiconductor device according to the first modification are the same as those in the first embodiment.

  The operation of the semiconductor device according to the first modification is the same as that of the first embodiment. The manufacturing method of the semiconductor device according to the first modification is the same as that of the first embodiment except that the resist mask pattern at the time of etching the second gate region 82 is changed.

  According to the first modification, it is possible to reduce the gate-drain capacitance while having the same effect as the first embodiment. Specifically, the drift region 2, the gate insulating film 7, and the second gate region 82 constitute a MOS capacitor when the drift region 2 in contact with the gate insulating film 7 has the same potential as the source electrode 13. For this reason, by applying a positive voltage between the gate and the source, a depletion layer spreads in the second gate region 82 and the capacitance between the gate and drain is reduced. Therefore, a semiconductor device with low switching loss can be provided.

(Second modification)
In the second modification of the first embodiment of the present invention, a case where a metal or an alloy of a metal and a semiconductor is used instead of using a semiconductor material as the first gate region 81 will be described. For example, a material such as titanium (Ti), aluminum (Al), or platinum (Pt) can be applied as the metal. As an alloy of a metal and a semiconductor, a material such as tungsten silicide (WSi) or titanium silicide (TiSi) can be applied. Here, as an example, Pt having a large work function is applied to the first gate region 81. Other configurations of the semiconductor device according to the second modification are the same as those in the first embodiment.

  The operation method of the semiconductor device according to the second modification is the same as that of the first embodiment. In the method for manufacturing a semiconductor device according to the second modification, after the second gate region 82 is formed, a metal film or an alloy film of a metal and a semiconductor is deposited in the step of forming the first gate region 81. As a deposition method, a method such as sputtering or MOCVD can be applied. Other steps of the semiconductor device manufacturing method according to the second modification are the same as those in the first embodiment.

  According to the second modification, in addition to the same effects as those of the first embodiment, the resistance of the gate electrode 8 can be further reduced by forming the first gate region 81 from a metal or an alloy. Thus, a semiconductor device with low switching loss can be provided.

  Further, since the work function of the first gate region 81 is larger than the work function of the second gate region 82, the band bending of the second gate region 82 can be increased. For this reason, a depletion layer of the second gate region 82 is formed, a gate-source capacitance is small, and a semiconductor device with low switching loss can be provided.

(Second Embodiment)
As shown in FIG. 6, the semiconductor device according to the second embodiment of the present invention includes a first conductivity type (N ⁺ type) semiconductor substrate (silicon carbide substrate) 1 and one main surface of the silicon carbide substrate 1. A first conductivity type (N-type) drift region 2 formed in the first region, a second conductivity type (P-type) well region 3 formed in the drift region 2, and a first region formed in the well region 3. A conductive type (N ⁺ -type) source region 4, a gate insulating film 7 in contact with the source region 4 and the well region 3, and a gate formed in contact with the source region 4 and the well region 3 through the gate insulating film 7. An electrode 8, an interlayer insulating film 9 covering the gate electrode 8, a source electrode 13 electrically connected to the well region 3 and the source region 4, and a drain electrode 12 electrically connected to the drift region 2 Prepare.

An N-type low concentration drift region 2 made of silicon carbide is formed on the surface of an N-type high concentration N ⁺ type silicon carbide substrate 1. A P-type well region 3 and an N ⁺ -type source region 4 are formed on the main surface side of the drift region 2. Further, a trench 5 is formed so as to penetrate the P-type well region 3 and the N ⁺ -type source region 4 and reach the drift region 2. A gate insulating film 7 is formed on the side and bottom of the trench 5 so as to be in contact with the drift region 2, the P-type well region 3 and the N ⁺ -type source region 4. A gate electrode 8 is formed on the side surface and bottom of the trench 5 with the gate insulating film 7 interposed therebetween.

  The gate electrode 8 has a first gate region 81 and a second gate region 82. The second gate region 82 is in contact with the drift region 2, the well region 3, and the source region 4 through the gate insulating film 7. The first gate region 81 is electrically connected to the second gate region 82. The first gate region 81 is in contact with the well region 3 through the gate insulating film 7.

Source electrode 13 is in contact with gate electrode 8 through interlayer insulating film 9. The source electrode 13 is ohmically connected to the source region 4 with low resistance. The source electrode 13 is also in contact with the well region 3. The source region 4 and the well region 3 take the same potential via the source electrode 13. A drain electrode 12 is electrically ohmically connected to the back surface of the N ⁺ type silicon carbide substrate 1 with low resistance.

  Other configurations of the semiconductor device according to the second embodiment of the present invention are the same as those of the first embodiment. The operation of the semiconductor device according to the second embodiment of the present invention is the same as that of the first embodiment.

