JP6544807B2 - Method of manufacturing semiconductor having gettering layer, method of manufacturing semiconductor device, and semiconductor device - Google Patents

Description

  The present invention relates to a method of manufacturing a semiconductor having a gettering layer, a method of manufacturing a semiconductor device, and a semiconductor device.

  Gettering technology (see Non-Patent Document 1) for providing a gettering effect to a silicon wafer is classified into intrinsic gettering (hereinafter referred to as IG) technology and extrinsic gettering (hereinafter referred to as EG) technology. In the former case, oxygen originally contained in a silicon wafer is coagulated and deposited by high temperature heat treatment to form a defect in the silicon wafer, and a straining field is formed around the defect to give a gettering effect. The latter is to impart a gettering effect by applying a strain field or a chemical action from the outside of the silicon wafer.

  Among the EG techniques, there is a laser irradiation method, which utilizes a laser induced defect as a gettering source. For example, ultrashort pulse laser (refer to patent document 1), near infrared laser (refer to patent document 2), KrF excimer laser (refer to non-patent document 1) or Q switch Nd: YAG laser (refer to non-patent documents 2 and 3) It has been attempted to induce a fractured layer (crystal defect) in the vicinity of the surface layer of a Si wafer using a light source as a light source to capture (gettering) and remove metal impurities.

Specifically, in Patent Document 1, an ultrashort pulse laser (pulse width: 1.0E-15 to 1.0E-8 sec; wavelength 300 to 1200 nm) is irradiated to obtain gettering to a depth of about several tens of μm. Laser gettering techniques have been proposed to make layers (including amorphous layers).
Patent Document 2 proposes a laser gettering technology for emitting a near infrared laser to form a fractured layer less than 1 μm thick at a certain depth of a silicon wafer less than 100 μm thick.
Regarding EG technology, Non-Patent Document 1 introduces gettering technology using a KrF excimer laser, and Non-Patent Documents 2 and 3 introduce gettering technology using a Q-switched Nd: YAG laser.

In Patent Document 3, boron is ion-implanted on the back surface of the silicon substrate, and B12 clusters are generated inside the silicon by ion-implanting boron which will be 2 × 10 ²⁰ / cm ³ or more. This cluster is a metal impurity ion in the silicon substrate Techniques for gettering have been devised.

In Patent Document 4 "Method for producing silicon wafer", a single crystal wafer is produced by the conventional Czochralski method by doping the back surface of the silicon substrate with an impurity of oxygen, carbon, or nitrogen by laser irradiation. It is making impossible wafers that are partially heavily doped with impurities. In this technology, the element in the Si wafer, oxygen is 1.0 × 10 ¹⁸ to 2.0 × 10 ¹⁹ / cm ³ , carbon is 1.0 × 10 ¹⁷ to 1.0 × 10 ¹⁸ / cm ³ , nitrogen is After the wafer is subjected to a high-temperature heat treatment (slip evaluation heat treatment) at a temperature of 1200 ° C. for one hour in an inert gas atmosphere with a concentration of 1.0 × 10 ¹⁵ to 1.0 × 10 ¹⁷ / cm ³ The gettering ability is high by performing a two-step heat treatment (BMD density evaluation heat treatment) of performing heat treatment at a temperature of 1000 ° C. for 16 hours in an oxidation atmosphere, followed by heat treatment at a temperature of 800 ° C. for 4 hours in an oxidation atmosphere. Techniques for manufacturing wafers have been devised.

  According to the Technology Roadmap (Semiconductor Technology Roadmap of Japan: STRJ) of the three-dimensional structure SiP, the thickness of the silicon wafer is expected to be 10 μm in recent years, and the device structure on the surface of the ultra-thin Si wafer It is necessary to newly form a gettering layer on the back surface so as not to cause heat damage. Therefore, EG method capable of low temperature process is already mainstream as gettering technology.

JP, 2010-283220, A Unexamined-Japanese-Patent No. 2007-165706 JP, 2013-201275, A JP, 2012-4939, A

Semiconductor World January 1987, pp. 88-95, "Crystal defects and gettering technology for ultra LSI wafers" Y. Hayafuji, T. Yanada, and Y. Aoki: JOURNAL OF THE ELECTROCHEMICAL SOCIETY 128 (1981) p. 1975, "Laser Damage Gettering and Its Application to Lifetime Improvement in Silicon" C. W. Pearce and V. J. Zaleckas: JOURNAL OF THE ELECTROCHEMICAL SOCIETY 126, No. 8 (1979) p. 1436, "A New Approach to Lattice Damage Gettering"

  In the technique for forming a gettering layer of a silicon wafer used in a three-dimensional stacked semiconductor device, in the EG method capable of low temperature processing, a laser is used after grinding and thinning the back side as a surface on which the device structure is provided. It emits light. However, if the thickness of the silicon wafer is extremely thin at 10 μm, there is a problem that the silicon wafer is easily broken due to damage of the formed fractured layer and the like.

The technique of Patent Document 3 has a problem that the apparatus becomes expensive because ion implantation is used, and the required dose amount is as large as 3 × 10 ¹⁶ / cm ² .
In the technique of Patent Document 4, it is an object of laser irradiation to dissolve oxygen, carbon and nitrogen in a Si wafer, and the subsequent high temperature heat treatment is indispensable for the expression of gettering ability. Therefore, there is a problem that the gettering layer formation processing by high temperature heat treatment can not be performed after forming the device on the laser non-irradiated surface.

