WO2012049872A1 - 半導体装置およびその製造方法 - Google Patents
半導体装置およびその製造方法 Download PDFInfo
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- WO2012049872A1 WO2012049872A1 PCT/JP2011/059397 JP2011059397W WO2012049872A1 WO 2012049872 A1 WO2012049872 A1 WO 2012049872A1 JP 2011059397 W JP2011059397 W JP 2011059397W WO 2012049872 A1 WO2012049872 A1 WO 2012049872A1
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- resurf layer
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- H01L29/66—Types of semiconductor device ; Multistep manufacturing processes therefor
- H01L29/86—Types of semiconductor device ; Multistep manufacturing processes therefor controllable only by variation of the electric current supplied, or only the electric potential applied, to one or more of the electrodes carrying the current to be rectified, amplified, oscillated or switched
- H01L29/861—Diodes
- H01L29/872—Schottky diodes
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L29/00—Semiconductor devices specially adapted for rectifying, amplifying, oscillating or switching and having potential barriers; Capacitors or resistors having potential barriers, e.g. a PN-junction depletion layer or carrier concentration layer; Details of semiconductor bodies or of electrodes thereof ; Multistep manufacturing processes therefor
- H01L29/02—Semiconductor bodies ; Multistep manufacturing processes therefor
- H01L29/12—Semiconductor bodies ; Multistep manufacturing processes therefor characterised by the materials of which they are formed
- H01L29/16—Semiconductor bodies ; Multistep manufacturing processes therefor characterised by the materials of which they are formed including, apart from doping materials or other impurities, only elements of Group IV of the Periodic Table
- H01L29/1608—Silicon carbide
Definitions
- the present invention relates to a semiconductor device, and mainly relates to a power semiconductor device having a withstand voltage of kilovolts or more.
- MOSFETs Metal-Oxide-Semiconductor Field-Effect-Transistors
- IGBTs Insulated Gate-Bipolar-Transistors
- the breakdown voltage of the semiconductor device includes the reverse breakdown voltage of the diode and the off breakdown voltage of the transistor. In either case, this is the breakdown voltage when not functioning as an active element, and the breakdown voltage is maintained by the depletion layer extending in the semiconductor. .
- the breakdown voltage of a semiconductor device having no termination region in the active region is not only insufficient in the depletion layer spreading, but also geometrically at the depletion layer boundary (usually in a columnar shape) on the active region side. Since the electric field concentrates due to the effect, only a low breakdown voltage can be obtained. Therefore, adjacent to the edge of the active region, an injection layer having a conductivity type opposite to that of the semiconductor substrate is formed, so that the depletion layer is expanded, the electric field concentration at the edge of the active region is reduced, and the breakdown voltage of the semiconductor device is increased. Adopting a configuration that enhances A configuration for increasing the breakdown voltage provided outside the active region is referred to as a termination region.
- the breakdown voltage of a PN junction composed of an N-type semiconductor substrate and a high-concentration P-type injection layer is reduced by the concentration of an electric field at the cylindrical junction at the edge of the high-concentration P-type injection layer. Therefore, when a low-concentration P-type injection layer is formed adjacent to the edge of the high-concentration P-type injection layer, the depletion layer extends to both the N-type semiconductor substrate (drift layer) and the low-concentration P-type injection layer.
- the breakdown voltage can be increased.
- This low concentration P-type injection layer is generally called a RESURF (Reduced Surface Surface) layer or JTE (Junction Termination Extension). Such a structure of the termination region is called a RESURF structure.
- the optimum injection condition (injection condition for obtaining the highest breakdown voltage) of the RESURF layer is defined not by the concentration but by the injection amount (dose amount).
- the optimum injection amount (injection surface density) is about 1 ⁇ 10 12 cm ⁇ 2 in the Si (silicon) substrate regardless of the drift layer concentration. It is approximately 1 ⁇ 10 13 cm ⁇ 2 (when the activation rate is 100%) with a 4H SiC (silicon carbide) substrate. These are called resurf conditions.
- a disadvantage of the RESURF structure is that the electric field at the outermost periphery of the RESURF layer has to be strong in order to obtain high pressure resistance.
- the increase in breakdown voltage is limited to breakdown (dielectric breakdown) at the outermost periphery of the RESURF layer, and the risk of thermal breakdown and flashover due to short-circuit current at the time of breakdown increases.
- Such electric field concentration at the outermost periphery of the RESURF layer is mainly caused by a bias of space charge in the depletion layer.
- the vector sum of the electric field from the space charge of the RESURF layer (negative acceptor ion for P type) and the space charge of the drift layer (positive donor ion for N type) is well offset. It is caused by not.
- the depth of the depletion layer in the drift layer gradually decreases from the active region toward the outside of the RESURF layer. Therefore, if the injection amount of the RESURF layer is gradually decreased outward as in Non-Patent Document 1, electric field concentration in the RESURF layer can be avoided.
- Non-Patent Document 1 the method of injecting impurities using a mask with a changed aperture ratio and making the concentration uniform by thermal diffusion to form a RESURF layer has a mask pattern finer than the thermal diffusion length of the impurities. Therefore, it is not applicable when a thick resist mask is required, such as MeV (Mega-Electron-Volt) ion implantation. Further, it cannot be used for a semiconductor material such as SiC in which the thermal diffusion of impurities is very small.
- MeV Micro-Electron-Volt
- the electric field concentration in the RESURF layer is further relaxed by increasing the gradation of the RESURF layer injection amount. be able to.
- the number of times of the photoengraving process and the impurity implantation process for mask formation increases by the same as the gradation of the implantation amount is increased.
- the present invention has been made to solve the above-described problems, and has a resurf structure capable of increasing the gradation of the resurf layer implantation amount while suppressing the number of photolithography processes and impurity implantation processes.
- An object is to provide a semiconductor device.
- An aspect of a semiconductor device is an active region formed in the surface of a semiconductor layer of a first conductivity type, and disposed so as to surround the active region from the edge of the active region toward the outside.
- the plurality of electric field relaxation layers have a first electric field relaxation layer in which the entire region has a first surface density and is implanted with a second conductivity type impurity, and the entire region has a second surface density and a second conductivity type.
- 1 is disposed between the first electric field relaxation layer and the second electric field relaxation layer, and an average surface density of the third electric field relaxation layer is between the first surface density and the second surface density. It becomes the value of.
- the plurality of electric field relaxation layers are implanted with the second conductivity type impurity at a first surface density that is narrower in the planar direction than the first electric field relaxation layer.
- a plurality of first small regions and a plurality of second small regions that are narrower in the planar direction than the second electric field relaxation layer and in which the second conductivity type impurity is implanted at the second surface density are alternately arranged. It has the 3rd electric field relaxation layer arrange
- the formation of the third electric field relaxation layer can also be used as the first and second electric field relaxation layer forming processes, and no dedicated photoengraving process or impurity implantation process is required.
- the effective gradation of the injection amount of the RESURF layer can be increased while suppressing the increase in the number of times. As a result, a semiconductor device having high breakdown voltage and high reliability can be obtained at low cost.
- FIG. 1 is a plan view showing a configuration of a diode 100 when the present invention is applied to a diode
- FIG. 2 is a cross-sectional view showing a cross section taken along line AA in FIG.
- the diode 100 has an active region formed of an injection layer containing a P-type impurity at a relatively high concentration in the surface of the semiconductor substrate 1 containing an N-type impurity at a relatively low concentration. 2 is formed, and a termination region 3 composed of a plurality of P-type injection layers having different concentrations is formed so as to surround the active region 2.
- An anode electrode 4 is disposed on the active region 2
- a cathode electrode 5 is disposed on the main surface (back surface of the substrate) of the semiconductor substrate 1 opposite to the anode electrode 4.
- the diode 100 functions as a PN junction diode by applying a bias voltage between the anode electrode 4 in contact with the active region 2 and the cathode electrode 5 on the back surface of the substrate.
- Embodiment 1 FIG. The configuration of the termination region and the manufacturing method according to the first embodiment of the present invention will be described with reference to FIGS.
- FIGS. 3 to 5 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as the RESURF layer 101 in FIG. 5 showing the final step.
- FIG. 5 it is composed of a plurality of P-type implanted layers containing P-type impurities at a relatively low concentration so as to be adjacent to an active region (P-type base) 2 containing P-type impurities at a relatively high concentration.
- the RESURF layer 101 is formed.
- a region where the RESURF layer 101 is formed is a termination region.
- the RESURF layer 101 includes a first RESURF layer 11, a second RESURF layer 12, a third RESURF layer 13, a fourth RESURF layer 14, and a fifth RESURF layer arranged so as to surround the P-type base 2 in order from the P-type base 2 side. 15.
- the RESURF layer 101 is composed of a plurality of RESURF layers (electric field relaxation layers), and this is the same in the other embodiments.
- the second RESURF layer 12 includes a small region 11 ′ having the same injection amount as the first RESURF layer 11 and a small region 13 ′ having the same injection amount as the third RESURF layer 13. Yes.
- the fourth RESURF layer 14 includes a small region 13 ′ having the same injection amount as the third RESURF layer 13 and a small region 15 ′ having the same injection amount as the fifth RESURF layer 15. Yes.
- the second RESURF layer 12 can be regarded as having an effective injection amount between the first RESURF layer 11 and the third RESURF layer 13, and the fourth RESURF layer 14 is It can be considered that the injection amount is intermediate between the third RESURF layer 13 and the fifth RESURF layer 15 effectively.
- the injection amount of the first resurf layer 11 is the largest, the injection amount of the third resurf layer 13 is smaller than the injection amount of the first resurf layer 11, and the injection of the fifth resurf layer 15.
- the amount is set to be smaller than the injection amount of the third RESURF layer 13, the effective injection amount of the RESURF layer 101 is gradually reduced toward the outside of the diode 100.
- the electric field concentration at the edge of the active region in the PN junction diode can be reduced.
- a method for forming the RESURF layer 101 will be described with reference to FIGS.