  According to the second embodiment of the present invention, the second gate region 82 of the gate electrode 8 is made of a semiconductor material having a lower concentration than the first gate region 81 and is in contact with the well region 3 through the gate insulating film 7. Yes. The gate threshold voltage of the MOSFET is affected by the flat band voltage between the well region 3 and the gate electrode 8. The flat band voltage is determined by the band bending between the well region 3 and the gate electrode 8. In the thermal equilibrium state, the impurity levels of the well region 3 and the first gate region 81 are at the same level. Therefore, the band of the second gate region 82 between the well region 3 and the first gate region 81 is bent accordingly. Therefore, regardless of the conductivity type of the second gate region 82, the impurity level is the same as that of the well region 3 in the vicinity of the interface of the gate insulating film 7. As a result, the flat band voltage is small. Inversion of the well region 3 requires a higher gate-source voltage than a conventional gate having a high impurity concentration. For this reason, the gate threshold can be increased.

  Further, since the impurity level of the second gate region 82 near the interface of the gate insulating film 7 is aligned with the impurity level of the well region 3, the band of the second gate region 82 is bent, and the depletion layer is formed in the second gate region 82. Spread. For this reason, the capacity | capacitance between gate sources can be reduced and a switching loss can be reduced. Therefore, a semiconductor device with a high gate threshold and a small switching loss can be provided.

  Further, the gate electrode 8 is in contact with the well region 3 on the side wall of the groove 5 through the gate insulating film 7, so that the channel can be formed on the side wall of the groove 5. Therefore, the semiconductor element can be reduced in size.

  Further, since the first gate region 81 is made of the first conductive type (N type) semiconductor material, the impurity levels of the second conductive type (P type) well region 3 and the first gate region 81 need to be aligned. . In the second gate region 82 sandwiched between the first gate region 81 and the well region 3, the vicinity of the gate insulating film 7 has the same impurity level as the well region 3. The vicinity of the first gate region 81 is an impurity level of the first gate region 81. Therefore, when the first gate region 81 and the well region 3 have different conductivity types, the band bending of the second gate region 82 is large. Therefore, the second gate region 82 has a large depletion layer, a small gate-source capacitance, and a low switching loss semiconductor device can be provided.

  Further, by making the second gate region 82 the first conductivity type (N type), the impurity level of the second gate region 82 is the same as the impurity level of the well region 3 when the gate-source voltage is 0V. Because it must be, the band is bent and the depletion layer is widened. Therefore, even when the gate-source voltage is low, the gate-source capacitance is smaller than when the second gate region 82 is of the second conductivity type (P type), and a semiconductor device with low switching loss can be provided.

  In addition, by setting the impurity concentration of the second gate region 82 to be equal to or less than the impurity concentration of the well region 3, the depletion layer spreads more greatly in the second gate region 82 when the gate-source voltage is 0V. For this reason, a lower gate-source capacitance or a gate-drain capacitance can be realized, and a semiconductor device with lower switching loss can be provided.

  Next, an example of a method for manufacturing a semiconductor device according to the second embodiment of the present invention will be described with reference to FIGS. 4A and 7A to 7F.

First, as shown in FIG. 4A, a drift region 2 made of an N ⁻ type silicon carbide epitaxial layer is formed on an N ⁺ type silicon carbide substrate 1. There are several polytypes (crystal polymorphs) in silicon carbide, but here it will be described as representative 4H. N ⁺ type silicon carbide substrate 1 has a thickness of about several tens to several hundreds of μm. The N ⁻ type drift region 2 is formed, for example, with an impurity concentration of 1 × 10 ¹⁴ to 1 × 10 ¹⁸ cm ⁻³ and a thickness of several μm to several tens of μm.

Next, a P-type well region 3 and an N ⁺ -type source region 4 are formed in the drift region 2 by ion implantation. In order to pattern the ion implantation region, a mask material may be formed on the drift region 2 by the following process. A silicon oxide film can be used as the mask material, and a thermal CVD method or a plasma CVD method can be used as the deposition method. Next, a resist is patterned on the mask material (not shown). As a patterning method, a general photolithography method can be used. The mask material is etched using the patterned resist as a mask. As an etching method, wet etching using hydrofluoric acid or dry etching such as reactive ion etching can be used. Next, the resist is removed with oxygen plasma or sulfuric acid.

P-type and N-type impurities are ion-implanted using the mask material as a mask to form a P-type well region 3 and an N ⁺ -type source region 4. Aluminum or boron can be used as the P-type impurity. Nitrogen can be used as the N-type impurity. At this time, by performing ion implantation while the substrate temperature is heated to about 600 ° C., it is possible to suppress the occurrence of crystal defects in the implanted region. After the ion implantation, the mask material is removed by wet etching using, for example, hydrofluoric acid. Next, the ion-implanted impurity is activated by heat treatment. A temperature of about 1700 ° C. can be used as the heat treatment temperature, and argon or nitrogen can be suitably used as the atmosphere. The cross-sectional structure after completion of this process is shown in FIG. 7A.

