JP2013042054A - Semiconductor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a termination structure capable of maintaining stable withstanding voltage even when a high electrical field is applied to a passivation film on a substrate principal surface in a semiconductor device having a power device on the semiconductor substrate containing a silicon carbide.SOLUTION: A semiconductor device comprises a passivation film 6 on a p-type impurity region forming a termination structure of an SiC power device, which has a lamination structure including a first silicon oxide film 6a contacting an SiC, a metal insulation film 6b on the first silicon oxide film 6a and a second silicon oxide film 6c on the metal insulation film 6b. The film thickness of the metal insulation film 6b is 0.3 nm or more to 10 nm or less. Accordingly, effective charge of the passivation film 6 is made negative.

Description

  The present invention relates to a semiconductor device, and more particularly to a technique effective when applied to a semiconductor device formed on a substrate containing silicon carbide.

  Semiconductor devices using silicon carbide (SiC), a new material that replaces conventional silicon (Si), have been studied for the purpose of reducing the loss of power devices that require high withstand voltage and through which large current flows. . SiC has a dielectric breakdown electric field about 10 times larger than that of Si, so that the drift layer that maintains the withstand voltage can be made thin and highly concentrated, and the conduction loss can be reduced. For this reason, it is expected to be applied to next-generation power devices with high breakdown voltage and low loss.

  In power devices, the structure of termination regions (termination structure) such as junction termination extension (JTE) or field limiting ring (FLR) is used to alleviate electric field concentration at the device edge in the blocking state. ) Is known to form. In addition, the blocking state here refers to a state where a high potential difference is generated between the electrodes of the power device and no current flows between the electrodes.

In Patent Document 1 (Japanese Patent Laid-Open No. 11-330496), a passivation film is formed of a silicon oxide film (SiO ₂ film) and a high dielectric film (high-k film), and thus the passivation film is applied. It is described that the voltage is shared between the silicon oxide film and the high-k film to prevent the passivation film from being destroyed.

  In Patent Document 2 (Japanese Patent Laid-Open No. 2002-524860), a voltage applied to the passivation film is formed by forming the passivation film with three layers of a silicon oxide film, a high-k film, and a silicon oxide film. Is divided by a silicon oxide film and a high-k film to prevent leakage current from flowing through the passivation film.

Japanese Patent Laid-Open No. 11-330496 JP 2002-524860 A

  In the termination design of a power device using SiC as a substrate, it is necessary to consider that a high electric field is applied not only to the structural design of JTE and FLR but also to a passivation film provided on the upper portion of the termination structure.

Here, the operation principle of JTE will be described using the diode shown in FIGS. 14 and 15 as an example of a power device. 14 is a plan view of the surface electrode of the diode and the passivation film, and FIG. 15 is a cross-sectional view taken along the line AA of FIG. In FIG. 14, the n ⁻ type drift layer 2 on the n ⁺ type substrate 1 (see FIG. 15), the p type guard ring region 3, the p type JTE region 4 and the n ⁺ formed on the upper surface of the n ⁻ type drift layer 2. Only the mold field stop region 5 is shown, and a passivation film, a surface electrode, a resin film, and the like formed thereon are not shown. Further, FIG. 15 shows only a termination region which is an end portion of the semiconductor chip in FIG. 14, and illustration of an active region in the central portion of the semiconductor chip and a diode formed in the active region is omitted. FIG. 14 is a plan view, but is partially hatched to make the drawing easy to see.

As shown in FIG. 15, a p-type guard ring region 3, a p-type JTE region 4, and an n ⁺ -type field stop region 5 are formed on the upper surface of the n ⁻ -type drift layer 2 formed on the n ⁺ -type substrate 1. The back electrode 7 is formed on the back surface of the n ⁺ type substrate 1, and the surface electrode 8, the passivation film 11, and the floating electrode are in contact with the top surface of the n ⁻ type drift layer 2 on the n ⁻ type drift layer 2. 9 is formed. A floating electrode 9 is electrically connected on the n ⁺ -type field stop region 5, and a part of each of the surface electrode 8 and the floating electrode 9 is formed on the passivation film 11. As shown in FIG. 14, p-type guard ring region 3, p-type JTE region 4 and n ⁺ -type field stop region 5, n ^- n so as to surround the active region of the type drift layer 2 top ^- -type drift layer 2 top Are formed in order from the center to the end. In addition, although a high breakdown voltage diode is formed in the active region surrounded by the p-type guard ring region 3, the illustration thereof is omitted here, and only the n ⁻ type drift layer 2 is shown in the active region. Actually, a p-type semiconductor layer or the like is formed on the upper surface of the n ⁻ -type drift layer 2 in the active region.

  In the blocking state in which a voltage is applied between the back electrode 7 and the front electrode 8 shown in FIG. 15, for example, the front electrode 8 to which a voltage of 0 V is applied from the back electrode 7 to which a voltage of several kV is applied, for example. Electric lines of force extend toward. At this time, electric lines of force tend to concentrate on the edge portion of the surface electrode 8, but the presence of the p-type guard ring region 3 and the p-type JTE region 4 spreads the electric lines of force in the lateral direction. The electric field concentration at the edge portion of 8 can be relaxed. Even in an FLR having a plurality of p-type regions for relaxing the electric field, the electric field lines can be similarly expanded in the lateral direction, so that the electric field concentration can be reduced. This makes it possible to increase the breakdown voltage of the power device.

  However, when a high-k film is used for the passivation film, there are technical problems described below. The passivation film typically has a film thickness of several hundreds of nanometers to several μm in order to prevent destruction by a high electric field, and the voltage applied to the passivation film is shared between the silicon oxide film and the high-k film. In some cases, the high-k film also needs to have a corresponding film thickness. However, as a result of studies by the present inventors, when the insulating film is composed of a silicon oxide film and a high-k film, if the high-k film is thick, the reliability of the insulating film (stabilization of the charge amount of the insulating film due to electric stress application) It became clear that there was a problem that the

  Furthermore, when a high electric field is applied to the passivation film as in a SiC power device, there are not only the destruction of the passivation film and an increase in leakage current, but also technical problems described below. In other words, there is a problem that carriers accelerated by a high electric field are injected into the passivation film, and the charge in the passivation film is moved by the high electric field, so that the effective passivation film charge is changed over time. There is a problem that fluctuates. In addition, since there are a large number of interface traps at the interface between the SiC and the insulating film, the effective passivation film charge fluctuates also due to charge / discharge of charges in the trap. When the charge in the passivation film fluctuates, the way in which the electric lines of force spread in JTE or FLR changes. For this reason, the withstand voltage of the power device, that is, the anode-cathode withstand voltage of the diode or the source-drain withstand voltage of the transistor fluctuates, which is a problem from the viewpoint of reliability.

  An object of the present invention is to provide a semiconductor device having high reliability.

  The above object and novel features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

  Of the inventions disclosed in the present application, the outline of typical ones will be briefly described as follows.