- An implantation mask M1 made of, for example, a resist material is patterned on the main surface on the side where 2 is formed. In the following description, it is assumed that the implantation mask is made of a resist material.
- the implantation mask M1 has a pattern in which portions corresponding to the small regions 11 ′ in the first RESURF layer 11 and the second RESURF layer 12 become openings, and a P-type impurity such as aluminum (Al) from above the implantation mask M1. Are ion-implanted to form a small region 11 ′ in the entire first RESURF layer 11 and the second RESURF layer 12.
- the implantation mask M2 is patterned in the step shown in FIG.
- the implantation mask M2 has a pattern in which portions corresponding to the small regions 13 ′ in the second RESURF layer 12 and the small regions 13 ′ in the third RESURF layer 13 and the fourth RESURF layer 14 become openings, and the implantation mask M2 By ion-implanting a P-type impurity such as Al from above, a small region 13 ′ in the entire third resurf layer 13, the second resurf layer 12, and the fourth resurf layer 14 is formed.
- the implantation mask M3 is patterned in the step shown in FIG.
- the implantation mask M3 has a pattern in which portions corresponding to the small regions 15 ′ in the fifth RESURF layer 15 and the fourth RESURF layer 14 become openings, and P type impurities such as Al are ion-implanted from above the implantation mask M3. Thus, the entire fifth RESURF layer 15 and the small region 15 ′ in the fourth RESURF layer 14 are formed.
- the RESURF layer 101 having an effective five-step implantation amount can be formed by three implantation processes, and the increase in the number of impurity implantation processes can be suppressed and the effective amount of the RESURF layer implantation can be reduced.
- the gradation can be increased. As a result, a semiconductor device having high breakdown voltage and high reliability can be obtained at low cost.
- the averaged injection amount is considered as an effective injection amount. Therefore, it is more effective that the period of alternating arrangement is shorter. That is, assuming a region having one effective implantation amount, the period of alternating arrangement is 1/2 or less with respect to its width (length in the arrangement direction of the layers) (that is, 4 or more). (Including a small area).
- the injection layers are formed without overlap. However, the injection is performed by thinning of the resist mask shielding part due to light diffusion during photolithography, scattering of impurity ions, and the like. Since the width of the layer slightly increases, the possibility that a region that is not injected into the RESURF layer 101 is low is low. Further, if the thermal diffusion length is equal to or greater than the alignment accuracy of the mask, the impurity implanted by the annealing process is thermally diffused, so that the possibility that a region that is not implanted into the RESURF layer 101 is further reduced.
- the RESURF layer is premised on depletion, and what is important is the amount of space charge (that is, the amount of injection). That is, even if mask misalignment occurs, the effect of reducing electric field concentration by the RESURF layer 101 does not change.
- the P-type base 2 and the first RESURF layer 11 are preferably in contact with each other, and in reality, the opening for the first RESURF layer 11 of the implantation mask M1 is preferably overlapped with the P-type base 2. . Even if the overlap amount is large, the depletion layer hardly expands in the P-type base 2 originally, so that no problem occurs.
- the boundary of the other RESURF layer may be overlapped with the adjacent RESURF layer at the mask stage.
- the overlap amount is preferably as small as possible.
- the RESURF layer 101 is formed after the P-type base 2 is formed. However, whichever is the first, the order of forming the injection layers constituting the RESURF layer 101 is also limited. There is no. There is no difference in the effect obtained as long as the RESURF layer 101 shown in FIG.
- the widths of the first to fifth RESURF layers 11 to 15 are all the same. However, these widths may not be equal. These optimum widths are determined by the implantation amount (or effective implantation amount) of each region.
- the depths of the first to fifth RESURF layers 11 to 15 are uniform, but in the three ion implantations described with reference to FIGS. There is no need to align. These optimum depths are determined by the relative depth of the injection layer including the P-type base 2 and the injection profile.
- the averaged injection amount is defined as an effective injection amount (the second RESURF layer 12 and the fourth RESURF layer 14). There may be a portion where there is no region defined by an effective implantation amount between different regions (in FIG. 5, the first RESURF layer 11, the third RESURF layer 13, and the fifth RESURF layer 15).
- the third RESURF layer 13 and the fifth RESURF layer 15 are adjacent to each other, and an area defined by an effective injection amount (the fourth RESURF layer in FIG. 5). 14) is not provided.
- an N-type injection layer (channel stopper) in which N-type impurities extending to the dicing line are implanted at a relatively high concentration may be provided at a spaced position outside the RESURF layer 101.
- a field plate having the same potential as that of the channel stopper may be provided on the semiconductor substrate 1 outside the RESURF layer 101 in order to suppress the extension of the depletion layer composed of the wiring layer and having almost no electric field relaxation effect.
- a field plate having the same potential as that of the P-type base may be provided so as to cover the edge of the P-type base 2 and part of the first RESURF layer 11 for further electric field relaxation at the edge of the P-type base 2. good. The present invention does not inhibit these effects.
- FIG. 7 to 9 are sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as the RESURF layer 102 in FIG. 9 showing the final step.
- the resurf layer 102 shown in FIG. 9 has a configuration in which a sixth resurf layer 16 is added to the outer side of the fifth resurf layer 15 of the resurf layer 101 shown in FIG.
- the sixth RESURF layer 16 has a configuration in which small regions 15 ′ having the same implantation amount as the fifth RESURF layer 15 and small regions 19 ′ where no ion implantation is performed are alternately arranged in a multiple manner. With this arrangement, the sixth RESURF layer 16 can be regarded as having an injection amount that is effectively smaller than that of the fifth RESURF layer 15.
- the implantation mask M11 is patterned on the main surface on the side where the active region 2 is formed.
- the implantation mask M11 has a pattern in which portions corresponding to the small regions 11 ′ in the first RESURF layer 11 and the second RESURF layer 12 become openings, and ion implantation of P-type impurities such as Al is performed on the implantation mask M1. As a result, a small region 11 ′ in the entire first RESURF layer 11 and the second RESURF layer 12 is formed.
- the implantation mask M12 is patterned in the step shown in FIG.
- the implantation mask M12 has a pattern in which portions corresponding to the small regions 13 ′ in the second RESURF layer 12, the small regions 13 ′ in the third RESURF layer 13 and the fourth RESURF layer 14 become openings, and the implantation mask M12 By ion-implanting a P-type impurity such as Al from above, a small region 13 ′ in the entire third resurf layer 13, the second resurf layer 12, and the fourth resurf layer 14 is formed.
- the implantation mask M13 is patterned in the step shown in FIG.
- the implantation mask M13 has a pattern in which portions corresponding to the small regions 15 ′ and the fifth RESURF layer 15 in the fourth RESURF layer 14 and the sixth RESURF layer 16 become openings, and Al or the like is formed on the implantation mask M13.
- Al or the like is formed on the implantation mask M13.
- the RESURF layer 102 having an effective six-stage injection amount can be formed by three injection processes.
- the RESURF layer having an effective injection amount is one step higher than the RESURF layer 101 shown in FIG. 5, and the electric field concentration can be further reduced.
- the RESURF layer 102 shown in FIG. 9 is wider than the RESURF layer 101 shown in FIG. 5 by the width of the sixth RESURF layer 19, but this is for convenience of explanation. In actuality, it is not necessary to change the entire width of the RESURF layer, and the inner region may be divided into six to form the structure of the RESURF layer 102 as shown in FIG.
- the RESURF layer 101 shown in FIG. 5 is connected to the P-type base 2, and the neutral region in the RESURF layer 101 when the reverse voltage bias is applied can be regarded as the same potential as the P-type base 2.
- the injection layer (small region 15 ′) of the sixth RESURF layer 16 is not connected to the fifth RESURF layer 15, and even when the voltage bias is zero, A region of a floating potential is generated in the injection layer of the 6 RESURF layer 16.
- the reverse voltage bias is applied and the depletion layer expands, the carriers remain confined in the injection layer of the sixth RESURF layer 16.
- the sixth resurf layer 16 is also depleted similarly to the first to fifth resurf layers 11 to 15 and functions as a resurf structure.
- the second RESURF layer 12 and the fourth RESURF layer 14 it is conceivable that carriers are left behind in a small region where the injection amount is large, surrounded by the depletion layer. Acts as a structure.
- the widths of the small regions constituting the RESURF layer defined by the effective injection amount are all configured to be the same.
- the width of the small region with the larger implantation amount is constant, and the width of the small region with the smaller implantation amount is A configuration may be adopted in which the width gradually increases toward the outside of the device.
- the RESURF layer 103 shown in FIG. 10 includes a first RESURF layer 11, a second RESURF layer 120, a third RESURF layer 13, and a fourth RESURF arranged so as to surround the P-type base 2 in order from the P-type base 2 side.
- the layer 140, the fifth RESURF layer 15, and the sixth RESURF layer 160 are configured.
- the second RESURF layer 120 includes a small region 11 ′ having the same injection amount as that of the first RESURF layer 11 and a small region 13 ′ having the same injection amount as that of the third RESURF layer 13.
- the small region 13 ′ is configured such that the width of the one adjacent to the first RESURF layer 11 is the narrowest, and the width becomes wider as the distance from the first RESURF layer 11 increases, and the width of the small region 11 ′ is It is constant.
- the fourth RESURF layer 140 includes a small region 13 ′ having the same injection amount as that of the third RESURF layer 13 and a small region 15 ′ having the same injection amount as that of the fifth RESURF layer 15.
- the small region 15 ′ is configured such that the width of the one adjacent to the third RESURF layer 13 is the narrowest and the width becomes wider as the distance from the third RESURF layer 13 increases, and the width of the small region 13 ′ is It is constant.
- the sixth RESURF layer 160 is configured such that a small region 15 ′ having the same implantation amount as that of the fifth RESURF layer 15 and a small region 19 ′ in which no ion implantation is performed are alternately arranged.
