Abstract:
A diode has a semiconductor layer and cathode and anode electrodes on a surface of the semiconductor layer. The semiconductor layer has cathode and anode regions respectively contacting the cathode and anode electrodes. The anode region has a first diffusion region having high surface concentration, a second diffusion region having intermediate surface concentration, and a third diffusion region having low surface concentration. The first diffusion region is covered with the second and third diffusion regions. The second diffusion region has a first side surface facing the cathode region, a second side surface opposite to the cathode region, and a bottom surface extending between the first and second side surfaces. The third diffusion region covers at least one of the first corner part connecting the first side surface with the bottom surface and the second corner part connecting the second side surface with the bottom surface.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is based on Japanese Patent Application No. 2010-256107 filed on Nov. 16, 2010, and No. 2011-224879 filed on Oct. 12, 2011, the disclosures of which are incorporated herein by reference. 
       TECHNICAL FIELD 
       [0002]    The present invention relates to a diode. 
       BACKGROUND 
       [0003]    Development of a high-voltage IC obtained by integrating a plurality of kinds of semiconductor devices on an SOI (Silicon on Insulator) substrate using the insulating/isolating technique is being advanced. A diode is mounted on such a high-voltage IC. A diode formed in such an SOI substrate is often constructed as a lateral diode. Each of patent literatures 1 and 2 discloses an example of the lateral diode. 
         [0004]    A lateral diode has an n-type cathode region, a p-type anode region, and an n-type drift region partitioning between the cathode region and the anode region. The anode region has a first diffusion region of high concentration and a second diffusion region covering the high-concentration first diffusion region and having impurity concentration lower than that of the first diffusion region. The anode region is often constructed by two kinds of diffusion regions. Generally, the impurity concentration and diffusion depth of the first diffusion region of high concentration are set to make electric connection to an anode electrode excellent and adjust an injection amount of holes at the time of forward bias. The impurity concentration and diffusion depth of the second diffusion region covering the first diffusion region are set to adjust the injection amount of holes at the time of forward bias together with the first diffusion region and reduce concentration of holes flowing toward the first diffusion region at the time of reverse recovery. 
         [0005]    For example, when the impurity concentration of the second diffusion region covering the first diffusion region of high concentration is high, although on resistance at the time of forward bias decreases, the amount of holes injected to the drift region increases, a reverse recovery charge amount increases, and switching loss increases. On the other hand, when the impurity concentration of the second diffusion region is low, although the amount of holes injected to the drift region decreases and switching loss decreases, the on resistance at the time of forward bias increases. Consequently, the impurity concentration of the second diffusion region is preferably set to a certain level of concentration. When the diffusion of the second diffusion region is deep, although the on resistance at the time of forward bias decreases, the amount of holes injected to the drift region increases, a reverse recovery charge amount increases, and switching loss increases. On the other hand, when the diffusion of the second diffusion region is shallow, although the amount of holes injected to the drift region decreases and switching loss decreases, the on resistance at the time of forward bias increases. Consequently, the diffusion depth of the second diffusion region is also preferably set to some degree of depth.
   [Patent literature 1]: Japanese Unexamined Patent Application Publication No. H11-233795 (corresponding to U.S. Pat. No. 5,982,015)   [Patent literature 2]: Japanese Unexamined Patent Application Publication No. 2006-270034   
 
         [0008]    As described above, in the anode region constructed by the two kinds of diffusion regions, the second diffusion region defining the contour of the anode region is constructed with the certain level of impurity concentration and the some degree of diffusion depth. Consequently, a corner part having a certain curvature is formed in the anode region. A high electric field is applied to the corner part in the anode region at the time of reverse recovery and holes in reverse recovery current flow. Due to this, at the time of reverse recovery, a dynamic avalanche phenomenon occurs around the corner part, and the carrier amount at the time of reverse recovery increases. As a result, the reverse recovery charge amount increases, and the switching loss increases. 
       SUMMARY 
       [0009]    In view of the above-described problem, it is an object of the present disclosure to provide a lateral diode having an excellent reverse recovery characteristic. 