A semiconductor device according to an invention of the present application includes a semiconductor substrate including silicon carbide having a first conductivity type,
A drift layer formed on the semiconductor substrate, having the first conductivity type, having a lower impurity concentration than the semiconductor substrate and containing silicon carbide;
A semiconductor region having a second conductivity type different from the first conductivity type formed on an upper surface in the drift layer;
A passivation film formed on the drift layer;
An electrode formed on the drift layer;
A back electrode formed in contact with the back surface of the drift layer;
Including
The passivation film is
A first insulating film formed in contact with the upper surface of the drift layer;
A metal insulating film formed on the first insulating film;
A second insulating film formed on the metal insulating film;
Have
The metal insulating film has a thickness in the range of 0.3 nm to 10 nm.

  Among the inventions disclosed in the present application, effects obtained by typical ones will be briefly described as follows.

  According to the present invention, the reliability of a semiconductor device can be improved.

It is sectional drawing which shows the semiconductor device which is Embodiment 1 of this invention. It is a graph which shows the relationship between a proof pressure and the charge amount of a passivation film. It is a graph which shows the relationship between the film thickness of an aluminum oxide film, and the effective negative charge amount of an aluminum oxide film. It is a graph which shows the relationship between the film thickness of an aluminum oxide film, and the variation | change_quantity of the insulating film charge after applying an electrical stress. It is sectional drawing which shows the manufacturing process of the semiconductor device which is Embodiment 1 of this invention. FIG. 6 is a cross-sectional view of the semiconductor device during a manufacturing step following that of FIG. 5; FIG. 7 is a cross-sectional view of the semiconductor device during a manufacturing step following that of FIG. 6; FIG. 8 is a cross-sectional view of the semiconductor device during a manufacturing step following that of FIG. 7; FIG. 9 is a cross-sectional view of the semiconductor device during a manufacturing step following that of FIG. 8; FIG. 10 is a cross-sectional view of the semiconductor device during a manufacturing step following that of FIG. 9; It is sectional drawing which shows the modification of the semiconductor device which is Embodiment 1 of this invention. It is sectional drawing which shows the semiconductor device which is Embodiment 2 of this invention. It is sectional drawing which shows the semiconductor device which is Embodiment 3 of this invention. It is a top view of the semiconductor device shown as an example of a power device. It is sectional drawing in the AA of FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiments, and the repetitive description thereof will be omitted. Also, in the following embodiments, the description of the same or similar parts will not be repeated in principle unless particularly necessary.

(Embodiment 1)
FIG. 1 shows a cross-sectional view of the semiconductor device of this embodiment. The semiconductor device of the present embodiment has a power device (not shown) such as a high breakdown voltage transistor formed on a semiconductor substrate made of silicon carbide (SiC). FIG. The cross section of the area | region (termination area | region) used as the edge part of the semiconductor chip formed by dividing into pieces is shown. SiC has a higher dielectric breakdown electric field and higher breakdown voltage than Si (silicon). Since the breakdown voltage of the device is greatly affected by the thickness of the drift layer, the drift layer can be made thin and highly concentrated while securing the breakdown voltage of the device by using SiC for the substrate and the drift layer. Therefore, although conduction loss can be reduced, since the high withstand voltage is applied to the passivation film on the drift layer, a leakage current is generated due to this. There is also a problem. In the structure shown in FIG. 1, the center portion of the semiconductor chip is located on the left side of the drawing, and the end portion of the semiconductor chip is located on the right side of the drawing.

As shown in FIG. 1, a p-type guard ring region 3, a p-type JTE region 4 and an n ⁺ -type field stop are formed on the upper surface of an n ⁻ -type drift layer 2 formed on an n ⁺ -type substrate 1 by an epitaxial growth method or the like. Region 5 is formed. The p-type guard ring region 3, the p-type JTE region 4 and the n ⁺ -type field stop region 5 surround the active region in the central portion of the semiconductor chip from the central portion (left side in FIG. 1) to the end portion of the semiconductor chip. They are arranged in order toward the right side of FIG. That is, when the semiconductor chip is viewed from above, the p-type guard ring region 3 is formed so as to surround the active region on the upper surface of the n ⁻ type drift layer 2, and the p-type JTE region so as to surround the p-type guard ring region 3. 4 are formed, and n ⁺ -type field stop regions 5 are formed in an annular shape so as to surround the p-type JTE region 4. In the figure, although the p-type guard ring region 3 and the p-type JTE region 4 is in contact, p-type JTE region 4 and n ⁺ -type field stop region 5 is not in contact, no impurity is introduced between n ^- A type drift layer 2 is present.

The p-type guard ring region 3 and the p-type JTE region 4 are semiconductor regions formed by introducing p-type impurities (for example, Al (aluminum)) into the upper surface of the n ⁻ -type drift layer 2 made of SiC. Here, it is assumed that the p-type guard ring region 3 has a higher p-type impurity concentration than the p-type JTE region 4, but which of the impurity concentrations of the p-type guard ring region 3 and the p-type JTE region 4 is different. It may be high or may have the same impurity concentration. The p-type guard ring region 3 and the p-type JTE region 4 have the same junction depth, and the n ⁺ -type field stop region 5 has a shallower junction depth than the p-type JTE region 4. The junction depth of each semiconductor region is not limited to this. The n ⁺ type field stop region 5 is a semiconductor region for preventing the electric field applied to the device from reaching the end portion of the semiconductor chip.

A back surface electrode 7 is formed on the back surface of the n ⁺ type substrate 1, and a surface electrode 8, a passivation film 6 and a floating electrode 9 are in contact with the top surface of the n ⁻ type drift layer 2 on the n ⁻ type drift layer 2. Is formed. The back electrode 7, the front electrode 8, and the floating electrode 9 are made of, for example, Al (aluminum), and the passivation film 6 is a first silicon oxide film 6 a that is sequentially stacked from the upper surface of the n ⁻ type drift layer 2. The metal insulating film 6b and the second silicon oxide film 6c are used. The bottom surface of the first silicon oxide film 6a is in contact with the n ⁻ type drift layer 2 made of SiC, and the film thickness of the metal insulating film 6b is not less than 0.3 nm and not more than 10 nm. Here, the film thickness of the metal insulating film 6b is assumed to be 1 nm, for example. In the present application, a film made of a metal compound having an insulating property is called a metal insulating film. The metal insulating film 6b is an insulating film made of, for example, aluminum oxide (for example, alumina (Al ₂ O ₃ )). In this application, a film containing an aluminum oxide containing oxygen (O) and aluminum (Al) is referred to as an aluminum oxide film.

  It is also conceivable that the metal insulating film 6b is formed of titanium oxide. However, since an electric charge is easily injected into the insulating film made of Ti (titanium) and Al (aluminum) when in contact with SiC, the lower surface and the upper surface of the metal insulating film 6b are used here as the first silicon oxide film 6a and the second oxide film. It is covered with a silicon film 6c.