- the small region 19 ′ is configured such that the width of the one adjacent to the fifth RESURF layer 15 is the narrowest and the width becomes wider as the distance from the fifth RESURF layer 15 increases, and the width of the small region 15 ′ is constant. is there.
- the effective injection amount is gradually changed with respect to the region of the single injection amount existing at both ends (the outside of the sixth RESURF is considered as a single region of zero injection amount). It is possible to reduce the electric field concentration.
- the width of the small region with the larger injection amount gradually decreases toward the outside of the device, and the injection amount The width of the smaller region with the smaller number may be gradually increased toward the outside of the apparatus.
- the RESURF layer 104 shown in FIG. 11 includes the first RESURF layer 11, the second RESURF layer 120A, the third RESURF layer 13, and the fourth RESURF arranged so as to surround the P-type base 2 in this order from the P-type base 2 side. It is composed of a layer 140A, a fifth RESURF layer 15, and a sixth RESURF layer 160A.
- the second RESURF layer 120A is configured such that the small region 11 ′ having the same injection amount as that of the first RESURF layer 11 and the small region 13 ′ having the same injection amount as that of the third RESURF layer 13 are alternately and alternately arranged.
- the width of the small region 11 ′ is the largest of the ones closest to the first RESURF layer 11, and is configured such that the width decreases as the distance from the first RESURF layer 11 decreases.
- the width adjacent to the first RESURF layer 11 is the narrowest, and the width increases as the distance from the first RESURF layer 11 increases.
- the fourth RESURF layer 140 ⁇ / b> A is configured such that a small region 13 ′ having the same injection amount as the third RESURF layer 13 and a small region 15 ′ having the same injection amount as the fifth RESURF layer 15 are alternately and alternately arranged.
- the width of the small region 13 ′ is the width closest to the third RESURF layer 13, and the width is narrowed away from the third RESURF layer 13.
- the small region 15 ′ In addition, the width adjacent to the third resurf layer 13 is the narrowest, and the width increases as the distance from the third resurf layer 13 increases.
- the sixth RESURF layer 160A is configured such that a small region 15 ′ having the same implantation amount as that of the fifth RESURF layer 15 and a small region 19 ′ in which no ion implantation is performed are alternately arranged.
- the width of the small region 15 ′ is the widest of the ones closest to the fifth RESURF layer 15, and the width is narrowed away from the fifth RESURF layer 15.
- the small region 19 ′ The width adjacent to the 5 RESURF layer 15 is the narrowest, and the width increases as the distance from the 5 RESURF layer 15 increases.
- the effective injection amount is more moderate than the region of the single injection amount existing at both ends (the outside of the sixth RESURF is considered as a single region of zero injection amount).
- the electric field concentration can be further reduced.
- FIG. 2 The configuration of the termination region and the manufacturing method according to the second embodiment of the present invention will be described with reference to FIGS.
- Device configuration. 12 and 13 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as the RESURF layer 101 in FIG. 13 showing the final step.
- the structure of the finally obtained RESURF layer is the same as RESURF layer 101 shown in FIG. 5 of the first embodiment, but the manufacturing method is different from that of the first embodiment. .
- the implantation mask M21 is patterned on the main surface on the side where the active region 2 is formed.
- the implantation mask M21 has a pattern in which a portion corresponding to the first RESURF layer 11, the second RESURF layer 12, and the third RESURF layer 13 and a portion corresponding to the small region 13 ′ in the fourth RESURF layer 14 are openings. Then, a P-type impurity such as Al is ion-implanted from above the implantation mask M21, thereby forming an implantation layer having the same implantation amount as that of the third RESURF layer 13 in a portion corresponding to the first to third RESURF layers 11 to 13. At the same time, a small region 13 ′ in the fourth RESURF layer 14 is formed.
- the implantation mask M22 is patterned in the step shown in FIG.
- the implantation mask M22 has a pattern in which portions corresponding to the small region 11 ′ in the first RESURF layer 11, the second RESURF layer 12, the small region 15 ′ in the fourth RESURF layer 14, and the fifth RESURF layer 15 become openings.
- the first RESURF layer 11, the second RESURF layer 12, the fourth RESURF layer 14, and the fifth RESURF layer 15 are formed by ion-implanting a P-type impurity such as Al from above the implantation mask M22.
- the third resurf layer 13 is obtained by preventing further impurity implantation by the implantation mask M22.
- the implantation amount of the implantation process using the implantation mask M22 shown in FIG. 13 is not smaller than the implantation amount of the implantation process using the implantation mask M21 shown in FIG. 101 cannot be obtained.
- the number of the photoengraving process and the impurity implantation process can be reduced compared to the manufacturing method of the first embodiment, in which the RESURF layer 101 having the implantation amount of five stages can be effectively formed by the two implantation processes. Can be reduced once.
- the same configuration as that of the RESURF layer 102 shown in FIG. 9 can be obtained by the same method.
- a method for forming the RESURF layer 102 will be described with reference to FIGS. 14 and 15.
- an implantation mask M31 is patterned on the main surface on the side where the active region 2 is formed.
- the implantation mask M31 has a pattern in which a portion corresponding to the first RESURF layer 11, the second RESURF layer 12, and the third RESURF layer 13 and a portion corresponding to the small region 13 ′ in the fourth RESURF layer 14 are openings. Then, a P-type impurity such as Al is ion-implanted from above the implantation mask M31 to form an implantation layer having the same implantation amount as that of the third RESURF layer 13 in a portion corresponding to the first to third RESURF layers 11 to 13. At the same time, a small region 13 ′ in the fourth RESURF layer 14 is formed.
- the implantation mask M32 is patterned in the step shown in FIG.
- the implantation mask M32 includes the first RESURF layer 11, the small area 11 ′ in the second RESURF layer 12, the small area 15 ′ in the fourth RESURF layer 14, the portion corresponding to the fifth RESURF layer 15, and the small area in the sixth RESURF layer 16.
- the region 15 ′ has a pattern in which an opening is formed, and a P-type impurity such as Al is ion-implanted from above the implantation mask M32, whereby the first RESURF layer 11, the second RESURF layer 12, the fourth RESURF layer 14, and A fifth RESURF layer 15 is formed.
- the third resurf layer 13 is obtained by preventing further impurity implantation by the implantation mask M32.
- the number of the photoengraving process and the impurity implantation process can be reduced as compared with the manufacturing method of the first embodiment, in which the RESURF layer 102 having the implantation amount of five stages can be effectively formed by the two implantation processes. Can be reduced once.
- the injection amount of the first RESURF layer 11 having the largest injection amount is determined by the sum of the injection amount of the third RESURF layer 13 and the injection amount of the fifth RESURF layer 15. This limitation is due to the following reason. It will not be a problem.
- the semiconductor substrate 1 is a SiC substrate having a polytype of 4H.
- the implantation amount (injection surface density) of the implantation process using the implantation mask M32 is 0.5 ⁇ 10 13 cm ⁇ 2 and the implantation amount of the implantation process using the implantation mask M31 is 1.0 ⁇ 10 13 cm ⁇ 2.
- the injection amounts or effective injection amounts of the first to sixth RESURF layers 11 to 19 are 1.5 ⁇ 10 13 cm ⁇ 2 and 1.25 ⁇ 10 13 cm ⁇ 2 in order from the first RESURF layer 11. 1.0 ⁇ 10 13 cm ⁇ 2 , 0.75 ⁇ 10 13 cm ⁇ 2 , 0.5 ⁇ 10 13 cm ⁇ 2 , and 0.25 ⁇ 10 13 cm ⁇ 2 .
- the widths of the first to sixth RESURF layers 11 to 16 are substantially equal, the injection amount of the RESURF layer 102 decreases linearly to zero stepwise toward the outside.
- the RESURF layer in which the injection amount decreases linearly to zero toward the outside is effective in improving the high voltage resistance and the reliability of device operation. Therefore, it can be said that there is almost no demerit due to the injection amount of the first resurf layer 11 being determined by the sum of the injection amount of the third resurf layer 13 and the injection amount of the fifth resurf layer 15.
- the N-type impurity concentration of the SiC substrate 1 is 3 ⁇ 10 15 cm ⁇ 3, and the widths of the first to sixth RESURF layers 11 to 16 having the above implantation amount are 25 ⁇ m (the width of the entire RESURF layer is 150 ⁇ m). Then, a withstand voltage of 4000 V or more can be obtained while suppressing the electric field on the outermost surface of the RESURF layer to 1 MV / cm or less.
- the widths of the first to fourth RESURF layers 11 to 14 are made substantially equal, and the width of the fifth RESURF layer 15 is 1.5 times that of the other.
- the degree it can be regarded as a RESURF layer in which the injection amount decreases linearly to zero stepwise toward the outside.
- FIG. 36 shows the electric field strength (V / cm) at the outermost surface of the substrate (outermost surface of the RESURF layer), and the horizontal axis represents the planar direction of the RESURF layer, the P-type base, and the low-concentration N-type semiconductor substrate. ( ⁇ m), and the vertical axis represents the electric field strength (V / cm).
- the horizontal axis represents the distance ( ⁇ m) in the plane direction, and the vertical axis represents the electric field strength (V / cm).
- the distance in the planar direction of FIG. 37 is the same as that of FIG. 36, but FIG. 37 shows a position deeper than the outermost surface of the substrate (outermost surface of the RESURF layer) by the implantation depth of the P-type base and RESURF layer (PN junction).
- the electric field strength distribution of (depth) is shown.
- the electric field intensity distribution obtained by the RESURF layer having the structure of the present invention is shown by a solid line, and an ideal structure (the second RESURF layer 12, the fourth RESURF layer 14, the sixth RESURF layer 16) is shown.
- the electric field intensity distribution with a single injection amount is shown by a broken line.
- the maximum electric field is generated at the PN junction depth at the edge of the P-type base in both the structure of the present invention and the ideal structure. This place is the same as the place where the electric field concentrates when the RESURF layer is not formed.
- 16 and 17 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as a RESURF layer 102A in FIG. 17 showing the final step.