         [0010]    According to an aspect of the disclosure, a diode includes: a semiconductor layer; a cathode electrode arranged on a surface of the semiconductor layer; and an anode electrode arranged on the surface of the semiconductor layer and apart from the cathode electrode. The semiconductor layer has a cathode region having a first conduction type and an anode region having a second conduction type. The cathode region is arranged in a surface part of the semiconductor layer and is in contact with the cathode electrode. The anode region is arranged in another surface part of the semiconductor layer and is in contact with the anode electrode. The anode region has a first diffusion region having first surface concentration, a second diffusion region having second surface concentration, and a third diffusion region having third surface concentration. The first diffusion region extends to first depth from the surface of the semiconductor layer. The second diffusion region extends to second depth deeper than the first depth from the surface of the semiconductor layer. The second surface concentration is lower than the first surface concentration. The third diffusion region extends to third depth deeper than the second depth from the surface of the semiconductor layer. The third surface concentration is lower than the second surface concentration. The first diffusion region is covered with the second diffusion region and the third diffusion region. The second diffusion region has a first side surface facing the cathode region, a second side surface opposite to the cathode region, and a bottom surface extending between the first and second side surfaces. The second diffusion region further has a first corner part connecting the first side surface with the bottom surface and a second corner part connecting the second side surface with the bottom surface. The third diffusion region covers at least one of the first and second corner parts. 
         [0011]    In the diode, since the impurity concentration of the third diffusion region is low, even if the third diffusion region is provided, increase in the injection amount of carriers at the time of forward bias is suppressed. On the other hand, since the corner part of the anode region is constructed by the third diffusion region having low impurity concentration, the electric field intensity in the corner part at the time of reverse recovery is lessened, and the dynamic avalanche phenomenon at the time of reverse recovery can be suppressed. Accordingly, increase in the amount of carriers caused by the dynamic avalanche phenomenon at the time of reverse recovery is suppressed, so that the reverse recovery charge amount at the time of reverse recovery is suppressed to be small, and the switching loss decreases. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0012]    The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings: 
           [0013]      FIG. 1  is a cross section of a main part taken along line I-I of  FIG. 2 ; 
           [0014]      FIG. 2  is a plan view of a main part of an SOI substrate in which a diode is formed; 
           [0015]      FIG. 3  shows a modification example of a diode in which the layout of a cathode region is different; 
           [0016]      FIG. 4  shows another modification example of a diode in which the layout of the cathode region is different; 
           [0017]      FIG. 5  is an enlarged cross section of a main part in an anode region; 
           [0018]      FIG. 6  is an enlarged cross section of a main part in a process of manufacturing the anode region; 
           [0019]      FIG. 7  is an enlarged cross section of a main part in the process of manufacturing the anode region; 
           [0020]      FIG. 8  is an enlarged cross section of a main part in the process of manufacturing the anode region; 
           [0021]      FIG. 9  shows the relation between reverse recovery current and voltage of a diode; 
           [0022]      FIG. 10  shows an example of a configuration in which a plurality of diodes are disposed; 
           [0023]      FIG. 11  shows another example of a configuration in which a plurality of diodes are disposed; 
           [0024]      FIG. 12  is a plan view of a main part of a diode as a modification of a first example; 
           [0025]      FIG. 13  is a plan view of a main part of a diode as a second example; 
           [0026]      FIG. 14  is a cross section of a main part of a diode as a modification of the second example; and 
           [0027]      FIG. 15  is a cross section of a main part of a diode as a third example. 
       
    
    
     DETAILED DESCRIPTION 
       [0028]    Characteristics of the technique disclosed in the specification will be summarized. 
         [0029]    A diode is formed on a laminated substrate in which a semiconductor underlayer, a buried insulating layer, and a semiconductor upper layer are stacked. The laminated substrate is an SOI substrate. 
         [0030]    The diode is formed in an island region surrounded by an insulating and isolating trench making a circle in the semiconductor upper layer. 
         [0031]    The anode region in the diode makes a circle around the periphery of the island region along the insulating and isolating trench. The anode region in the diode is in contact with a side surface of the insulating and isolating trench. 
         [0032]    In the anode region in the diode, the high-concentration anode diffusion region is in contact with the low-concentration anode diffusion region. 
         [0033]    In the anode region in the diode, a low-concentration anode diffusion region covering a first corner part on the side of the cathode region and a low-concentration anode diffusion region covering a second corner part on the side opposite to the cathode region are formed. In this case, the diffusion depth of the low-concentration anode diffusion region covering the first corner part is greater than that of the low-concentration anode diffusion region covering the second corner part. 