A floating electrode 9 is electrically connected to the upper surface of the n ⁺ type field stop region 5, and the surface electrode 8 is a high voltage MOSFET (Metal Oxide Semiconductor Field) formed on the upper surface of the n ⁻ type drift layer 2 in the active region. It is electrically connected to the source electrode (not shown) of Effect Transistor. A part of each of the surface electrode 8 and the floating electrode 9 is formed so as to run on the end portion of the passivation film 6. The floating electrode 9 is an electrode for fixing the potential of the n ⁺ type field stop region 5.

The passivation film 6 is arranged so as to cover the upper surface of the end portion of the p-type guard ring region 3, the upper surface of the p-type JTE region 4, and the upper surface of the end portion of the n ⁺ -type field stop region 5. That is, the passivation film 6 is formed from a portion directly above the p-type guard ring region 3 to a portion directly above the n ⁺ -type field stop region 5 and covers the entire upper surface of the p-type JTE region 4. In the present application, a structure including a p-type guard ring region 3 or a p-type JTE region 4 semiconductor region for the purpose of electric field relaxation formed in a region near an end portion (edge portion) of a semiconductor chip as shown in FIG. Is called a termination structure. An insulating film that covers the passivation film 6, the surface electrode 8, and the floating electrode 9 may be further provided above the passivation film 6. As the material of the insulating film, it is conceivable to use an insulating film such as a silicon oxide film or a resin such as polyimide.

During operation of the semiconductor device having this termination structure, in a blocking state in which a voltage is applied between the back electrode 7 and the front electrode 8, electric lines of force extend from the back electrode 7 toward the front electrode 8. . The electric lines of force tend to concentrate on the edge portion of the surface electrode 8, that is, the end of the surface electrode 8 in contact with the n ⁻ type drift layer 2, but the electric line of force is generated by the p-type guard ring region 3 and the p-type JTE region 4. Since it is spread in the lateral direction, the electric field concentration at the edge portion of the surface electrode 8 can be relaxed. Further, as will be described below, since the metal insulating film 6b having a negative charge is used for the passivation film 6, an effective inside of the passivation film 6 is caused by a high electric field applied to the passivation film 6. Even if the charge fluctuates, concentration of electric lines of force on the surface electrode 8 can be prevented. For this reason, it is possible to suppress withstand voltage fluctuation.

A semiconductor device according to an embodiment of the present invention includes a first silicon oxide film in which a passivation film on a p-type impurity region forming a termination structure of a SiC power device is in contact with SiC (n ⁻ type drift layer 2); It has a metal insulating film located above the first silicon oxide film and a second silicon oxide film located above the metal insulating film, and the thickness of the metal insulating film is not less than 0.3 nm and not more than 10 nm. It is characterized by.

  The effects of the semiconductor device of this embodiment will be described below using graphs.

  FIG. 2 is a graph showing the relationship between the effective passivation film charge and the breakdown voltage of the device. The vertical axis of the graph represents the breakdown voltage of the power device, and the breakdown voltage when the charge amount of the passivation film is 0 is defined as 1. The horizontal axis of the graph indicates the amount of charge in the passivation film. In the case where the effective passivation film charge is positive, the breakdown voltage sharply decreases as the positive charge increases. That is, on the right side of the graph, the withstand voltage changes rapidly as the charge amount of the passivation film changes.

  On the other hand, when the effective passivation film charge is negative, there is almost no fluctuation in breakdown voltage due to the charge. In other words, if the passivation film charge is negative, even if the passivation film charge increases or decreases somewhat positively or negatively, the withstand voltage may suddenly change as in the case where the passivation film charge is positive. Absent. In particular, in the blocking state, the positive charge increases in the passivation film. However, if the original passivation film charge is negative, it is high even if the passivation film charge varies positively as shown in FIG. The breakdown voltage can be maintained.

  Since the metal insulating film containing Al (aluminum) or Ti (titanium) has a negative charge, a stable termination structure with less fluctuation in breakdown voltage can be realized by using these for the passivation film. In addition, as shown in FIG. 1, the first silicon oxide film 6a and the second silicon oxide film 6c are disposed on the lower layer and the upper layer of the metal insulating film 6b, respectively, so that a high electric field is applied to the passivation film 6. Charge injection into the metal insulating film 6b can be suppressed. Thereby, the charge fluctuation of the passivation film 6 can be suppressed.

As a result of studies by the present inventors, it has been clarified that the film thickness of the aluminum oxide film and the negative charge amount have a relationship as shown in the graph of FIG. 3, the vertical axis represents the absolute value of the effective negative charge amount Q _F of passivation film including an aluminum oxide film, the negative charge amount when the film thickness of the aluminum oxide film is 20 nm 1 It is defined as The horizontal axis of the graph indicates the film thickness of the aluminum oxide film. When the thickness of the aluminum oxide film is increased from 0 nm, the negative charge amount increases rapidly. However, when the film thickness is 0.3 nm or more, the increase in the negative charge amount becomes very gradual. That is, if the thickness of the aluminum oxide film is 0.3 nm or more, a desired negative charge can be provided in the aluminum oxide film.

  On the other hand, if the thickness of the aluminum oxide film is too thick, the electric charge amount of the aluminum oxide film tends to fluctuate when electrical stress is applied. As a result of the study by the present inventors, it is clear that the film thickness of the aluminum oxide film and the amount of change in the charge of the passivation film when an electrical stress is applied have a relationship as shown in the graph of FIG. became. In FIG. 4, the vertical axis indicates the amount of change in the charge of the passivation film including the aluminum oxide film due to electrical stress. The amount of change in the charge when the film thickness is 20 nm is defined as 1. The horizontal axis of the graph indicates the film thickness of the aluminum oxide film.

If the thickness of the aluminum oxide film is small, the amount of fluctuation in the charge is small and stable, but if the thickness exceeds 5 nm, the amount of fluctuation in the charge increases, and if it exceeds 10 nm, the aluminum oxide film is not used. As shown in FIG. 8, the charge fluctuation amount is five times or more compared to the case where the passivation film 11 is made of only SiO ₂ . In particular, when a high electric field is applied to the passivation film as in a SiC power device, it is easily affected by the high electric field due to strong electrical stress.

  Due to the above facts, it is important that the thickness of the metal insulating film is not less than 0.3 nm and not more than 10 nm. That is, if the thickness of the metal insulating film is 0.3 nm or more, a sufficient amount of charge can be provided, but if the thickness is larger than 10 nm, the amount of charge in the metal insulating film becomes unstable. The thickness needs to be 10 nm or less. More preferably, the thickness of the metal insulating film is from 0.3 nm to 5 nm. Thereby, a passivation film having a more stable charge against electrical stress can be provided.

  When the metal insulating film is processed by wet etching for the purpose of avoiding damage to the main surface of the substrate by dry etching, the thickness of the metal insulating film is not less than 0.3 nm and not more than 1 nm. More desirable. Thereby, there is no etching residue, and the metal insulating film and the silicon oxide film positioned above and below the metal insulating film can be processed continuously.