Next, as shown in FIG. 7B, a groove 5 is formed in the drift region 2. First, a mask material 14 is formed on the N ⁺ type source region 4. As the mask material 14, a patterned insulating film can be used as in the process of FIG. 7A. Next, the groove 5 is formed using the mask material 14 as a mask. As a method of forming the groove 5, a dry etching method is preferably used. The depth of the groove 5 needs to be deeper than the depth of the P-type well region 3. After the groove 5 is formed, the mask material 14 is removed. For example, when the mask material 14 is a silicon oxide film, wet etching with hydrofluoric acid is suitable.

Next, as shown in FIG. 7C, the gate insulating film 7 is formed so as to cover the top surface of the drift region 2 and the side surfaces and bottom of the trench 5. In this step, a thermal oxidation method or a deposition method may be used. As an example, in the case of thermal oxidation, a silicon oxide film is formed in all portions where the substrate contacts oxygen by heating the substrate in an oxygen atmosphere to a temperature of about 1100 ° C. After the gate insulating film 7 is formed, annealing at about 1000 ° C. may be performed in an atmosphere of nitrogen, argon, N ₂ O or the like in order to reduce the interface state between the P-type well region 3 and the gate insulating film 7 interface. Good. The thickness of the gate insulating film 7 is preferably several tens of nm.

Next, the gate electrode 8 is formed so as to be embedded in the trench 5. First, the second gate region 82 is formed. Here, as an example, the second gate region 82 is formed of N ⁻ type polycrystalline silicon. Low pressure CVD may be used as the polycrystalline silicon deposition method. By introducing PCl ₃ gas during deposition, the polycrystalline silicon can be made N-type. Further, the impurity concentration of the polycrystal can be controlled by the flow rate ratio of PCl ₃ , and 1 × 10 ¹⁶ cm ⁻³ is preferable here. The film thickness needs to be a thickness that does not fill the grooves 5. Next, the N ⁻ type polycrystalline silicon is etched. As an etching method, dry etching such as reactive ion etching can be used. A cross-sectional view of the etching is shown in FIG. 7D.

Next, the first gate region 81 is formed. The first gate region 81 can be formed by the same method as the second gate region 82. For example, the first gate region 81 is preferably N ⁺ polycrystalline silicon, and the impurity concentration is preferably 1 × 10 ²⁰ cm ⁻³ . The polycrystalline silicon in the first gate region 81 is etched. As an etching method, selective etching using a mask material is preferable. A resistor is suitable for the mask material. As an example, this etching process exposes the well region 3 so that the subsequent source electrode 13 can be contacted by the side wall of the source region 4. The cross-sectional structure after etching the gate electrode 8 is shown in FIG. 7E.

  Next, an interlayer insulating film 9 is formed so as to cover the gate electrode 8. A silicon oxide film can be used as the interlayer insulating film 9, and a thermal CVD method or a plasma CVD method can be used as a deposition method. After deposition, a resist is patterned on the interlayer insulating film 9 (not shown). As a patterning method, a general photolithography method can be used. The mask material is etched using the patterned resist as a mask. As an etching method, wet etching using hydrofluoric acid or dry etching such as reactive ion etching can be used. In this etching, it is preferable to perform the etching until the interlayer insulating film 9 and the gate insulating film 7 on the substrate surface are removed, and further, the well region 3 is exposed. The cross-sectional structure after removal is shown in FIG. 7F.

Next, the source electrode 13 and the drain electrode 12 are formed. Specifically, the source electrode 13 is formed so as to be in ohmic contact with the P-type well region 3 and the N ⁺ -type source region 4 with low resistance. As the source electrode 13, nickel silicide (NiSi) is preferably used. Metals such as cobalt silicide (CoSi) and titanium silicide (TiSi) may be used. As a deposition method, an evaporation method, a sputtering method, a CVD method, or the like can be used. Furthermore, a stacked structure in which titanium (Ti) or aluminum (Al) is stacked on the source electrode 13 may be employed. Next, nickel (Ni) is similarly deposited on the back surface of the N ⁺ type silicon carbide substrate 1. Next, annealing is performed at about 1000 ° C. to alloy silicon carbide (SiC) and nickel to form nickel silicide (Ni), and the source electrode 13 and the drain electrode 12 are formed. As a result, the semiconductor device shown in FIG. 6 is completed.