       First Embodiment 
       [0034]    As illustrated in  FIG. 1 , a lateral diode  1 A is formed in an SOI (Silicon On Insulator) substrate  5  in which an n-type or p-type semiconductor underlayer  2 , a buried insulating layer  3 , and an n − -type semiconductor upper layer  4  are stacked. As illustrated in  FIG. 2 , the diode  1 A is formed in an island region of the semiconductor upper layer  4  surrounded by an insulating and isolating trench  8 . In  FIG. 2 , electrodes and the like on the SOI substrate are not shown. The insulating and isolating trench  8  penetrates the semiconductor upper layer  4  from the surface of the semiconductor upper layer  4  and reaches the buried insulating layer  3 , and makes a circle in the semiconductor upper layer  4  in plan view. In an example, single-crystal silicon is used as the material of the semiconductor underlayer  2  and the semiconductor upper layer  4 , and silicon oxide is used as the material of the buried insulating layer  3 . To realize withstand voltage of 500V or higher, the thickness of the buried insulating layer  3  is set to about 3 μm or larger. To realize withstand voltage of 500V or higher, the impurity concentration of the semiconductor upper layer  4  is about 7×10 14  cm −3  and the thickness is about 10 to 20 μm. 
         [0035]    As illustrated in  FIG. 1 , the diode  1 A has a cathode electrode  6 , an anode electrode  7 , a LOCOS oxide film  32 , and resistive field plates  34  provided on the surface of the semiconductor upper layer  4 . The cathode electrode  6  and the anode electrode  7  are disposed with a distance therebetween in the surface of the semiconductor upper layer  4  and are electrically insulated from each other. As the cathode electrode  6  and the anode electrode  7 , a laminated electrode made of titanium (Ti)/titanium nitride (TiN)/aluminum (Al) is used. Titanium is in contact with the semiconductor upper layer  4 . In the titanium part, as necessary, silicide obtained by mixing silicon in titanium may be used. The LOCOS oxide film  32  is provided between the cathode electrode  6  and the anode electrode  7 . The resistive field plate  34  is provided on the surface of the LOCOS oxide film  32 . One end of the resistive field plate  34  is electrically connected to the cathode electrode  6 , and the other end is electrically connected to the anode electrode  7 . The LOCOS oxide film  32  and the resistive field plates  34  uniformize the potential distribution between the cathode electrode  6  and the anode electrode  7  in the surface layer part of the semiconductor upper layer  4 . 
         [0036]    In the surface layer part of the semiconductor upper layer  4 , an n-type cathode region  10  and a p-type anode region  20  are formed. The cathode region  10  is in contact with the cathode electrode  6 . The anode region  20  is in contact with the anode electrode  7 . Between the cathode region  10  and the anode region  20 , a drift region  30  is formed. The drift region  30  is a residual part after forming the cathode region  10  and the anode region  20  in the semiconductor upper layer  4 . In the drift region  30 , as necessary, a semiconductor region for higher withstand voltage (for example, a RESURF region) may be formed. 
         [0037]    The cathode region  10  has an n + -type high-concentration cathode diffusion region  10   a  and an n-type low-concentration cathode diffusion region  10   b . The diffusion depth of the low-concentration cathode diffusion region  10   b  is greater than that of the high-concentration cathode diffusion region  10   a . Consequently, the entire high-concentration cathode diffusion region  10   a  is covered with the low-concentration cathode diffusion region  10   b . As necessary, the low-concentration cathode diffusion region  10   b  may not be provided. As shown in  FIG. 2 , the cathode region  10  is disposed in a center of the island region surrounded by the insulating and isolating trench  8  and has an almost rectangular shape. The high-concentration cathode diffusion region  10   a  is divided in a plurality of pieces, and a p + -type contact adjustment region  10   c  is formed between the neighboring high-concentration cathode diffusion regions  10   a . As described above, the high-concentration cathode diffusion region  10   a  and the contact adjustment region  10   c  are repeatedly formed along the longitudinal direction of the cathode region  10 . The contact adjustment regions  10   c  are formed to reduce the contact area between the cathode region  10  and the cathode electrode  6  and adjust the amount of electrons injected at the time of forward bias. The high-concentration cathode diffusion region  10   a  and the contact adjustment region  10   c  are in ohmic-contact with the cathode electrode  6 , and the low-concentration cathode diffusion region  10   b  is in ohmic-contact with the cathode electrode  6 . In an example, the surface concentration of the high-concentration cathode diffusion region  10   a  is about 6×10 20  cm −3  and the diffusion depth is about 0.1 to 0.5 μm. The surface concentration of the low-concentration cathode diffusion region  10   b  is about 1.8×10 17  cm −3  and the diffusion depth is about 3 to 7 μm. The surface concentration of the contact adjustment region  10   c  is about 1×10 20  cm −3  and the diffusion depth is about 0.3 to 0.6 μm. As illustrated in  FIG. 3 , the contact adjustment region  10   c  may not be provided as necessary. As illustrated in  FIG. 4 , the low-concentration cathode diffusion region  10   b  may be interposed between the repetitive structure of the high-concentration cathode diffusion region  10   a  and the contact adjustment region  10   c . Those layouts are examples and various layouts can be employed as combinations of the high-concentration cathode diffusion region  10   a , the low-concentration cathode diffusion region  10   b , and the contact adjustment region  10   c.    