  Since the electric field applied to the passivation film can be controlled by the structure design such as the concentration, width, and depth of the p-type impurity region of the termination structure, the thickness of the passivation film can be reduced without forming a thick high-k film. Insulation breakdown can be prevented and leakage current can be reduced, and the device can have a high breakdown voltage. Therefore, as shown in FIG. 1, it is not always necessary to form a high-k film having a high dielectric constant and a large film thickness in the passivation film 6. A high-k film having a large film thickness is less stable in the amount of charge in the insulating film when an electrical stress is applied. However, in the semiconductor device shown in FIG. Since the k film is not formed, it is possible to prevent the charge amount of the passivation film 6 from fluctuating.

  In the semiconductor device of the present embodiment, as shown in FIG. 1, the passivation film 6 is formed using a metal insulating film 6b having a film thickness of 0.3 nm or more and 10 nm or less, so that it is hardly affected by an electric field. A termination structure that can maintain a stable charge is realized. Further, since the metal insulating film 6b is made of an aluminum oxide film, the metal insulating film 6b is an insulating film having a negative charge. Therefore, as described with reference to FIG. 2, the passivation film is formed by a high electric field in the blocking state. Even if the positive charge in 6 increases, the high breakdown voltage of the passivation film 6 can be maintained.

  Therefore, in the termination region of a semiconductor device having a SiC power device, the charge in the passivation film can be stabilized even when a high electric field is applied, and the amount of fluctuation in the breakdown voltage of the passivation film is reduced, resulting in a high breakdown voltage. Can be maintained stably. For this reason, the generation of leakage current that flows due to the concentration of electric lines of force on the edge portion of the surface electrode 8 is prevented, and the reliability of the insulating film (the stability of the charge amount of the insulating film due to the application of electrical stress) is improved. It is possible to prevent the withstand voltage of the transistor, that is, the anode-cathode withstand voltage of the diode or the source-drain withstand voltage of the transistor from fluctuating. Thereby, the reliability of the semiconductor device can be improved.

  That is, by inserting the metal insulating film 6 b having a negative fixed charge into the passivation film 6, the effective passivation film charge can be made negative. As a result, it is possible to provide a stable termination structure with little fluctuation in breakdown voltage even when a high electric field is applied to the passivation film.

  Hereinafter, a method for manufacturing the semiconductor device of the present embodiment will be described with reference to the drawings. 5 to 10 are cross-sectional views of the semiconductor device during the manufacturing process. Here, the active region is not shown, and the description of the manufacturing process of the high breakdown voltage element formed in the active region is omitted, but at the same time as the termination structure is formed, a semiconductor element is formed in the active region according to the device structure. Needless to say.

First, as shown in FIG. 5, a base in which an n ⁻ type drift layer 2 is laminated on an n ⁺ type substrate 1 that is a SiC substrate is prepared. The n ⁻ type drift layer 2 is an n type SiC film formed on the n ⁺ type substrate 1 by an epitaxial growth method.

Next, as shown in FIG. 6, after an insulating film made of a silicon oxide film or the like is formed on the upper surface of the n ⁻ type drift layer 2, the insulating film is patterned to form an ion implantation mask M1. Subsequently, p-type impurities (for example, Al (aluminum)) are ion-implanted into the upper surface of the n ⁻ -type drift layer 2 to form the p-type guard ring region 3. At this time, the p-type guard ring region 3 is formed with a doping concentration of about 1 × 10 ¹⁸ cm ⁻³ to 2 × 10 ²⁰ cm ⁻³ and a thickness (junction depth) of about 0.5 to 2.0 μm. .

Next, as shown in FIG. 7, after removing the mask M1, a patterned ion implantation mask M2 made of a silicon oxide film or the like is formed on the n ⁻ type drift layer 2 and the p type guard ring region 3. To do. Subsequently, p-type impurities (for example, Al (aluminum)) are ion-implanted into the upper surface of the n ⁻ -type drift layer 2 exposed from the mask M 2 to form the p-type JTE region 4. At this time, the p-type JTE region 4 is formed with a doping concentration of about 5 × 10 ¹⁶ cm ⁻³ to 1 × 10 ¹⁸ cm ⁻³ and a thickness of about 0.5 to 2.0 μm. Here, the p-type JTE region 4 is formed adjacent to the p-type guard ring region 3.

Next, as shown in FIG. 8, after removing the mask M2, patterned ions made of a silicon oxide film or the like on the n ⁻ type drift layer 2, the p type guard ring region 3 and the p type JTE region 4 are formed. An implantation mask M3 is formed. Subsequently, an n ⁺ type field stop region 5 is formed by ion implantation of an n type impurity (for example, N (nitrogen)) on the upper surface of the n ⁻ type drift layer 2 exposed from the mask M3. The p-type guard ring region 3, the p-type JTE region 4, and the n ⁺ -type field stop region 5 are formed in order toward the outside of the active region so as to surround the active region (not shown) on the upper surface of the n ⁻ -type drift layer 2. .

That is, from the central portion (left side in FIG. 8) to the end portion of the semiconductor chip (right side in FIG. 8) so as to surround the active region in the central portion of the semiconductor chip that is formed by dicing the n ⁺ type substrate 1 later by dicing. P-type guard ring region 3, p-type JTE region 4 and n ⁺ -type field stop region 5 are arranged in this order. In plan view, p-type guard ring region 3 is formed so as to surround the active region on the upper surface of n ⁻ type drift layer 2, p-type JTE region 4 is formed so as to surround p-type guard ring region 3, and p An n ⁺ type field stop region 5 is formed so as to surround the type JTE region 4. Subsequently, after removing the mask M3, the semiconductor device in the manufacturing process including the n ⁺ type substrate 1 is heat-treated at, for example, 1700 ° C. in order to activate the implanted Al (aluminum) and N (nitrogen).

Next, as shown in FIG. 9, a first silicon oxide film 6a is formed on the n ⁻ type drift layer 2 by thermal oxidation, CVD (Chemical Vapor Deposition), or a combination of both. Next, a metal insulating film 6b and a second silicon oxide film 6c are sequentially formed on the first silicon oxide film 6a using a CVD method or the like, and the first silicon oxide film 6a, the metal insulating film 6b, and the second silicon oxide film 6c are formed. A passivation film 6 is formed. The first silicon oxide film 6a and the second silicon oxide film 6c are SiO ₂ films, and the metal insulating film 6b is an insulating film containing aluminum oxide, and here is composed of an Al ₂ O ₃ film. The thickness of the metal insulating film 6b is not less than 0.3 nm and not more than 10 nm.

Subsequently, a patterned mask M4 is formed on the passivation film 6, and the passivation film 6 is processed by dry etching or wet etching, so that the p-type guard ring region 3 and the n ⁺ -type field stop region 5 are processed. To expose. The mask M4 is assumed to be a photoresist film formed using, for example, a photolithography technique.