- the RESURF layer 102 is disposed so as to surround the P-type base 2 in order from the P-type base 2 side.
- the first RESURF layer 11A has an impurity layer 111 in the first RESURF layer shallower than the third RESURF layer 13A in an injection layer having the same injection amount and the same depth as the third RESURF layer 13A. Yes.
- the second RESURF layer 12A has the same implantation amount and the same depth as the third RESURF layer 13A, and the small region 111 ′ having the same implantation amount and the same depth as the impurity layer 111 in the first RESURF layer. They are arranged at predetermined intervals.
- the fourth RESURF layer 14A includes a small region 13 ′ having the same injection amount and the same depth as the third RESURF layer 13A, and a small region 15 ′ having the same injection amount and the same depth as the fifth RESURF layer 15A. They are arranged alternately.
- the sixth RESURF layer 16A has a configuration in which small regions 15 ′ having the same implantation amount and depth as the fifth RESURF layer 15A and small regions 19 ′ in which no ion implantation is performed are alternately arranged. ing.
- the concentration change in the depth direction of the first RESURF layer 11A and the second RESURF layer 12A can be moderated.
- the electric field concentration in the first RESURF layer 11A and the second RESURF layer 12A can be reduced.
- an implantation mask M31 is patterned on the main surface on which the active region 2 is formed.
- the implantation mask M31 has a pattern in which a portion corresponding to the first RESURF layer 11A, the second RESURF layer 12A, and the third RESURF layer 13A and a portion corresponding to the small region 13 ′ in the fourth RESURF layer 14A are openings. Then, a P-type impurity such as Al is ion-implanted from above the implantation mask M31, thereby implanting the portion corresponding to the first to third resurf layers 11A to 13A with the same implantation amount and the same depth as the third resurf layer 13A. A layer is formed, and a small region 13 ′ in the fourth RESURF layer 14A is formed. In this case, the implantation depth of the third RESURF layer 13A is made equal to the implantation depth of the P-type base 2.
- the implantation mask M32 is patterned in the step shown in FIG.
- the implantation mask M32 includes a small region 111 ′ in the first RESURF layer 11A, a second RESURF layer 12A, a small region 15 ′ in the fourth RESURF layer 14A, a portion corresponding to the fifth RESURF layer 15A, and a small region in the sixth RESURF layer 16A.
- the region 15 ′ has a pattern that is an opening.
- a P-type impurity such as Al is ion-implanted from above the implantation mask M32 with an implantation energy lower than that of the implantation process of the implantation mask M31, whereby the first RESURF layer impurity layer 111, the small region 111 ′, and the small region 15 are implanted.
- the fifth RESURF layer 15A and the small region 15' are formed to form the first RESURF layer 11A, the second RESURF layer 12A, the fourth RESURF layer 14A, the fifth RESURF layer 15A, and the sixth RESURF layer 16A.
- the third resurf layer 13A is obtained by preventing further impurity implantation by the implantation mask M32.
- FIG. 18 and 19 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as a RESURF layer 102B in FIG. 19 showing the final step.
- the RESURF layer 102B is arranged so as to surround the P-type base 2 in this order from the P-type base 2 side, the first RESURF layer 11B, the second RESURF layer 12B, the third RESURF layer 13B, the fourth RESURF layer 14B, and the fifth RESURF layer. 15B and the sixth RESURF layer 16B.
- the first RESURF layer 11B has a first RESURF layer impurity layer 111 shallower than the third RESURF layer 13B in an injection layer having the same injection amount and the same depth as the third RESURF layer 13B. Yes.
- the second RESURF layer 12B has the same implantation amount and the same depth as the third RESURF layer 13B, and the small region 111 ′ having the same implantation amount and the same depth as the impurity layer 111 in the first RESURF layer. They are arranged at predetermined intervals.
- the fourth RESURF layer 14B includes a small region 13 ′ having the same injection amount and the same depth as the third RESURF layer 13B, and a small region 15 ′ having the same injection amount and the same depth as the fifth RESURF layer 15B. They are arranged alternately.
- the sixth RESURF layer 16B has a configuration in which small regions 15 'having the same implantation amount and depth as the fifth RESURF layer 15B and small regions 19' in which no ion implantation is performed are alternately arranged in multiple layers. ing.
- the first RESURF layer 11B overlaps with the P-type base 2 in the width direction and the depth direction, so the corner portion of the P-type base 2 near the first RESURF layer 11B The density change in the depth direction can be moderated. As a result, the electric field concentration at the corner near the RESURF layer 11B of the P-type base 2 can be reduced.
- an implantation mask M51 is patterned on the main surface on which the active region 2 is formed.
- the implantation mask M51 has a pattern in which a portion corresponding to the first RESURF layer 11B, the second RESURF layer 12B, and the third RESURF layer 13B and a portion corresponding to the small region 13 ′ in the fourth RESURF layer 14B are openings. Then, a P-type impurity such as Al is ion-implanted from above the implantation mask M51, thereby implanting the portions corresponding to the first to third resurf layers 11B to 13B with the same implantation amount and depth as the third resurf layer 13B. A layer is formed, and a small region 13 ′ in the fourth RESURF layer 14B is formed.
- the implantation energy is set so that the implantation depth of the implantation layer having the same implantation amount and the same depth as the third RESURF layer 13B is deeper than the implantation depth of the P-type base 2, and the P-type base 2 in the width direction.
- the opening portion of the implantation mask M51 is formed so as to overlap with each other.
- the implantation mask M52 is patterned in the step shown in FIG.
- the implantation mask M52 includes an impurity layer 111 in the first RESURF layer, a small region 111 ′ in the second RESURF layer 12B, a small region 15 ′ in the fourth RESURF layer 14B, a portion corresponding to the fifth RESURF layer 15B, and a sixth RESURF layer.
- a small region 15 'in 16B has a pattern that is an opening.
- the opening for forming the impurity layer 111 in the first RESURF layer is formed so as to overlap the P-type base 2 in the width direction, but the same injection amount as that of the third RESURF layer 13B in the width direction, The injection layer having the same depth is formed so as not to exceed the portion overlapping the P-type base 2.
- a P-type impurity such as Al is ion-implanted from above the implantation mask M52 with an implantation energy lower than the implantation process of the implantation mask M51, whereby the first RESURF layer impurity layer 111, the small region 111 ′, and the small region 15 are implanted.
- the fifth RESURF layer 15B and the small region 15' are formed to form the first RESURF layer 11B, the second RESURF layer 12B, the fourth RESURF layer 14B, the fifth RESURF layer 15B, and the sixth RESURF layer 16B.
- the third resurf layer 13B is obtained by preventing further impurity implantation by the implantation mask M52.
- the implantation energy is set so that the implantation depth of the first RESURF layer impurity layer 111 is deeper than the P-type base 2.
- 20 and 21 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as a RESURF layer 102C in FIG. 21 showing the final step.
- the RESURF layer 102C is arranged so as to surround the P-type base 2 in order from the P-type base 2 side.
- the first RESURF layer 11C has an impurity layer 111 in the first RESURF layer shallower than the third RESURF layer 13C in an injection layer having the same injection amount and the same depth as the third RESURF layer 13C. Yes.
- the second RESURF layer 12C has the same implantation amount and the same depth as the third RESURF layer 13C, and the small region 111 ′ having the same implantation amount and the same depth as the impurity layer 111 in the first RESURF layer. They are arranged at predetermined intervals.
- the fourth RESURF layer 14C includes a small region 13 ′ having the same injection amount and the same depth as the third RESURF layer 13C, and a small region 15 ′ having the same injection amount and the same depth as the fifth RESURF layer 15C. They are arranged alternately.
- the sixth RESURF layer 16C has a configuration in which small regions 15 ′ having the same implantation amount and depth as the fifth RESURF layer 15C and small regions 19 ′ in which no ion implantation is performed are alternately arranged in multiple layers. ing.
- the impurity layer 111 in the first RESURF layer is provided so as to include the entire P-type base 2, and the injection layer having the same injection amount and the same depth as the third RESURF layer 13C is the first RESURF.
- a region provided so as to include the in-layer impurity layer 111 and including the P-type base 2 is referred to as an active region RESURF layer 10.
- the concentration change in the depth direction of the entire P-type base 2 becomes gentle, and the switching characteristics of the PN diode can be changed.
- the implantation mask M61 is patterned on the main surface on the side where the active region 2 is formed.
- the portion corresponding to the P-type base 2, the first RESURF layer 11C, the second RESURF layer 12C, and the third RESURF layer 13C, and the portion corresponding to the small region 13 ′ in the fourth RESURF layer 14C are openings.
- the third RESURF layer is formed in the portion corresponding to the active region RESURF layer 10 and the first to third RESURF layers 11C to 13C by ion-implanting a P-type impurity such as Al from above the implantation mask M61.
- An injection layer having the same injection amount and depth as 13C is formed, and a small region 13 ′ in the fourth RESURF layer 14C is formed.
- the implantation energy is set so that the implantation depth of the implantation layer having the same implantation amount and the same depth as the third RESURF layer 13C is deeper than the implantation depth of the P-type base 2.
- the implantation mask M62 includes a first RESURF layer impurity layer 111, a small region 111 ′ in the second RESURF layer 12C, a small region 15 ′ in the fourth RESURF layer 14C, a portion corresponding to the fifth RESURF layer 15C, and a sixth RESURF layer.
- a small region 15 'in 16C has a pattern that is an opening. In this case, the opening for forming the first RESURF layer impurity layer 111 is also formed on the entire P-type base 2.
- a P-type impurity such as Al is ion-implanted from above the implantation mask M62 with an implantation energy lower than the implantation process of the implantation mask M61, whereby the first RESURF layer impurity layer 111, the small region 111 ′, and the small region 15 are implanted.
- a fifth RESURF layer 15C, a small region 15' are formed, and the active region RESURF layer 10, the first RESURF layer 11C, the second RESURF layer 12C, the fourth RESURF layer 14C, the fifth RESURF layer 15C, and the sixth RESURF Layer 16C is formed.