         [0038]      FIG. 5  is an enlarged cross section of the anode region  20 . The anode region  20  has a p + -type high-concentration anode diffusion region  20   a , a p-type intermediate-concentration anode diffusion region  20   b , and a p − -type low-concentration anode diffusion region  20   c . The diffusion depth of the intermediate-concentration anode diffusion region  20   b  is greater than that of the high-concentration anode diffusion region  20   a . The diffusion depth of the low-concentration anode diffusion region  20   c  is greater than that of the high-concentration anode diffusion region  20   a  and the intermediate-concentration anode diffusion region  20   b . The high-concentration anode diffusion region  20   a  is in ohmic-contact with the anode electrode  7 , and the intermediate-concentration anode diffusion region  20   b  and the low-concentration anode diffusion region  20   c  are in Schottky-contact with the anode electrode  7 . As shown in  FIG. 2 , the high-concentration anode diffusion region  20   a , the intermediate-concentration anode diffusion region  20   b , and the low-concentration anode diffusion region  20   c  make a circle along the insulating and isolating trench  8  around the island region in plan view. As necessary, only linear parts of the high-concentration anode diffusion region  20   a  may be provided (that is, the corner parts of the high-concentration anode diffusion region  20   a  are not provided). 
         [0039]    As illustrated in  FIG. 5 , the high-concentration anode diffusion region  20   a  is covered with the intermediate-concentration anode diffusion region  20   b  and the low-concentration anode diffusion region  20   c . The intermediate-concentration anode diffusion region  20   b  has a first side surface  20 A on the side of the cathode region  10 , a second side surface  20 E on the side opposite to the cathode region  10 , and a bottom surface  20 C extending between the first side surface  20 A and the second side surface  20 E. Between the first side surface  20 A and the bottom surface  20 C, a first corner part  20 B exists. Between the second side surface  20 E and the bottom surface  20 C, a second corner part  20 D exists. 
         [0040]    The low-concentration anode diffusion region  20   c  covers the second corner part  20 D of the intermediate-concentration anode diffusion region  20   b . A part of the bottom surface  20 C of the intermediate-concentration anode diffusion region  20   b  is not covered with the low-concentration anode diffusion region  20   c . The low-concentration anode diffusion region  20   c  is in contact with the side surface of the insulating and isolating trench  8 . The surface concentration of the high-concentration anode diffusion region  20   a , that of the intermediate-concentration anode diffusion region  20   b , and that of the low-concentration anode diffusion region  20   c  are desirably different almost every two digits. In an example, the surface concentration of the high-concentration anode diffusion region  20   a  is about 1×10 20  cm −3  and the diffusion depth is about 0.2 to 0.6 μm. The surface concentration of the intermediate-concentration anode diffusion region  20   b  is about 9×10 17  cm −3  and the diffusion depth is about 1 to 2 μm. The surface concentration of the low-concentration anode diffusion region  20   c  is about 1.2×10 16  cm −3  and the diffusion depth is about 3 to 5 μm. 
         [0041]    In an example, using the manufacturing processes shown in  FIGS. 6 to 8 , the anode region  20  can be formed. First, as shown in  FIG. 6 , a resist  42  having an opening corresponding to the low-concentration anode diffusion region  20   c  is patterned on the surface of the semiconductor upper layer  4 . Next, using the ion injection technique, boron is injected to the surface layer part of the semiconductor upper layer  4  via the opening. The process of forming the low-concentration anode diffusion region  20   c  can also be used as, for example, a process of forming a well region for a MOSFET formed in another region in the SOI substrate  5 . Next, the resist  42  is removed and, after that, using the heat treatment technique, the injected boron is diffused and activated to form the low-concentration anode diffusion region  20   c.    