Next, as shown in FIG. 10, after removing the mask M ^< b ^> 4, the back surface electrode 7 is formed on the back surface that is the surface opposite to the main surface of the n ⁺ type substrate 1. The back electrode 7 may be formed by sputtering Al (aluminum), for example, but may be formed by NiSi or TiSi. Next, after forming a metal film made of, for example, Al (aluminum) so as to cover the upper surface of the n ⁻ type drift layer 2 and the surface of the passivation film 6, the metal film is patterned to form a passivation film. The upper surface of the passivation film 6 is exposed. At this time, the upper surfaces of both ends of the passivation film 6 are not exposed. Accordingly, the surface electrode 8 and the floating electrode 9 made of the metal film are formed on the inner side (active region side) and the outer side of the passivation film 6 having an annular planar shape, respectively. That is, the surface electrode 8 is formed on the active region side with respect to the passivation film 6, and the floating electrode 9 is formed on the opposite side of the active region with respect to the passivation film 6. Both the surface electrode 8 and the floating electrode 9 are formed so that a part thereof rides on the end portion of the passivation film 6.

As described above, the surface electrode 8 electrically connected to a part of the power device in the active region and the floating electrode 9 electrically connected to the n ⁺ type field stop region 5 are formed. The termination structure shown in FIG. 10 is completed. Note that the p-type guard ring region 3 and the p-type JTE region 4 need not have the same depth. Further, the p-type JTE region 4 does not have to be a single region, and may be formed of a plurality of regions. That is, the p-type JTE region 4 may be formed of a semiconductor region having a relatively high impurity concentration and a semiconductor region having a lower impurity concentration, and the p-type JTE region 4 may have a concentration gradient. Further, the order of forming the p-type guard ring region 3, the p-type JTE region 4, and the n ⁺ -type field stop region 5 need not be as described above.

Thereafter, the semiconductor device of the present embodiment is completed by dicing the n ⁺ type substrate 1 into pieces to form a plurality of semiconductor chips. An insulating film covering the entire surface of the n ⁺ type substrate 1 may be formed before dicing. Further, the semiconductor chip may be covered with a resin film made of polyimide or the like. The n ⁺ -type field stop region 5 is located near the end of the semiconductor chip formed by dicing, and the p-type guard ring region 3 is closer to the center of the semiconductor chip than the n ⁺ -type field stop region 5. The area will be located.

  In the present embodiment, aluminum oxide is exemplified as a member of the metal insulating film 6b. However, the present invention is not limited to this, and may be aluminum nitride or titanium oxide. That is, since the metal insulating film 6b may be an insulating film having a negative charge, various members can be used.

  Further, as described above, the thickness of the metal insulating film 6b is more preferably 0.3 nm or more and 5 nm or less. As a result, a passivation film that is stable against electrical stress can be provided.

  Further, when the metal insulating film 6b is processed by a wet process, the thickness of the metal insulating film 6b is more preferably 0.3 nm or more and 1 nm or less. As a result, there is no etching residue, and the metal insulating film 6b and the first silicon oxide film 6a positioned above and below the metal insulating film 6b can be processed continuously.

In this embodiment, the termination structure is JTE. However, as shown in FIG. 11, the same effect can be obtained even if the termination structure is FLR. FIG. 11 is a cross-sectional view showing a modification of the semiconductor device according to the present embodiment. A plurality of p-type semiconductor regions 4 a are formed on the upper surface of the n ⁻ -type drift layer 2 instead of the p-type JTE region 4. Each of the plurality of p-type semiconductor regions 4 a has an annular planar shape like the p-type guard ring region 3 and is disposed so as to surround the active region and the p-type guard ring region 3. By forming the plurality of p-type semiconductor regions 4a in this way, the electric field applied to the termination region can be relaxed.

Further, when the first silicon oxide film 6a is formed, if it is oxynitrided with nitrogen monoxide or dinitrogen monoxide or annealed, the n ⁻ type drift layer 2 made of SiC of the first silicon oxide film 6a. N (nitrogen) can be introduced into the first silicon oxide film 6a in the vicinity of the interface. Thus, reducing the trap (trap level) at the interface between the n ⁻ type drift layer 2 and the passivation film 6 is effective for suppressing the fluctuation of the effective passivation film charge.

  In the semiconductor device of the present embodiment formed by the manufacturing process described above, a metal insulating film having a thickness of 0.3 nm to 10 nm and having a negative charge is provided in the passivation film, as described above. In the termination region of an apparatus having a SiC power device, the charge in the passivation film can be stabilized even when a high electric field is applied. Therefore, it is possible to prevent the breakdown voltage of the power device from fluctuating, so that the reliability of the semiconductor device can be improved.

(Embodiment 2)
A cross-sectional view of the termination region of the semiconductor device containing SiC according to the present embodiment will be described with reference to FIG. FIG. 12 is a cross-sectional view of the semiconductor device according to the present embodiment, and shows a structure substantially similar to the termination structure shown in FIG. However, in the semiconductor device of the present embodiment, the first silicon oxide film 6a, the silicon nitride (SiN) film 6d, the metal insulating film 6b, the silicon nitride film 6e, and the first film in which the passivation film 6 is sequentially stacked on the substrate. It differs from the first embodiment in that it has at least five layers of the silicon dioxide film 6c.

That is, the passivation film 6 includes the first silicon oxide film 6a, the silicon nitride film 6d, the metal insulating film 6b, the silicon nitride film 6e, and the second silicon oxide film 6c that are sequentially stacked on the upper surface of the n ⁻ type drift layer 2. The metal insulating film 6b is made of a metal oxide film such as aluminum oxide, for example. The thickness of the metal insulating film 6b is 0.3 nm or more, and the sum of the thicknesses of the silicon nitride film 6d, the metal insulating film 6b, and the silicon nitride film 6e is 10 nm or less. Note that an insulating film may be further provided on the passivation film 6.

  As an operation of this termination structure, in a blocking state in which a voltage is applied between the back electrode 7 and the front electrode 8, electric lines of force extend from the back electrode 7 to the front electrode 8. Electric field lines tend to concentrate on the edge portion of the surface electrode 8, but the electric field lines are spread laterally by the p-type guard ring region 3 and the p-type JTE region 4. Can be relaxed. Since the metal film 6b having a negative charge is used for the passivation film 6, even if the effective passivation film charge fluctuates due to a high electric field applied to the passivation film 6, the electricity to the surface electrode 8 is changed. Concentration of field lines can be prevented. For this reason, it is possible to suppress withstand voltage fluctuation.

  In the passivation film made of a laminated insulating film made of a silicon oxide film, a silicon nitride film, or a metal insulating film shown in this embodiment, the reliability of the film itself is improved as compared with a laminated insulating film without a silicon nitride film. To do. Specifically, the life until dielectric breakdown and the stability of effective insulating film charge are improved.

  Note that in the case where the metal insulating film is sandwiched between silicon nitride films as in this embodiment, if the silicon nitride film is too thick, the charge of the metal insulating film is similar to the characteristics described with reference to FIG. The fluctuation amount of becomes larger. For this reason, in this embodiment, the total film thickness of the silicon nitride film 6d, the metal insulating film 6b, and the silicon nitride film 6e is set to 10 nm or less, thereby stabilizing the charge in the passivation film 6 and improving the breakdown voltage of the device. It is possible to make it.