- the third resurf layer 13C is obtained by preventing further impurity implantation by the implantation mask M62.
- the implantation energy is set so that the implantation depth of the first RESURF layer impurity layer 111 is deeper than the P-type base 2.
- the first to third modifications of the second embodiment described above show a method of controlling the resurf structure and further the profile in the depth direction of the active region by changing the implantation depth of each implantation process.
- This method is particularly effective in the case of using a semiconductor substrate that is small in scattering and diffusion of impurity ions, such as a SiC substrate. Further, even a semiconductor substrate that thermally diffuses greatly, such as a silicon substrate, can be applied when shortening the annealing time and reducing the annealing temperature.
- the first RESURF layer 11B overlaps the P-type base 2 in the width direction and the depth direction, and the impurities in the first RESURF layer
- the structure in which the layer 111 is provided so as to include the entire P-type base 2 is shown.
- the impurity region of the first RESURF layer adjacent to the P-type base 2 is changed. You may comprise as mentioned above.
- the implantation process of the P-type base layer 2 is omitted, and the first RESURF layer impurity layer 111 (that is, the active region RESURF layer 10 and the first RESURF layer 11C) is regarded as a P-type base. May be.
- the total implantation amount of the region serving as the P-type base is 1 to 2 times or more the value given by the RESURF condition of the semiconductor material (a condition that the P-type base is not completely depleted). .
- the photoengraving process and impurity implantation process for manufacturing the PN junction diode can be reduced once.
- Embodiment 3 In the second embodiment, the configuration and the manufacturing method for forming the RESURF layer in which the effective implantation amount gradually decreases in five or six steps toward the outside of the semiconductor device by two implantation processes have been described. It can be formulated into two or more n injection processes.
- Embodiment 3 according to the present invention a configuration and a manufacturing method for forming a RESURF layer by n injection processes will be described.
- the injection amount sj can be expressed by the following mathematical formula (3).
- a region of injection amount s (2 n -1) is arranged adjacent to the P-type base 2
- a region of injection amount s (2 n -2) is arranged adjacent to the outside thereof, and so on.
- the injection amount sj is gradually reduced toward the outside, and a region of the injection amount s1 is finally arranged.
- a RESURF layer having an injection amount of (2 n ⁇ 1) stages can be formed by n injection processes. If all the widths of the region of the implantation amount sj are made the same, a (2 n ⁇ 1) stage RESURF layer can be formed in which the implantation amount decreases linearly to zero toward the outside.
- 22 to 24 are sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as the RESURF layer 121 in FIG. 24 showing the final step.
- the 24 includes a first resurf layer 21, a second resurf layer 22, a third resurf layer 23, and a fourth resurf layer 24 arranged so as to surround the P type base 2 in this order from the P type base 2 side.
- the fifth RESURF layer 25, the sixth RESURF layer 26, and the seventh RESURF layer 27 are included.
- the implantation mask M71 has a pattern in which portions corresponding to the first RESURF layer 21, the second RESURF layer 22, the third RESURF layer 23, and the fourth RESURF layer 24 become openings, and Al or the like is formed on the implantation mask M71.
- an implantation layer having the same implantation amount and depth as the fourth RESURF layer 24 is formed in portions corresponding to the first to fourth RESURF layers 21 to 24.
- the implantation mask M72 has a pattern in which portions corresponding to the first RESURF layer 21, the second RESURF layer 22, the fifth RESURF layer 25, and the sixth RESURF layer 26 become openings, and Al or the like is formed on the implantation mask M72.
- An injection layer is formed, and an injection layer having the same injection amount and depth as the sixth RESURF layer 26 is formed in portions corresponding to the fifth and sixth RESURF layers 25 and 26.
- the implantation mask M73 is patterned in the step shown in FIG.
- the implantation mask M73 has a pattern in which portions corresponding to the first RESURF layer 21, the third RESURF layer 23, the fifth RESURF layer 25, and the seventh RESURF layer 26 are openings, and Al or the like is formed on the implantation mask M73.
- the first resurf layer 21, the third resurf layer 23, the fifth resurf layer 25, and the seventh resurf layer 27 are formed by ion-implanting the P-type impurity with the same impurity amount as the seventh resurf layer 27.
- the second resurf layer 22, the fourth resurf layer 24, and the sixth resurf layer 26 are obtained by preventing further impurity implantation by the implantation mask M73.
- the effective injection amount is ⁇ 2 ⁇ (2 n ⁇ 1) ⁇ .
- an effective injection amount (including a single injection amount) tj is expressed by the following formula (4).
- the gradation (number of steps) of the injection amount can be approximately doubled even with the same number of injection processes.
- Production method. 25 to 27 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as the RESURF layer 122 in FIG. 27 showing the final step.
- the RESURF layer 122 shown in FIG. 27 includes a first RESURF layer 41, a second RESURF layer 42, a third RESURF layer 43, and a fourth RESURF layer 44 that are disposed so as to surround the P-type base 2 in this order from the P-type base 2 side. , 5th RESURF layer 45, 6th RESURF layer 46, 7th RESURF layer 47, 8th RESURF layer 48, 9th RESURF layer 49, 10th RESURF layer 50, 11th RESURF layer 51, 12th RESURF layer 52, It is composed of a 13th RESURF layer 53 and a 14th RESURF layer 54.
- the second resurf layer 42, the fourth resurf layer 44, the sixth resurf layer 46, the eighth resurf layer 48, the tenth resurf layer 50, the twelfth resurf layer 52 and the fourteenth resurf layer 54 are effective injection amounts. It is a RESURF layer having.
- the second RESURF layer 42 includes a small region 41 ′ having the same injection amount as that of the first RESURF layer 41 and a small region 43 ′ having the same injection amount as that of the third RESURF layer 43. Yes.
- the fourth RESURF layer 44 is configured by alternately arranging a small region 43 ′ having the same injection amount as the third RESURF layer 43 and a small region 45 ′ having the same injection amount as the fifth RESURF layer 45. Yes.
- the sixth RESURF layer 46 is composed of small regions 45 ′ having the same injection amount as the fifth RESURF layer 45 and small regions 47 ′ having the same injection amount as the seventh RESURF layer 47. Yes.
- the eighth RESURF layer 48 includes a small region 47 ′ having the same injection amount as that of the seventh RESURF layer 47 and a small region 49 ′ having the same injection amount as that of the ninth RESURF layer 49. Yes.
- the tenth RESURF layer 50 includes a small region 49 ′ having the same injection amount as that of the ninth RESURF layer 49 and a small region 51 ′ having the same injection amount as that of the eleventh RESURF layer 51. Yes.
- the twelfth RESURF layer 52 is configured such that small regions 51 ′ having the same injection amount as the eleventh RESURF layer 51 and small regions 53 ′ having the same injection amount as the thirteenth RESURF layer 53 are alternately arranged in multiple layers. Yes.
- the fourteenth RESURF layer 54 is configured such that small regions 53 'having the same implantation amount as the thirteenth RESURF layer 53 and small regions 19' in which no ion implantation is performed are alternately arranged in multiple layers.
- an implantation mask M81 is patterned on the main surface on which the active region 2 is formed.
- the implantation mask M81 has a pattern in which a portion corresponding to the first to seventh RESURF layers 41 to 47 and a portion corresponding to the small region 47 ′ in the eighth RESURF layer 48 are openings, from above the implantation mask M81.
- a P-type impurity such as Al
- an implantation layer having the same implantation amount as that of the seventh RESURF layer 47 is formed in portions corresponding to the first to seventh RESURF layers 41 to 47, and the eighth RESURF layer 18 Forming a small region 47 '.
- the implantation mask M82 includes portions corresponding to the first RESURF layer 41, the second RESURF layer 42, the third RESURF layer 43, the ninth RESURF layer 49, the tenth RESURF layer 50, and the eleventh RESURF layer 51, and the fourth RESURF layer 44. And the portion corresponding to the small region 51 ′ in the twelfth RESURF layer 52 has a pattern of openings, and P-type impurities such as Al are introduced from the implantation mask M82 into the eleventh region.
- the portion corresponding to the first to third RESURF layers 41 to 43 and the small region 49 ′ in the eighth RESURF layer 48 have the same implantation amount as that of the third RESURF layer 43.
- An injection layer is formed, and a small region 43 ′ in the fourth RESURF layer 44 is formed.
- an injection layer having the same injection amount as that of the eleventh RESURF layer 51 is formed in portions corresponding to the ninth to eleventh RESURF layers 49 to 51, and a small region 51 'in the twelfth RESURF layer 52 is formed.
- the implantation mask M83 includes portions corresponding to the first RESURF layer 41, the fifth RESURF layer 45, the ninth RESURF layer 49, and the thirteenth RESURF layer 53, a portion corresponding to the small region 41 ′ in the second RESURF layer 42, a fourth A portion corresponding to the small region 45 ′ in the RESURF layer 44, a portion corresponding to the small region 45 ′ in the sixth RESURF layer 46, a portion corresponding to the small region 49 ′ in the eighth RESURF layer 48, and a small portion in the tenth RESURF layer 50.
- the portion corresponding to the region 49 ′, the portion corresponding to the small region 51 ′ in the twelfth RESURF layer 52, and the portion corresponding to the small region 53 ′ in the fourteenth RESURF layer 54 have an opening pattern.
- the first resurf layer 41, the fifth resurf layer 45, the ninth resurf layer 49, and the thirteenth resurf layer are formed by ion-implanting a P-type impurity such as Al from above the implantation mask M83 with the same impurity amount as that of the thirteenth resurf layer 53. 53 is formed.
- a P-type impurity such as Al from above the implantation mask M83 with the same impurity amount as that of the thirteenth resurf layer 53. 53 is formed.