  According to the method for manufacturing a semiconductor device according to the second embodiment of the present invention, the second gate region 82 can be formed without using a mask. Therefore, mask misalignment does not occur, and a highly reliable semiconductor device can be provided.

(First modification)
In the second embodiment of the present invention, the case where the second gate region 82 is in contact with the entire side wall of the trench 5 has been described as shown in FIG. As a first modification of the second embodiment of the present invention, as shown in FIG. 8, the point that the second gate region 82 is in contact with a part of the side surface of the trench 5 is different from the second embodiment. Different. The second gate region 82 may be formed on the side wall of the trench 5 so as to face at least the well region 3, and has the same effect as that of the second embodiment. Although not shown, even if the second gate region 82 is formed so as to face both the well region 3 and the source region 4, the same effect as in the second embodiment can be obtained.

(Second modification)
As shown in FIG. 9, the semiconductor device according to the second modification of the second embodiment is such that the second gate region 82 is in contact with the drift region 2 at the bottom of the trench 5 through the gate insulating film 7. Different from the semiconductor device shown in FIG.

  The operation method of the semiconductor device according to the second modification is the same as that of the second embodiment. Further, in the method of manufacturing a semiconductor device according to the second modification, after depositing the polycrystalline silicon in the second gate region 82, the polycrystalline silicon in the first gate region 81 is deposited on the surface without being removed. In the subsequent etching, the first gate region 81 and the second gate region 82 outside the trench 5 are simultaneously removed.

  According to the second modification, the same effect as that of the second embodiment can be obtained, and the gate-drain capacitance can be reduced at the bottom of the trench 5 as compared with the second embodiment. A semiconductor device can be provided.

(Other embodiments)
As described above, the first and second embodiments of the present invention have been described. However, it should not be understood that the description and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  For example, in the first and second embodiments, the case where the semiconductor device is manufactured on the silicon carbide substrate 1 has been described. However, the present invention is not particularly limited to the silicon carbide substrate 1 and is on a semiconductor substrate made of a semiconductor material having a wide band gap. A semiconductor device may be manufactured. Examples of the semiconductor material having a wide band gap include gallium nitride (GaN), diamond, zinc oxide (ZnO), and gallium aluminum nitride (AlGaN).

  Further, although N-type polysilicon has been described as the gate electrode 8, it may be P-type polysilicon. The gate electrode 8 may be another semiconductor material or another conductive material such as a metal material. For example, P-type polysilicon carbide, silicon germanium (SiGe), aluminum (Al), and the like can be given.

  Further, although the silicon oxide film has been described as the gate insulating film 7, it may be a silicon nitride film or a laminated structure of a silicon oxide film and a silicon nitride film. When the gate insulating film 7 is a silicon nitride film and isotropic etching is performed, the etching can be performed by cleaning with 160 ° C. hot phosphoric acid.

1 ... Semiconductor substrate (silicon carbide substrate)
2 ... Drift region 3 ... Well region 4 ... Source region 5 ... Groove 7 ... Gate insulating film 8 ... Gate electrode 9 ... Interlayer insulating film 12 ... Drain electrode 13 ... Source electrode 14 ... Mask material 81 ... First gate region 82 ... First 2 gate area

Claims (7)

A semiconductor substrate;
A drift region of a first conductivity type formed on one main surface of the semiconductor substrate;
A second conductivity type well region formed in the drift region;
A first conductivity type source region formed in the well region;
A gate insulating film in contact with the source region and the well region;
A gate electrode formed so as to be in contact with the source region and the well region via the gate insulating film;
An interlayer insulating film covering the gate electrode;
A source electrode electrically connected to the well region and the source region;
A drain electrode electrically connected to the drift region,
The gate electrode has a first gate region and a second gate region;
The second gate region is made of a semiconductor material of a first conductivity type ,
At least a portion of the second gate region is in contact with the well region via the gate insulating film;
A semiconductor device, wherein a carrier concentration in the first gate region is higher than a carrier concentration in the second gate region. A groove having a depth reaching the drift region through the source region and the well region;
The semiconductor device according to claim 1, wherein the gate electrode is in contact with the source region and the well region via the gate insulating film on a side surface of the trench.   The semiconductor device according to claim 1, wherein the first gate region is made of a semiconductor material of a first conductivity type.   The semiconductor device according to claim 1, wherein the first gate region is made of a metal or an alloy of a metal and a semiconductor.   The semiconductor device according to claim 4, wherein a work function of the first gate region is larger than a work function of the second gate region. The semiconductor device according to claim 1 , wherein the second gate region is in contact with the drift region through the gate insulating film. The impurity concentration in the second gate region, the semiconductor device according to claim 1, wherein the or less impurity concentration of the well region.

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