  When manufacturing the semiconductor device of this embodiment, the semiconductor device shown in FIG. 12 can be formed by performing substantially the same steps as those described in Embodiment 1 with reference to FIGS. However, the structure of the passivation film 6 is different from that of the first embodiment. Therefore, in the process described with reference to FIG. 9, after the first silicon oxide film 6a is formed by thermal oxidation or CVD, or a combination of both, the silicon nitride film 6d, the metal insulating film 6b, the silicon nitride film 6e, The passivation film 6 is formed by sequentially laminating the second silicon oxide film 6c using the CVD method or the like and patterning the laminated insulating film formed thereby.

  Here, the thickness of the metal insulating film 6b is 0.3 nm or more, and the sum of the thicknesses of the silicon nitride film 6d, the metal insulating film 6b, and the silicon nitride film 6e is 10 nm or less. The metal insulating film is, for example, aluminum oxide. The subsequent steps are performed in the same manner as in the first embodiment, thereby completing the termination structure shown in FIG. Note that the p-type guard ring region 3 and the p-type JTE region 4 need not have the same depth. Further, the p-type JTE region 4 does not have to be a single region, and may be formed of a plurality of regions.

  It has been confirmed that the reliability of the stacked insulating film itself is improved in the stacked insulating film including the silicon oxide film, the silicon nitride film, and the metal insulating film described in this embodiment as compared with the stacked insulating film without the silicon nitride film. did it. Specifically, the life until breakdown and the stability of the effective insulating film charge were improved.

  In the present embodiment, aluminum oxide is exemplified as the metal insulating film, but the present invention is not limited to this and may be aluminum nitride or titanium oxide. In the present embodiment, the termination structure is JTE, but the same effect can be obtained even if the termination structure is FLR.

Further, when the first silicon oxide film 6a is formed, if it is oxynitrided with nitrogen monoxide or dinitrogen monoxide or annealed, the n ⁻ type drift layer 2 made of SiC of the first silicon oxide film 6a. N (nitrogen) can be introduced into the first silicon oxide film 6a in the vicinity of the interface. Thus, reducing traps at the interface between the n ⁻ type drift layer 2 and the passivation film 6 is effective for suppressing fluctuations in effective passivation film charge.

(Embodiment 3)
FIG. 13 shows a cross-sectional view including the MOSFET and termination region formed in the active region on the SiC substrate in the present embodiment. As shown in FIG. 13, the termination region on the right side of the figure has the same structure as the termination structure of the first embodiment shown in FIG. However, the passivation film 27 includes a first silicon oxide film 27a, a metal insulating film 27b, a second silicon oxide film 27c, and an insulating film 27d that are sequentially formed on the n ⁻ type drift layer 2.

Further, a high breakdown voltage MOSFET is formed in the active region shown on the left side of FIG. MOSFET the n ^- formed via a gate insulating film 24 made of the first silicon oxide film 24a from the type drift layer 2 above are laminated in this order, a metal insulating film 24b and the second silicon oxide film 24c ^- -type drift layer 2 on the n Gate electrode 25, n ⁺ type source region 22 formed on the upper surface of n ⁻ type drift layer 2 on both sides of gate electrode 25, and n ⁺ type substrate 1 as a drain region. That is, the back electrode 7 in contact with the n ⁺ type substrate 1 is a drain electrode that supplies a potential to the drain region of the MOSFET. The surface electrode 8 to the n ⁺ -type source regions 22 are electrically connected is a source electrode supplying a potential to the n ⁺ -type source region 22.

The gate insulating film 24 is in contact with the upper surfaces of the n ⁻ type drift layer 2 and the p type base region 21 and the n ⁺ type source region 22 formed on both sides of the n ⁻ type drift layer 2, respectively. 25, n in plan view ^- it is formed in either the even positions overlapping the p-type is formed on both sides of the type drift layer 2 base region 21 and n ⁺ -type source region 22 ^- -type drift layer 2 and the n. That is, the gate insulating film 24 is continuously formed immediately above each of the n ⁻ type drift layer 2, the p type base region 21, and the n ⁺ type source region 22, and the gate electrode 25 is also formed of the n ⁻ type drift layer 2. , P type base region 21 and n ⁺ type source region 22 are formed immediately above each.

A p ⁺ -type contact region 23 is formed further outside the n ⁺ -type source region 22 formed on the upper surface of the n ⁻ -type drift layer 2 on both sides of the gate electrode 25, and is formed on the upper surface of the n ⁻ -type drift layer 2. The p-type base region 21 is formed so as to cover the bottom and side surfaces of the semiconductor region formed of the n ⁺ -type source region 22 and the p ⁺ -type contact region 23. The surface electrode 8 is formed in contact with the upper surfaces of the n ⁺ -type source region 22 and the p ⁺ -type contact region 23, and the p ⁺ -type contact region 23 has a role of supplying a potential to the p-type base region 21. Yes. The p-type base region 21 is a p-type semiconductor region in which a MOSFET channel region is formed, and has a deeper junction depth than the n ⁺ -type source region 22 and the p ⁺ -type contact region 23. Here, the side surface of the p-type base region 21 is in contact with the side surface of the p-type guard ring region 3, and the junction depths of the p-type base region 21, the p-type guard ring region 3 and the p-type JTE region 4 are substantially the same. It shall be. However, the junction depth of these semiconductor regions can be changed as appropriate.

An insulating film 26 is formed immediately above the gate insulating film 24 so as to cover the surface of the gate electrode 25 and the upper surface of the end of the gate electrode 25. The surface electrode 8 includes an upper surface of one end of the passivation film 27, a p-type guard ring region 3, a p-type base region 21, an n ⁺ -type source region 22, a p ⁺ -type contact region 23, and a gate insulating film 24. It is continuously formed in contact with the sidewall and the surface of the insulating film 26. That is, the gate insulating film 24 and the insulating film 26 are covered with the surface electrode 8.

  As shown in FIG. 13, the gate insulating film 24 is composed of a laminated film in which a first silicon oxide film 24a, a metal insulating film 24b, and a second silicon oxide film 24c are sequentially formed on a substrate containing SiC. The passivation film 27 has the same structure as the gate insulating film 24, that is, has a first silicon oxide film 27a, a metal insulating film 27b, and a second silicon oxide film 27c in the film, and further on the second silicon oxide film 27c. The insulating film 27d is formed on the substrate. The metal insulating films 24b and 27b are made of, for example, a metal oxide film such as aluminum oxide, and their film thickness is not less than 0.3 nm and not more than 10 nm. Note that an insulating film may be further provided above the passivation film 27 in the termination region.