- the small region 41 ′ in the second resurf layer 42, the small region 45 ′ in the fourth resurf layer 44, the small region 45 ′ in the sixth resurf layer 46, the small region 49 ′ in the eighth resurf layer 48, and the tenth RESURF layer 50 are formed by ion-implanting a P-type impurity such as Al from above the implantation mask M83 with the same impurity amount as that of the thirteenth re
- the implantation masks M81 to M83 shown in FIGS. 25 to 27 are merely examples, and the mask capable of forming a RESURF layer having 14 implantation amounts in three implantation processes is not limited thereto.
- the implantation masks M81 to M83 are opened with the following law, and this can also be applied to n implantation processes.
- the implantation amount am a1 / 2 m ⁇ 1 (1 ⁇ m ⁇
- the mask used for the implantation of n) is, in order from the P-type base side, an opening of width ⁇ w ⁇ (2 n ⁇ m + 1 ⁇ 1) ⁇ , a partially opened portion of width w, and a width ⁇ w ⁇ (2 n ⁇ m + 1 ⁇ 1) ⁇ and a partially opened portion having a width w are formed repeatedly.
- 28 to 30 are sectional views sequentially showing the manufacturing process of the termination region, and the final structure of the termination region is shown as a RESURF layer 121A in FIG. 30 showing the final step.
- the RESURF layer 121A is arranged so as to surround the P-type base 2 in order from the P-type base 2 side.
- the first RESURF layer 21A is shallower than the second RESURF layer impurity layer 221 in the second RESURF layer impurity layer 221 included in the second RESURF layer 22A.
- One RESURF layer impurity layer 211 is provided.
- the second RESURF layer 22A is configured to have an impurity layer 221 in the second RESURF layer shallower than the fourth RESURF layer 24A in an injection layer having the same injection amount and the same depth as the fourth RESURF layer 24A. Yes.
- the third RESURF layer 23A has a third RESURF layer impurity layer 231 shallower than the fourth RESURF layer 24A in the same injection amount and the same depth as the fourth RESURF layer 24A. Yes.
- the fifth RESURF layer 25A includes an impurity layer 251 in the fifth RESURF layer that is shallower than the sixth RESURF layer 26A in an injection layer having the same injection amount and the same depth as the sixth RESURF layer 26A. Yes.
- the concentration change in the depth direction of the first to third RESURF layers 21A to 23A can be moderated.
- the electric field concentration in the first to third RESURF layers 21A to 23A can be reduced.
- an implantation mask M91 is patterned on the main surface on the side where the active region 2 is formed.
- the implantation mask M91 has a pattern in which portions corresponding to the first to fourth RESURF layers 21A to 24A are openings, and P-type impurities such as Al are ion-implanted from above the implantation mask M91.
- An injection layer having the same injection amount and the same depth as those of the fourth RESURF layer 24A is formed in portions corresponding to the fourth RESURF layers 21A to 24A.
- the implantation mask M92 is patterned in the step shown in FIG.
- the implantation mask M92 has a pattern in which portions corresponding to the first RESURF layer 21A, the second RESURF layer 22A, the fifth RESURF layer 25A, and the sixth RESURF layer 26A become openings.
- the P-type impurity is ion-implanted with an implantation energy lower than the implantation process of the implantation mask M91, so that an implantation layer having the same implantation amount and depth as those of the second RESURF layer impurity layer 221 and the sixth RESURF layer 26A can be obtained.
- the implantation mask M93 is patterned in the step shown in FIG.
- the implantation mask M93 has a pattern in which portions corresponding to the first RESURF layer 21A, the third RESURF layer 23A, the fifth RESURF layer 25A, and the seventh RESURF layer 27A are openings.
- the first resurf-layer impurity layer 211 is formed in the second resurf-layer impurity layer 221 by ion-implanting the P-type impurity with an implantation energy lower than the implantation process of the implantation mask M92, and the fourth resurf layer
- the third RESURF layer impurity layer 231 is formed in the implantation layer having the same implantation amount and the same depth as 24A, and the fifth RESURF layer in the implantation layer having the same implantation amount and the same depth as the sixth RESURF layer 26A.
- An inner impurity layer 251 is formed, and a seventh RESURF layer 27 A is formed in the semiconductor substrate 1.
- the second resurf layer 22A, the fourth resurf layer 24A, and the sixth resurf layer 26A are obtained by preventing further impurity implantation by the implantation mask M93.
- 31 to 33 are cross-sectional views sequentially showing the manufacturing process of the termination region, and the final configuration of the termination region is shown as a RESURF layer 122A in FIG. 33 showing the final step.
- the RESURF layer 122A shown in FIG. 33 includes a first RESURF layer 41A, a second RESURF layer 42A, a third RESURF layer 43A, and a fourth RESURF layer 44A arranged so as to surround the P-type base 2 in this order from the P-type base 2 side.
- the second RESURF layer 42A, the fourth RESURF layer 44A, the sixth RESURF layer 46A, the eighth RESURF layer 48A, the tenth RESURF layer 50A, the 12th RESURF layer 52A, and the 14th RESURF layer 54A are effective injection amounts. It is a RESURF layer having.
- the first RESURF layer 41A is shallower than the fourth RESURF layer impurity layer 431 in the third RESURF layer impurity layer 431 included in the third RESURF layer 43A, in the same injection amount and depth as the third RESURF layer impurity layer 431.
- One RESURF layer impurity layer 411 is provided.
- the third RESURF layer 43A is configured to have an impurity layer 431 in the third RESURF layer shallower than the seventh RESURF layer 47A in an injection layer having the same injection amount and the same depth as the seventh RESURF layer 47A. Yes.
- the fifth RESURF layer 45A is configured to have an impurity layer 451 in the fifth RESURF layer shallower than the seventh RESURF layer 47A in an injection layer having the same injection amount and the same depth as the seventh RESURF layer 47A. Yes.
- the ninth RESURF layer 49A is configured to have an ninth RESURF layer impurity layer 491 shallower than the eleventh RESURF layer 51A in the same injection amount and depth as the eleventh RESURF layer 51A. Yes.
- the second RESURF layer 42 ⁇ / b> A includes a small region 41 ′ having the same implantation amount and the same depth as the first RESURF layer impurity layer 411 included in the first RESURF layer 41 ⁇ / b> A, and a third RESURF layer included in the third RESURF layer 43.
- Small regions 43 ′ having the same implantation amount and the same depth as the inner impurity layer 431 are configured to be alternately arranged in multiple layers.
- the fourth RESURF layer 44A is the same as the third RESURF layer impurity layer 431 included in the third RESURF layer 43.
- the fourth RESURF layer 44A is included in the fifth RESURF layer included in the fifth RESURF layer 45A.
- Small regions 45 ′ having the same implantation amount and the same depth as the impurity layer 451 are configured to be alternately arranged in multiple.
- the sixth RESURF layer 46A has the same implantation amount as the impurity layer 451 in the fifth RESURF layer included in the fifth RESURF layer 45A, the same implantation amount and the same depth as the small region 45 ′ having the same depth and the seventh RESURF layer 47A.
- the small regions 47 ′ are arranged alternately in a multiple manner.
- the eighth RESURF layer 48 has the same implantation amount and the same depth as the seventh RESURF layer 47A, the small region 47 ′ having the same depth, and the ninth RESURF layer impurity layer 491 included in the ninth RESURF layer 49A.
- the sub-regions 49 ′ are arranged alternately in a multiple manner.
- the tenth RESURF layer 50A has the same implant amount as the impurity layer 491 in the ninth RESURF layer 49A included in the ninth RESURF layer 49A, the same implant amount and the same depth as the small region 49 ′ having the same depth and the eleventh RESURF layer 51A.
- the small regions 51 ′ are alternately arranged in a multiple manner.
- the twelfth RESURF layer 52A includes a small region 51 ′ having the same injection amount and the same depth as the eleventh RESURF layer 51A, and a small region 53 ′ having the same injection amount and the same depth as the thirteenth RESURF layer 53A. They are arranged alternately.
- the fourteenth RESURF layer 54A is configured such that small regions 53 ′ having the same implantation amount and depth as the thirteenth RESURF layer 53A and small regions 19 ′ in which no ion implantation is performed are alternately arranged in multiple layers. Yes.
- the concentration change in the depth direction of the first to third RESURF layers 41A to 43A can be moderated.
- the electric field concentration in the first to third RESURF layers 41A to 43A can be reduced.
- the concentration in the depth direction at the corner portion of the P-type base 2 near the first RESURF layer 41A. Change can be moderated.
- the electric field concentration at the corner near the RESURF layer 41A of the P-type base 2 can be reduced.
- an implantation mask M101 is patterned on the main surface on the side where the active region 2 is formed.
- the implantation mask M101 has a pattern in which a portion corresponding to the first to seventh RESURF layers 41A to 47A and a portion corresponding to the small region 47 ′ in the eighth RESURF layer 48A are openings, from above the implantation mask M101.
- a P-type impurity such as Al
- an implantation layer having the same implantation amount as that of the seventh RESURF layer 47A is formed in portions corresponding to the first to seventh RESURF layers 41A to 47A, and the eighth RESURF layer 18 Forming a small region 47 '.
- the implantation mask M102 includes portions corresponding to the first RESURF layer 41A, the second RESURF layer 42A, the third RESURF layer 43A, the ninth RESURF layer 49A, the tenth RESURF layer 50A, and the eleventh RESURF layer 51A, the fourth RESURF layer 44A.
- a portion corresponding to the small region 43 ′ in FIG. 5 and a portion corresponding to the small region 51 ′ in the twelfth RESURF layer 52A have an opening, and a P-type impurity such as Al is implanted from above the implantation mask M102.
- a portion corresponding to the first to third RESURF layers 41A to 43A and a small region in the eighth RESURF layer 48A are implanted by the same impurity amount as the eleventh RESURF layer 51A with an implantation energy lower than the implantation process of the mask M101.
- An injection layer having the same injection amount as that of the third RESURF layer 43 is formed on 49 ′, and the fourth RESURF layer 44 is formed on the fourth RESURF layer 44. Kicking forming small regions 43 '.