         [0042]    Next, as illustrated in  FIG. 7 , a resist  44  having an opening corresponding to the intermediate-concentration anode diffusion region  20   b  is patterned on the surface of the semiconductor upper layer  4 . Next, using the ion injection technique, boron is injected to the surface layer part of the semiconductor upper layer  4  via the opening. The process of forming the intermediate-concentration anode diffusion region  20   b  can also be used as, for example, a process of forming a body region for a MOSFET or IGBT formed in another region in the SOI substrate  5 . Next, the resist  44  is removed and, after that, using the heat treatment technique, the injected boron is diffused and activated to form the intermediate-concentration anode diffusion region  20   b.    
         [0043]    Next, as illustrated in  FIG. 8 , a resist  46  having an opening corresponding to the high-concentration anode diffusion region  20   a  is patterned on the surface of the semiconductor upper layer  4 . Next, using the ion injection technique, boron is injected to the surface layer part of the semiconductor upper layer  4  via the opening. The process of forming the high-concentration anode diffusion region  20   a  can also be used as, for example, a process of forming a body contact region for a MOSFET or IGBT formed in another region in the SOI substrate  5 . Next, the resist  46  is removed and, after that, using the heat treatment technique, the injected boron is diffused and activated to form the high-concentration anode diffusion region  20   a.    
         [0044]    The operation of the diode  1 A will now be described. When potential higher than the cathode electrode  6  is applied to the anode electrode  7 , the diode  1 A is forward-biased. Accordingly, electrons are injected from the cathode region  10  to the drift region  30 , and holes are injected from the anode region  20  to the drift region  30 . As a result, in the diode  1 A, current flows from the anode electrode  7  toward the cathode electrode  6 . 
         [0045]    Next, when potential higher than the anode electrode  7  is applied to the cathode electrode  6 , the diode  1 A is reverse-biased. Accordingly, the electrons injected to the drift region  30  at the time of the forward bias are ejected from the cathode region  10  and holes are ejected from the anode region  20 . In such a manner, reverse recovery current flows to the diode  1 A in the period of transition from the forward bias to the reverse bias. Since the reverse recovery charge amount of the reverse recovery current causes a switching loss, it is important to suppress the reverse recovery charge amount. To suppress the reverse recovery charge amount, it is important to decrease the amount of carriers injected at the time of forward bias and, further, suppress the generation amount of carriers caused by the dynamic avalanche phenomenon at the time of reverse recovery. The dynamic avalanche phenomenon denotes that, at the time of reverse recovery, holes flowing in the anode region  20  cause an avalanche phenomenon by high electric field applied to the pn junction between the anode region  20  and the drift region  30 . 
         [0046]    The anode region  20  in the diode  1 A is characterized by being constructed by three diffusion regions  20   a ,  20   b , and  20   c  of different concentrations. Since the impurity concentration of the low-concentration anode diffusion region  20   c  is extremely low, even when the low-concentration anode diffusion region  20   c  is provided, the amount of holes injected at the time of forward bias hardly increases. The amount of holes injected from the anode region  20  is determined by the high-concentration anode diffusion region  20   a  and the intermediate-concentration anode diffusion region  20   b . That is, the amount of holes injected at the time of forward bias in the diode  1 A is equivalent to that in the conventional structure. 
         [0047]    On the other hand, since the low-concentration anode diffusion region  20   c  is provided, the field intensity of the second corner part  20 D at the time of the reverse recovery decreases conspicuously. Therefore, the dynamic avalanche phenomenon which occurs around the second corner part  20 D is suppressed.  FIG. 9  shows reverse recovery current in the diode  1 A and the voltage applied across the cathode electrode  6  and the anode electrode  7  at that time. The solid lines indicate the case of the diode  1 A of the embodiment, and broken lines indicate a result of a comparative example of the case where the low-concentration anode diffusion region  20   c  is not provided (the case where the anode region  20  is constructed only of the high-concentration anode diffusion region  20   a  and the intermediate-concentration anode diffusion region  20   b ). As shown in  FIG. 9 , in the comparative example, two peak waveforms appear in the reverse recovery current. Particularly, it is recognized that, at the peak in the latter half, the electric field is concentrated around the second corner part  20 D, and the density of Hall current accompanying the dynamic avalanche phenomenon is recognized. On the other hand, in the embodiment, the two peak waveforms do not appear. In other words, in the embodiment, it can also be evaluated that the peak waveform in the latter half disappears. In the embodiment, it is confirmed that the electric field concentration around the second corner part  20 D is lessened, and the density of Hall current accompanying the dynamic avalanche phenomenon decreases conspicuously. As a result, in the embodiment, it is understood that the reverse recovery charge amount decreases. As described above, the diode  1 A of the embodiment has the reverse recovery characteristics that the reverse recovery charge amount is small and the switching loss is small. 