As an operation of this MOSFET, when a positive voltage is applied to the gate electrode 25 with a voltage applied between the back electrode (drain electrode) 7 and the front electrode (source electrode) 8, a p-type base is applied. An electron inversion layer is formed on the surface layer of the region 21. As a result, a current flows from the back electrode 7 to the surface electrode 8 through the n ⁺ type substrate 1, the n ⁻ type drift layer 2, the surface layer of the p type base region 21, and the n ⁺ type source region 22. On the other hand, as an operation of the termination structure, when a voltage is applied between the back electrode 7 and the front electrode 8 and 0 V is applied to the gate electrode 25, a current flows between the back electrode 7 and the front electrode 8. A blocking state that does not flow occurs, and electric lines of force extend from the back electrode 7 toward the front electrode 8. Electric field lines tend to concentrate on the edge portion of the surface electrode 8, but the electric field lines are laterally expanded by the p-type guard ring region 3 and the p-type JTE region 4. Can be relaxed. Since the metal film 27b having a negative charge is used for the passivation film 27, even if the effective passivation film charge fluctuates due to a high electric field applied to the passivation film 27, the passivation film 27 is applied to the surface electrode 8. Concentration of electric field lines can be prevented. For this reason, it is possible to suppress fluctuations in the breakdown voltage of the device.

  Next, a method of manufacturing the MOSFET and termination structure in the present embodiment will be described with reference to FIG. However, the present invention relates to a termination structure, and the MOSFET is formed by a well-known manufacturing method, and thus the illustration of the semiconductor device during the manufacturing process is omitted. Further, the manufacturing process of the termination structure on the right side of FIG. 13 is substantially the same as in the first embodiment.

First, an n ⁻ type drift layer 2 is formed on an n ⁺ type substrate 1 made of SiC by an epitaxial growth method. Then, a p-type guard ring region 3 is formed by forming a hard mask made of a silicon oxide film or the like on the upper surface of the n ⁻ -type drift layer 2 and implanting p-type impurities (for example, Al (aluminum)). . At this time, the p-type guard ring region 3 is formed with a doping concentration of about 1 × 10 ¹⁸ cm ⁻³ to 2 × 10 ²⁰ cm ⁻³ and a thickness of about 0.5 to 2.0 μm. Thereafter, similarly, ion implantation using a hard mask is performed to form the p-type JTE region 4. At this time, the p-type JTE region 4 is formed with a doping concentration of about 5 × 10 ¹⁶ cm ⁻³ to 1 × 10 ¹⁸ cm ⁻³ and a thickness of about 0.5 to 2.0 μm. Thereafter, n ⁺ -type field stop region 5 is formed by ion-implanting n-type impurities (for example, N (nitrogen)) into the upper surface of n ⁻ -type drift layer 2 in the same manner using a hard mask.

Next, a patterned hard mask is formed on the n ⁻ type drift layer 2, the p type guard ring region 3, the p type JTE region 4, and the n ⁺ type field stop region 5, and then exposed in the active region. A p-type base region 21 is formed by ion-implanting a p-type impurity (for example, Al (aluminum)) on the upper surface of the n ⁻ -type drift layer 2. The p-type base region 21 is formed with a doping concentration of about 1 × 10 ¹⁷ cm ⁻³ to 1 × 10 ¹⁸ cm ⁻³ and a thickness of about 0.5 to 3.0 μm. Subsequently, a hard mask that exposes a part of the p-type base region 21 is formed on the n ⁻ -type drift layer 2, and an n-type impurity (for example, N (nitrogen)) is ion-implanted to thereby form an n ⁺ -type source region. 22 is formed. Subsequently, a hard mask is formed on the n ⁻ type drift layer 2 so as to cover the n ⁺ type source region 22 and expose a part of the p type base region 21, and p type impurities (for example, Al (aluminum)) are formed. A p ⁺ -type contact region 23 is formed by ion implantation. Subsequently, after removing the hard mask, heat treatment is performed at 1700 ° C., for example, to activate the implanted Al (aluminum) and N (nitrogen).

Next, a first insulating film made of silicon oxide is formed on the n ⁻ type drift layer 2 by performing thermal oxidation within a process temperature range of about 1000 to 1300 ° C. Subsequently, a second insulating film containing metal and a third insulating film made of silicon oxide are sequentially formed on the first insulating film by a CVD method or the like. After that, after a polycrystalline silicon film is formed on the third insulating film by a CVD method or the like, the polycrystalline silicon film is patterned to form a gate directly above the region between the two p-type base regions 21 in the active region. The electrode 25 is formed. Subsequently, a fourth insulating film made of, for example, silicon oxide is formed on the third insulating film so as to cover the gate electrode 25.

  Next, after forming a hard mask directly over the region between the two p-type base regions 21 in the active region and covering a part of the termination region, the first to fourth regions are formed using a dry etching method or a wet etching method. The insulating film is patterned. Thus, the first silicon oxide film 24a made of the first insulating film, the metal insulating film 24b made of the second insulating film, and the third insulating film are formed immediately above the region between the two p-type base regions 21 in the active region. A gate insulating film 24 made of a laminated film in which the second silicon oxide film 24c is sequentially laminated is formed. At the same time, the termination region includes a first silicon oxide film 27a made of a first insulating film, a metal insulating film 27b made of a second insulating film, a second silicon oxide film 27c made of a third insulating film, and a fourth insulating film. A passivation film 27 in which insulating films 27d are sequentially stacked is formed. Here, the film thickness of the metal insulating films 24b and 27b is 0.3 nm or more and 10 nm or less, and the total film thickness of the gate insulating film 24 is 30 nm or more and 100 nm or less. The metal insulating films 24b and 27b are made of, for example, aluminum oxide. Thus, in the step of forming the gate insulating film 24, the first silicon oxide film 27a, the metal insulating film 27b, and the second silicon oxide film 27c, which are part of the passivation film 27 to be formed later, are also formed at the same time. The That is, the passivation film 27 includes the same structure as the gate insulating film 24.

  At this time, an insulating film 26 made of the fourth insulating film is formed on the second silicon oxide film 24c. The insulating film 26 is formed so as to cover the surface of the gate electrode 25, and is formed with the same width as the gate insulating film 24 immediately above the gate insulating film 24. That is, the width of the gate electrode 25 in the gate length direction is narrower than the width of the gate insulating film 24 in the same direction. As a result, the gate electrode 25 is formed via the gate insulating film 24 immediately above the region between the two p-type base regions 21 in the active region.

Thereafter, a back electrode (drain electrode) 7 is formed on the back surface of the n ⁺ -type substrate 1 by using a sputtering method or the like, and then a metal film is formed on the entire surface of the n ⁻ -type drift layer 2. By patterning, the surface electrode 8 electrically connected to the n ⁺ type source region 22 and the p ⁺ type contact region 23 and the floating electrode 9 electrically connected to the n ⁺ type field stop region 5 are formed. Thereby, the MOSFET and termination structure shown in FIG. 13 are completed. Note that the p-type guard ring region 3 and the p-type JTE region 4 need not have the same depth. Further, the p-type JTE region 4 does not have to be a single region, and may be formed of a plurality of regions. Further, the formation order of the p-type guard ring region 3, the p-type JTE region 4, the n ⁺ -type field stop region 5, the p-type base region 21, the n ⁺ -type source region 22, and the p ⁺ -type contact region 23 is as described above. Need not be.