- an injection layer having the same injection amount as that of the eleventh RESURF layer 51A is formed in a portion corresponding to the ninth to eleventh RESURF layers 49A to 51A, and a small region 51 'in the twelfth RESURF layer 52A is formed.
- the implantation mask M103 includes portions corresponding to the first RESURF layer 41A, the fifth RESURF layer 45A, the ninth RESURF layer 49A, and the thirteenth RESURF layer 53A, a portion corresponding to the small region 41 ′ in the second RESURF layer 42A, a fourth A portion corresponding to the small region 45 ′ in the RESURF layer 44 A, a portion corresponding to the small region 45 ′ in the sixth RESURF layer 46, a portion corresponding to the small region 49 ′ in the eighth RESURF layer 48, and a small portion in the tenth RESURF layer 50
- the portion corresponding to the region 49 ′, the portion corresponding to the small region 51 ′ in the twelfth RESURF layer 52, and the portion corresponding to the small region 53 ′ in the fourteenth RESURF layer 54 have an opening pattern.
- the first RESURF layer 41A and the fifth RESURF A layer 45A, a ninth RESURF layer 49A, and a thirteenth RESURF layer 53A are formed. Further, the small region 41 ′ in the second RESURF layer 42A, the small region 45 ′ in the fourth RESURF layer 44A, the small region 45 ′ in the sixth RESURF layer 46A, the small region 49 ′ in the eighth RESURF layer 48A, and the tenth RESURF layer 50A.
- the third resurf layer 43A, the seventh resurf layer 47A, and the eleventh RESURF layer 51A are obtained by preventing further impurity implantation by the implantation mask M103.
- a RESURF layer for example, in a SiC substrate, the maximum impurity concentration is 1.5 ⁇ 10 6 in which the implantation amount gradually decreases linearly from the P-type base layer on the average with a relatively low implantation amount. 13 cm -2 ), and by expanding the depletion layer to some extent in the region where the multiple ion implantations are superimposed (first RESURF layer), the radius of curvature of the depletion layer boundary on the P-type base layer side is expanded, In addition, excellent high pressure resistance can be provided.
- the concentration of the RESURF layer is relatively low and the depletion layer can be expanded to some extent in the region of the RESURF layer having the highest concentration, excessive electric field concentration does not occur at the depletion layer boundary on the P-type base layer side. .
- the depth of the implantation layer having different implantation amounts (or concentrations) there is no significant limitation on the depth of the implantation layer having different implantation amounts (or concentrations).
- the breakdown voltage can be improved by a structure in which the RESURF layers having different depths are superimposed. it can.
- the steps of the RESURF structure can be increased by providing regions that are alternately implanted in separate regions without overlapping the impurities.
- the effect of reducing electric field concentration by the RESURF layer does not change (implantation mask alignment error does not affect the withstand voltage performance), so a problem occurs. do not do.
- a RESURF layer having an injection amount of 5 to 6 stages can be effectively formed by three injection processes, and the method described in the second embodiment is used. According to this, since the RESURF layer having an injection amount of 5 to 6 steps can be effectively formed by two injection processes, more RESURF layers can be formed and the breakdown voltage can be increased by a small injection process. it can.
- Embodiment 4 In the first to third embodiments, the case where the present invention is applied to a PN diode has been described.
- a MOSFET having a P-type implantation layer (P-type well) containing a P-type impurity at a relatively high concentration It can also be applied to the termination region of the Schottky barrier diode to reduce the electric field concentration in the termination region.
- FIG. 34 is a cross-sectional view showing a termination region of the Schottky barrier diode 200 when the present invention is applied.
- the Schottky barrier diode 200 is formed on the semiconductor substrate 1 containing a relatively low concentration of N-type impurities, and below the edge of the Schottky electrode 81 provided on the main surface of the semiconductor substrate 1.
- the RESURF layer 102 is formed so that the first RESURF layer 11 is disposed on the surface.
- the RESURF layer 102 has the same configuration as the RESURF layer 102 shown in FIG.
- a P-type injection layer containing a P-type impurity at a relatively high concentration is provided below the Schottky electrode edge in order to reduce electric field concentration at the edge of the Schottky electrode. If the injection amount of the first RESURF layer 11 is 1 to 2 times or more of the value given by the RESURF condition of the semiconductor material (a condition that the first RESURF layer 11 is not completely depleted), it is particularly a separate P type. There is no need to provide an injection layer.
- the location to be protected is the lower edge (this portion corresponds to the active region) of the Schottky electrode 81, and therefore the first RESURF layer 11 includes the Schottky electrode 81. It is comprised so that it may extend also to the lower end edge part.
- the electric field is concentrated on the inner edge of the first RESURF layer 11.
- the overlap between the Schottky electrode 81 and the first RESURF layer 11 is several ⁇ m or more.
- the RESURF layer 102 when it is formed, it may be simultaneously injected into a part of the lower part (active region) of the Schottky electrode 81 to form JBS (Junction Barrier Schottky ⁇ ⁇ ⁇ ⁇ diode) or MPS (Merged PN-Schottky diode).
- JBS Joint Barrier Schottky ⁇ ⁇ ⁇ ⁇ diode
- MPS Merged PN-Schottky diode
- FIG. 5 In the first to third embodiments, the case where the present invention is applied to a PN diode has been described. However, the present invention can also be applied to an LDMOSFET (Laterally Diffused MOSFET) to reduce electric field concentration at the edge of a high concentration injection layer. .
- LDMOSFET Laser Diffused MOSFET
- FIG. 35 is a cross-sectional view showing an active region of the LDMOSFET 300 when the present invention is applied.
- the LDMOSFET 300 is formed on the semiconductor substrate 91 containing P-type impurities at a relatively low concentration, and a P-type implantation layer containing P-type impurities at a relatively high concentration provided in the main surface of the semiconductor substrate 91.
- the N-type implantation layer 94 including the source electrode 95 provided on the P-type well 98 and the N-type implantation layer 94, and the N-type impurity serving as the drain provided at a relatively high concentration.
- An N-type injection layer 96 including a drain electrode 97 provided on the N-type injection layer 96, and a RESURF layer 101 including an N-type impurity provided between the gate and the drain at a relatively low concentration.
- the N-type injection layer 96 side becomes the first RESURF layer 11, and the end of the fifth RESURF layer 15 is in contact with the side surface of the P-type well 98.
- the gate electrode 95 covers the end of the fifth RESURF layer 15 as much as possible, there may be a region that is not implanted between the end of the fifth RESURF layer 15 and the P-type well 98. If the lower part of the drain side end of the gate electrode 95 is an N-type impurity layer, the fifth RESURF layer 15 and the P-type well 98 may be overlapped and implanted. Even in such a configuration, the LDMOSFET is not turned on unless the channel on the surface of the P-type well 98 is opened, so that the gate threshold voltage does not change.
- the purpose of providing the RESURF layer is the same.
- a back surface of the semiconductor substrate, a region having substantially the same potential as the back surface of the semiconductor substrate (corresponding to a dicing line and a channel stopper in the active region of the LDMOSFET and a termination region of the vertical diode), and the semiconductor substrate High-concentration injection layer edge generated when a high voltage is applied between the high-concentration injection layers of different conductivity types (equivalent to the drain in the active region of the LDMOSFET and the P base in the termination region of the vertical diode)
- the RESURF layer 101 is provided in order to alleviate the electric field concentration.
- Embodiments 1 to 3 an example of application to a vertical device has been shown. However, in the case of a horizontal device as well, if a mechanism for maintaining a breakdown voltage is required at the device peripheral portion (termination region), a similar resurf structure should be applied. Can do.
- the configuration applied to the PN junction diode constituted by the N-type semiconductor substrate and the P-type injection layer has been described. An effect is obtained.
- the same effect can be obtained when applied not only to a PN junction diode but also to a transistor such as a MOSFET, IGBT, or BJT (Bipolar Junction Transistor).
- a transistor such as a MOSFET, IGBT, or BJT (Bipolar Junction Transistor).
- the present invention can also be applied to the termination structure of the lateral LDMOSFET of the fifth embodiment.
- the semiconductor substrate is not limited to SiC, and a semiconductor having a wide band gap, for example, a gallium nitride-based material, a substrate made of diamond, or a Si substrate may be used.
- the optimum amount of injection of the RESURF layer is mainly determined by the dielectric constant and the breakdown electric field of the semiconductor material used, and the optimum width of the RESURF layer is mainly determined by the breakdown electric field of the semiconductor material and the required breakdown voltage.
- Switching elements and diode elements composed of such wide band gap semiconductors have high voltage resistance and high allowable current density, and therefore can be made smaller than silicon semiconductors. These miniaturized switching elements By using a diode element, it is possible to reduce the size of a semiconductor device module incorporating these elements.
- the heat sink fins of the heat sink can be downsized, and cooling by air cooling rather than water cooling can be performed, so that the semiconductor device module can be further downsized.
- Impurities used for implantation are activated by substituting atoms of a semiconductor material such as B (boron), N (nitrogen), Al (aluminum), P (phosphorus), As (arsenic), and In (indium). Any thing can be used. However, in the case of an impurity having a longer diffusion length, the change in the injection amount (or concentration) becomes smoother at the interface between the regions with different injection amounts, and the electric field concentration is reduced. Therefore, in the case of an N-type semiconductor substrate, a better effect can be expected by injecting B (boron) or Al (aluminum) to form a P-type injection layer.