         [0048]    The diode  1 A has the following characteristics. 
         [0049]    (1) As illustrated in  FIG. 1 , the low-concentration anode diffusion region  20   c  of the anode region  20  is in contact with the side face of the insulating and isolating trench  8 . Due to this, a current path using the surface recombination effect in the interface between the low-concentration anode diffusion region  20   c  and the insulating and isolating trench  8  is formed. Consequently, at the time of reverse recovery, a part of reverse recovery current flows in the current path formed in the interface. As a result, the concentration of the reverse recovery current is lessened, so that occurrence of the dynamic avalanche phenomenon is suppressed. 
         [0050]    (2) As the material of the cathode electrode  6  and the anode electrode  7  of the diode  1 A of the embodiment, titanium is used. Consequently, in the anode region  20 , the high-concentration anode diffusion region  20   a  and the anode electrode  7  are in ohmic contact with each other, and the intermediate-concentration anode diffusion region  20   b  and the anode electrode  7  are in Schottky contact with each other. Due to this, at the time of the forward bias, the amount of holes injected from the anode region  20  can be suppressed. By lowering the impurity concentration of the intermediate-concentration anode diffusion region  20   b , current concentration at the time of the reverse recovery can be suppressed. Further, by forming the low-concentration anode diffusion region  20   c  so that diffusion is deep, occurrence of carriers caused by the dynamic avalanche phenomenon by application of reverse bias after the ejection of holes can be suppressed. To realize Schottky contact between the intermediate-concentration anode diffusion region  20   b  and the anode electrode  7 , it is sufficient that the work function of the material used for the anode electrode  7  is 5.16 eV or less. Consequently, as the material of the anode electrode  7 , nickel, copper, or the like may be used in place of titanium. 
         [0051]    (3) As illustrated in  FIG. 5 , in the diode  1 A, the high-concentration anode diffusion region  20   a  is provided so as to be biased to the side opposite to the cathode region  10  in the intermediate-concentration anode diffusion region  20   b  so that the high-concentration anode diffusion region  20   a  is in contact with the low-concentration anode diffusion region  20   c . With the configuration, the current path at the time of forward bias extends in the anode region  20 , so that a wide range of the drift region  30  can be used as the current path, and the on resistance can be decreased. Since the current path at the time of reverse bias also extends in the anode region  20 , occurrence of the dynamic avalanche phenomenon can also be suppressed. 
         [0052]    (4) As illustrated in  FIG. 5 , in the diode  1 A, a part of the bottom surface  20 C of the intermediate-concentration anode diffusion region  20   b  is not covered with the low-concentration anode diffusion region  20   c . For example, even if the low-concentration anode diffusion region  20   c  is formed so as to completely cover the intermediate-concentration anode diffusion region  20   b , it is advantageous from the viewpoint that the dynamic avalanche phenomenon in the corner parts  20 B and  20 D in the intermediate-concentration anode diffusion region  20   b  can be suppressed. However, if such a large low-concentration anode diffusion region  20   c  is provided, even if the impurity concentration is adjusted to be low, the injection amount of holes at the time of forward bias may increase. By selectively covering only the corner part of the intermediate-concentration anode diffusion region  20   b  with the low-concentration anode diffusion region  20   c  like in the diode  1  of the embodiment, occurrence of the dynamic avalanche phenomenon can be effectively suppressed without enlarging the formation range of the low-concentration anode diffusion region  20   c.    