  In the semiconductor device having the high breakdown voltage MOSFET (power device) in the active region as described above, the passivation film 27 including the metal insulating film 27b having a film thickness of 0.3 nm to 10 nm is formed as shown in FIG. As a result, the same effect as in the first embodiment can be obtained. Since the gate insulating film 24 is a gate insulating film of a MOSFET, the film thickness cannot be increased more than necessary. Therefore, the film thickness is set to 30 nm to 100 nm. In this case, if the passivation film is constituted only by the first silicon oxide film 27a, the metal insulating film 27b, and the second silicon oxide film 27c constituting the passivation film 27, the film thickness is insufficient and the breakdown voltage is secured. Therefore, the insulating film 27d is provided here to increase the thickness of the insulating film 27d. Specifically, the thickness of the passivation film 27 needs to be several hundred nm to several μm.

  In the present embodiment, aluminum oxide is exemplified as the metal insulating film, but the present invention is not limited to this and may be aluminum nitride or titanium oxide. In the present embodiment, the termination structure is JTE, but the same effect can be obtained even if the termination structure is FLR.

Further, when the first silicon oxide films 24a and 27a are formed, if they are oxynitrided with nitrogen monoxide or dinitrogen monoxide or annealed, the first silicon oxide films 24a and 27a and n made of SiC are formed. N (nitrogen) can be introduced into the first silicon oxide film 24 a and 27 a in the vicinity of the interface with the ⁻ type drift layer 2. Thus, reducing the traps at the interface between the n ⁻ type drift layer 2 and the first silicon oxide film 27a made of SiC and the n ⁻ type drift layer 2 and the gate insulating film 24 is effective for the passivation film charge. This is effective for suppressing the fluctuation of the MOSFET and for reducing the on-resistance of the MOSFET. This is because the mobility of carriers in the channel can be improved by reducing traps.

  Although the invention made by the present inventors has been specifically described based on the embodiment, the present invention is not limited to the embodiment, and various modifications can be made without departing from the scope of the invention. Needless to say.

  The present invention is effective when applied to a manufacturing technique of a semiconductor device including a SiC substrate.

1 n ⁺ type substrate 2 n ⁻ type drift layer 3 p type guard ring region 4 p type JTE region 4a p type semiconductor region 5 n ⁺ type field stop region 6 passivation film 6a first silicon oxide film 6b metal insulating film 6c second Silicon oxide film 6d Silicon nitride film 6e Silicon nitride film 7 Back electrode 8 Front electrode 9 Floating electrode 11 Passivation film 21 P-type base region 22 n ⁺ -type source region 23 p ⁺ -type contact region 24 Gate insulating film 24a First silicon oxide film 24b Metal insulating film 24c Second silicon oxide film 25 Gate electrode 26 Insulating film 27 Passivation film 27a First silicon oxide film 27b Metal insulating film 27c Second silicon oxide film 27d Insulating films M1 to M4 Mask

Claims (17)

A semiconductor substrate comprising silicon carbide having a first conductivity type;
A drift layer formed on the semiconductor substrate, having the first conductivity type, having a lower impurity concentration than the semiconductor substrate and containing silicon carbide;
A semiconductor region having a second conductivity type different from the first conductivity type formed on an upper surface in the drift layer;
A passivation film formed on the drift layer;
An electrode formed on the drift layer;
A back electrode formed in contact with the back surface of the drift layer;
Including
The passivation film is
A first insulating film formed in contact with the upper surface of the drift layer;
A metal insulating film formed on the first insulating film;
A second insulating film formed on the metal insulating film;
Have
The semiconductor device is characterized in that the metal insulating film has a thickness in a range of 0.3 nm to 10 nm.   The semiconductor device according to claim 1, wherein the metal insulating film contains aluminum oxide.   The semiconductor device according to claim 1, wherein the metal insulating film includes aluminum nitride.   The semiconductor device according to claim 1, wherein the metal insulating film contains titanium oxide.   The semiconductor device according to claim 1, wherein the metal insulating film has a thickness of 5 nm or less.   The semiconductor device according to claim 1, wherein the metal insulating film has a thickness of 1 nm or less.   The semiconductor device according to claim 1, wherein the first insulating film and the second insulating film contain silicon oxide.   2. The semiconductor device according to claim 1, wherein nitrogen is introduced into the first insulating film in the vicinity of the interface between the first insulating film and the drift layer. A base region formed on an upper surface of the drift layer and having the second conductivity type;
A source region formed on an upper surface of the base region, having the first conductivity type and having an impurity concentration higher than that of the drift layer;
A contact region formed on an upper surface of the base region, having the second conductivity type and having a higher impurity concentration than the base region;
A gate electrode formed directly over the drift layer and the base region via a gate insulating film;
Have
The electrode is electrically connected to the source region and the contact region;
The gate insulating film is
A third insulating film formed in contact with the upper surface of the drift layer;
A metal insulating film formed on the third insulating film;
A fourth insulating film formed on the metal insulating film;
Have
The thickness of the metal insulating film is in the range of 0.3 nm to 10 nm,
The gate insulating film has a thickness in the range of 30 to 100 nm,
The semiconductor device according to claim 1, wherein the passivation film includes the same structure as the gate insulating film.   The semiconductor device according to claim 9, wherein the passivation film includes a fifth insulating film formed on the second insulating film.   10. The semiconductor device according to claim 9, wherein nitrogen is introduced into the third insulating film in the vicinity of the interface between the third insulating film and the drift layer.   The semiconductor device according to claim 9, wherein the third insulating film and the fourth insulating film contain silicon oxide. A semiconductor substrate comprising silicon carbide having a first conductivity type;
A drift layer formed on the semiconductor substrate, having the first conductivity type, having a lower impurity concentration than the semiconductor substrate and containing silicon carbide;
A semiconductor region having a second conductivity type different from the first conductivity type formed on an upper surface in the drift layer;
A passivation film formed on the drift layer;
An electrode formed on the drift layer;
A back electrode formed in contact with the back surface of the drift layer;
Including
The passivation film is
A first insulating film formed in contact with the upper surface of the drift layer;
A first nitride film, a metal insulating film, a second nitride film, and a second insulating film, which are sequentially stacked on the first insulating film;
Have
The metal insulating film has a thickness of 0.3 nm or more,
The sum of the film thicknesses of the first nitride film, the metal insulating film, and the second nitride film is 10 nm or less.   The semiconductor device according to claim 13, wherein the metal insulating film contains aluminum oxide.   The semiconductor device according to claim 13, wherein the metal insulating film includes aluminum nitride.   The semiconductor device according to claim 13, wherein the metal insulating film contains titanium oxide.   The semiconductor device according to claim 13, wherein nitrogen is introduced into the first insulating film in the vicinity of the interface between the first insulating film and the drift layer.

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