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Abstract
Description
図1は本発明をダイオードに適用した場合のダイオード100の構成を示す平面図であり、図2は、図1におけるA-A線での矢視断面を示す断面図である。ダイオード100は、図1および図2に示すように、N型不純物を比較的低濃度に含む半導体基板1の表面内に、P型不純物を比較的高濃度に含む注入層で構成される活性領域2が形成され、さらに活性領域2を取り囲むように、濃度の異なる複数のP型注入層で構成される終端領域3が形成されている。そして、活性領域2上にはアノード電極4が配設され、アノード電極4とは反対側の半導体基板1の主面(基板裏面)上にはカソード電極5が配設されている。
図3~図5を用いて、本発明に係る実施の形態1の終端領域の構成および製造方法について説明する。
図3~図5は終端領域の製造工程を順に示す断面図であり、終端領域の最終的な構成は、最終工程を示す図5にリサーフ層101として示す。
次に、図3~図5を用いてリサーフ層101の形成方法について説明する。まず、イオン注入を用いて、半導体基板1の表面内に、P型不純物を比較的高濃度に注入して活性領域2を形成した状態の半導体基板1において、図3に示すように、活性領域2を形成した側の主面上に例えばレジスト材で構成される注入マスクM1をパターニングする。なお、以下の説明では、注入マスクはレジスト材で構成されるものとする。
以下、図7~図9を用いて実施の形態1の変形例1による終端領域の構成および製造方法について説明する。
図5および図9にそれぞれ示したリサーフ層101および102においては、実効的な注入量で定義されるリサーフ層を構成する各小領域の幅は何れも同じとなるように構成されていたが、図10に示すリサーフ層103のように、実効的な注入量で定義されるリサーフ層においては、注入量が多い方の小領域の幅は一定とし、注入量が少ない方の小領域の幅は、装置の外側に向かって徐々に広くなる構成としても良い。
図12および図13を用いて、本発明に係る実施の形態2の終端領域の構成および製造方法について説明する。
図12および図13は終端領域の製造工程を順に示す断面図であり、終端領域の最終的な構成は、最終工程を示す図13にリサーフ層101として示す。なお、本実施の形態においては、最終的に得られるリサーフ層の構成は実施の形態1の図5に示したリサーフ層101と同じであるが、製造方法において実施の形態1とは異なっている。
以下、図12および図13を用いてリサーフ層101の形成方法について説明する。まず、図12に示すように、活性領域2を形成した側の主面上に注入マスクM21をパターニングする。
以上説明した実施の形態2では、2回の注入プロセスでの注入深さを同一にしているが、注入プロセスによって注入深さを変えても良い。以下、図16および図17を用いて実施の形態2の変形例1による終端領域の構成および製造方法について説明する。
また、注入プロセスによって注入深さを変える方法としては、図18および図19に示す方法を用いても良い。
また、活性領域が図1で示すようなP型ベース2のみで構成されるダイオード100であれば、P型ベース2全体にもリサーフ層の注入を行っても良い。この方法について、図20および図21を用いて説明する。
実施の形態2では、2回の注入プロセスにより、実効的な注入量が半導体装置の外側に向かって5段階ないしは6段階で漸減するリサーフ層を形成する構成および製造方法を説明したが、これは2回以上のn回の注入プロセスに定式化することができる。以下、本発明に係る実施の形態3として、n回の注入プロセスでリサーフ層を形成する構成および製造方法について説明する。
ここで、n=3の例について図22~図24を用いて説明する。上記理論に基づけば、3回の注入プロセスで7段階の注入量を有するリサーフ層を形成できる。
次に、図22~図24を用いてリサーフ層121の形成方法について説明する。まず、図22に示すように、活性領域2を形成した側の主面上に注入マスクM71をパターニングする。
次に、実施の形態1および2において説明した、異なる注入量の小領域を多重に交互に配列した領域を設けて、実効的な注入量の階調を増やす場合についての定式化を行う。
図25~図27は終端領域の製造工程を順に示す断面図であり、終端領域の最終的な構成は、最終工程を示す図27にリサーフ層122として示す。
以上説明した実施の形態3では、3回の注入プロセスでの注入深さを同一にしているが、注入プロセスによって注入深さを変えても良い。以下、図28~図30を用いて実施の形態3の変形例1による終端領域の構成および製造方法について説明する。
実施の形態3の変形例2として、異なる注入量の小領域を多重に交互に配列した領域を設けて、実効的な注入量の階調を増やす構成において、注入プロセスによって注入深さを変えた場合の構成について、図31~図33を用いて説明する。
実施の形態1~3においては、本発明をPNダイオードに適用した場合について説明したが、P型不純物を比較的高濃度に含むP型注入層(P型ウエル)を有するMOSFETはもちろんのこと、ショットキーバリアダイオードの終端領域にも適用して、終端領域での電界集中を緩和することができる。
実施の形態1~3においては、本発明をPNダイオードに適用した場合について説明したが、LDMOSFET(Laterally Diffused MOSFET)にも適用して高濃度注入層端縁部における電界集中を緩和することができる。
実施の形態1~3では縦型デバイスへの適用例を示したが、横型デバイスでも、デバイス周縁部(終端領域)に耐圧を保持する機構が必要な場合は、同様のリサーフ構造を適用することができる。
Claims (15)
- 第1導電型の半導体層(1)の表面内に形成された活性領域(2)と、
前記活性領域の端縁部から外側に向けて、前記活性領域を囲むように配設された第2導電型の不純物領域で規定される複数の電界緩和層と、を備え、
前記複数の電界緩和層は、前記活性領域側から外側に向かうにつれて不純物注入量が少なくなるように構成され、
前記複数の電界緩和層は、
その領域全体が第1の面密度で第2導電型の不純物が注入された第1の電界緩和層と、
その領域全体が第2の面密度で第2導電型の不純物が注入された第2の電界緩和層と、
前記第1の電界緩和層よりも平面方向の幅が狭く、前記第1の面密度で第2導電型の不純物が注入された第1の小領域と、前記第2の電界緩和層よりも平面方向の幅が狭く、前記第2の面密度で第2導電型の不純物が注入された第2の小領域とが、それぞれ交互に複数配設された第3の電界緩和層とを有し、
前記第3の電界緩和層は、前記第1の電界緩和層と前記第2の電界緩和層との平面方向の間に配置され、前記第3の電界緩和層の平均の面密度は、前記第1の面密度と前記第2の面密度との間の値となる、半導体装置。 - 前記複数の電界緩和層は、
前記活性領域側を先頭とした場合に最終段となる最終電界緩和層が、
前記最終電界緩和層の1つ前に位置する最終直前電界緩和層よりも平面方向の幅が狭く、前記最終直前電界緩和層と同じ面密度で第2導電型の不純物が注入された第3の小領域と、前記半導体層に第2導電型の不純物を注入しない非注入領域とがそれぞれ交互に複数配設された構成を有する、請求項1記載の半導体装置。 - 前記第2の電界緩和層は、
その不純物領域の注入深さが前記第1の電界緩和層の不純物領域の注入深さよりも深い、請求項1記載の半導体装置。 - 前記第2の電界緩和層の前記不純物領域と同時に同じ深さ同じ不純物濃度で形成される不純物領域は、前記第1の電界緩和層の前記不純物領域と同時に同じ深さ同じ不純物濃度で形成される不純物領域を断面方向に包含する、請求項3記載の半導体装置。
- 前記第1の電界緩和層が、前記活性領域に隣接して設けられる場合、前記第1の電界緩和層を構成する前記不純物領域が、前記活性領域の端縁部、または全体を覆うように前記不純物領域の注入深さおよび注入領域が設定される、請求項1記載の半導体装置。
- 前記第1の電界緩和層が前記活性領域を兼用する、請求項5記載の半導体装置。
- 前記第3の電界緩和層は、
前記第1および第2の小領域のうち、注入量が多い方の平面方向の幅は一定とし、注入量が少ない方の小平面方向の幅は、前記活性領域から離れる方向に向けて徐々に広くなるように形成される、請求項1記載の半導体装置。 - 前記第3の電界緩和層は、
前記第1および第2の小領域のうち、注入量が多い方の平面方向の幅は前記活性領域から離れる方向に向けて徐々に狭くなり、注入量が少ない方の小平面方向の幅は、前記活性領域から離れる方向に向けて徐々に広くなるように形成される、請求項1記載の半導体装置。 - 前記活性領域は、PN接合ダイオードのアノード領域に対応する、請求項1記載の半導体装置。
- 前記活性領域は、ショットキーバリアダイオードのショットキー電極下部の領域に対応する、請求項1記載の半導体装置。
- 前記活性領域は、MOSFET、IGBT、BJTを含むトランジスタの一部の領域に対応する、請求項1記載の半導体装置。
- 前記活性領域は、前記半導体層の主面上に、平面方向に、ソース電極(95)、ゲート電極(93)およびドレイン電極(97)が配置されるLDMOSFET(Laterally Diffused MOSFET)のドレイン領域に相当し、
前記複数の電界緩和層は、前記ドレイン領域とソース領域を含むウエル領域との間に配設される、請求項11記載の半導体装置。 - 前記半導体層は、ワイドバンドギャップ半導体によって構成される、請求項1記載の半導体装置。
- 請求項1記載の半導体装置の製造方法であって、
(a)前記半導体層上に、第1の注入マスクを形成し、前記第1の面密度で第2導電型の不純物をイオン注入して前記第1の電界緩和層および前記第1の小領域を形成する工程と、
(b)前記工程(a)の後、前記半導体層上に、第2の注入マスクを形成し、前記第2の面密度で第2導電型の不純物をイオン注入して前記第2の電界緩和層および前記第2の小領域を形成する工程と、を含む、半導体装置の製造方法。 - 請求項1記載の半導体装置の製造方法であって、
(a)前記半導体層上に、第1の注入マスクを形成し、前記第2の面密度で第2導電型の不純物をイオン注入して前記第2の電界緩和層と同じ不純物層を前記第1の電界緩和層の形成領域に及ぶように形成するとともに前記第2の小領域を形成する工程と、
(b)前記工程(a)の後、前記半導体層上に、少なくとも前記第2の電界緩和層上を覆う第2の注入マスクを形成し、前記第2の面密度に加えることで前記第1の面密度となる面密度で第2導電型の不純物をイオン注入して前記第1の電界緩和層および前記第1の小領域を形成する工程と、を含む、半導体装置の製造方法。
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US8716717B2 (en) | 2014-05-06 |
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KR20130063002A (ko) | 2013-06-13 |
DE112011103469T5 (de) | 2013-08-01 |
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