         [0053]    (5) Each of  FIGS. 10 and 11  shows an example in which a plurality of diodes  1 A are arranged on the SOI substrate  5 . Although each of  FIGS. 10 and 11  shows an example where two diodes  1 A are mounted, the present invention is not limited to the example but more than two diodes  1 A may be arranged on the SOI substrate  5 . In the example of  FIG. 10 , the track-shaped insulating and isolating trenches  8  of the diodes  1 A are coupled to form a single island region. In a coupling part  50 , a p-type intermediate-concentration coupling diffusion region  52  and a p − -type low-concentration coupling diffusion region  54  are formed. The intermediate-concentration coupling diffusion region  52  is formed by the process common to that of the intermediate-concentration anode diffusion region  20   b  and has the same concentration profile as that of the intermediate-concentration anode diffusion region  20   b . The intermediate-concentration coupling diffusion region  52  may not be provided as necessary. The low-concentration coupling diffusion region  54  is formed by the process common to that of the low-concentration anode diffusion region  20   c  and has the same concentration profile as that of the low-concentration anode diffusion region  20   c . The low-concentration coupling diffusion region  54  is formed in contact with the insulating and isolating trench  8  and covers the corner parts of the intermediate-concentration coupling diffusion region  52 . In the example, also in the coupling part, the electric field concentration is lessened. In the example of  FIG. 11 , a single island region is formed by a rectangular insulating and isolating trench  8 . In the example, the intermediate-concentration anode diffusion region  20   b  is formed widely in the outer range of the track-shaped diode. The low-concentration anode diffusion region  20   c  is formed in contact with the insulating and isolating trench  8  and covers the corner parts of the intermediate-concentration coupling diffusion region  52 . Also in the example, the electric field concentration in the corner parts of the intermediate-concentration anode diffusion region  20   b  is lessened. 
         [0054]    (6)  FIG. 12  illustrates a diode  1 B as a modification of the embodiment. In the diode  1 B as the modification, a low-concentration anode diffusion region  20   d  is formed so as to cover the first corner part  20 B of the intermediate-concentration anode diffusion region  20   b . With the configuration, both of the first corner part  20 B and the second corner part  20 D of the intermediate-concentration anode diffusion region  20   b  are covered with the low-concentration anode diffusion regions  20   c  and  20   d , so that the dynamic avalanche phenomenon in both of the first corner part  20 B and the second corner part  20 D is suppressed. Desirably, the diffusion depth of the low-concentration anode diffusion region  20   d  covering the first corner part  20 B is greater than that of the low-concentration anode diffusion region  20   c  covering the second corner part  20 D. The low-concentration anode diffusion region  20   d  covering the first corner part  20 B may be in contact with the buried insulating layer  3 . The deeper the diffusion of the low-concentration anode diffusion region  20   d  covering the first corner part  20 B is, the more the reverse recovery charge amount is decreased. 
       Second Embodiment 
       [0055]      FIG. 13  shows a diode  1 C formed by using an epitaxial substrate  15 . The epitaxial substrate  15  is formed by epitaxially growing the semiconductor upper layer  4  on a p − -type semiconductor underlayer  12 . A pn junction is formed between the semiconductor underlayer  12  and the semiconductor upper layer  4 . The semiconductor underlayer  12  is fixed to the ground voltage. Also in the example, the device is isolated by using the insulating and isolating trench  8 . Like in a diode  1 D shown in  FIG. 14 , the device may be isolated by using a p + -type diffusion isolation region  18  in place of the insulating and isolating trench  8 . The technique disclosed in the specification can also be used for the diodes  1 C and  1 D formed by using the epitaxial substrate  15 . 
       Third Embodiment 
       [0056]      FIG. 15  shows a diode  1 E formed by using a polysilicon substrate  25 . The polysilicon substrate  25  is formed by forming a trench in the surface part of a polysilicon layer  22 , anodizing the inner surface of the trench to form a dielectric film  28  of silicon oxide and, subsequently, filling the trench with a single-crystal silicon layer  24 . The polysilicon layer  22  is fixed to the ground voltage. In this example, the device is isolated by using the dielectric film  28 . The technique disclosed in the specification is useful also to the diode  1 E formed by using the polysilicon substrate  25 . 
         [0057]    For example, although silicon is used as the semiconductor material in the embodiment, a wide-gap semiconductor may be used in place of silicon. 
         [0058]    The technical elements described in the specification or drawings display technical utility singularly or in various combinations and are not limited to the combinations described in the claims in the application. The technique in the specification or drawings can achieve a plurality of purposes at the same time and has the technical utility by achieving one of the purposes. 
         [0059]    While the invention has been described with reference to preferred embodiments thereof, it is to be understood that the invention is not limited to the preferred embodiments and constructions. The invention is intended to cover various modification and equivalent arrangements. In addition, while the various combinations and configurations, which are preferred, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the invention.