  The present invention has been made against the background described above, and by performing laser irradiation on a semiconductor on which an impurity-containing film is formed during gettering processing, an effective gettering layer is provided without causing thermal damage to the semiconductor. Can be formed on a semiconductor surface, and it is an object of the present invention to provide a method of manufacturing a semiconductor, a method of manufacturing a semiconductor device, and a semiconductor device having a gettering layer which is less likely to be cracked even when the silicon wafer is thinned. One of the

That is, among the methods for producing a semiconductor having a gettering layer according to the present invention, the first present invention is a method for producing a semiconductor having a gettering layer, which is the back side of the surface on which the device structure is provided. A film forming step of forming an impurity-containing film which is a boron oxide film on one surface;
And the melting step of melting the semiconductor surface layer by irradiating the semiconductor with laser light from the one surface side, and in the melting step, impurities are doped in the melted semiconductor to form a high concentration region of impurities Forming the gettering layer, and the laser beam passes through the impurity-containing film and has a wavelength of 510 to 540 nm absorbed by the surface layer of the semiconductor, and the half width is 300 ns or less The impurity containing layer is irradiated with an energy density of 0.5 to 6.0 J / cm ² .
A method of manufacturing a semiconductor having a gettering layer according to a second aspect of the present invention is characterized in that in the first aspect of the present invention, the impurities to be doped in the semiconductor are boron and oxygen.
A method of manufacturing a semiconductor having a gettering layer according to a third aspect of the present invention is a method of manufacturing a semiconductor having a gettering layer,
A film forming step of forming a carbon-containing film or an impurity-containing film which is a film containing boron and carbon on one surface of the semiconductor which is the back side of the surface on which a device structure is provided;
And a melting step of melting the semiconductor surface layer by irradiating the semiconductor with a laser beam from the one surface side,
The gettering layer is formed by doping the impurity into the melted semiconductor to form a high concentration region of the impurity in the melting step;
The laser beam has a wavelength of 510 to 540 nm absorbed by the impurity-containing film, is irradiated with a half-width of 300 ns or less, and has an energy density of 0.5 to 6.0 J / cm ^2. The semiconductor surface layer is melted by heat conduction from the impurity-containing film which has been heated to a high temperature by the laser light irradiation.
The method of manufacturing a semiconductor having a gettering layer according to a fourth aspect of the present invention is the semiconductor device according to the third aspect , wherein the laser light is absorbed by the impurity-containing film by irradiation of the laser light to become high temperature The semiconductor surface layer is melted by heat conduction from the semiconductor device.
According to a fifth aspect of the present invention, there is provided a method of manufacturing a semiconductor having a gettering layer according to the third or fourth aspect , wherein the impurity to be doped in the semiconductor is any of carbon and oxygen and boron and carbon and oxygen. It is characterized in that it is a combination of
In the method for producing a semiconductor having a gettering layer according to a sixth aspect of the present invention, in any one of the first to fifth aspects of the present invention, in the film forming step, a liquid containing an impurity and a solvent is used as the semiconductor It is characterized in that the film is coated on the one surface of the film and then fired to form the impurity-containing film.
According to a seventh aspect of the present invention, in the method of manufacturing a semiconductor having the gettering layer, in any of the first to sixth aspects of the present invention, crystal defects caused by high concentration impurities are formed in the high concentration region. It is characterized by
In the method of manufacturing a semiconductor having a gettering layer according to an eighth invention, in the seventh invention, the crystal defect is disturbed by the crystal plane of the semiconductor by impurities other than high concentration oxygen and oxygen. It is characterized by having a stacking fault in which the crystal orientation or / and the crystal lattice spacing are shifted.
According to a ninth aspect of the present invention, there is provided a method of manufacturing a semiconductor having a gettering layer according to any one of the first to eighth aspects of the present invention, including the steps of: forming a circuit on the other surface of the semiconductor; And polishing the one surface side of the semiconductor having the circuit formed thereon for thinning.

According to a tenth aspect of the present invention, there is provided a method of manufacturing a semiconductor device according to any of the first to ninth aspects of the present invention, the semiconductor having the gettering layer manufactured according to any of the first to ninth aspects of the present invention is stacked. And electrically connect the stacked semiconductors by the through electrodes.

The semiconductor device according to the eleventh aspect of the present invention has a circuit formed on the main surface, and the impurity is formed by the method of manufacturing a semiconductor having the gettering layer according to any one of the first to ninth aspects on the back side of the thinned semiconductor. The semiconductor device is characterized in that a gettering layer is formed in the semiconductor by a high concentration region of impurities.
The semiconductor device according to a twelfth aspect of the present invention is the semiconductor device according to the eleventh aspect , wherein the impurity-containing film is a boron oxide film or a carbon-containing film, or a film containing boron and carbon, and doped with high concentration in silicon. The impurity to be contained is characterized by being constituted by any combination of boron and oxygen, carbon and oxygen, boron and carbon and oxygen.
The semiconductor device according to a thirteenth aspect of the present invention is characterized in that, in the eleventh or twelfth aspect of the present invention, a crystal defect caused by a high concentration impurity is formed in the high concentration region.
In the semiconductor device according to the fourteenth aspect of the present invention, in the semiconductor device according to the thirteenth aspect , the crystal defect of the semiconductor is disturbed by high concentration of boron and oxygen so that crystal orientation or / and crystal lattice spacing is deviated. It is characterized by having a stacking fault.
The semiconductor device according to a fifteenth aspect of the present invention is the semiconductor device according to any of the eleventh to fourteenth aspects, wherein a semiconductor having a gettering layer is laminated on the back surface, and a penetrating electrode is provided inside the laminated semiconductor. The semiconductors stacked by electrodes are electrically connected.
A semiconductor device according to a sixteenth aspect of the present invention is characterized in that, in any one of the eleventh to fourteenth aspects of the present invention, the semiconductor is semiconductor silicon.

  In the present invention, laser light is irradiated from the side of the impurity-containing film to melt the impurity-containing film and the semiconductor surface layer, so that the semiconductor surface layer is inexpensive and has a high concentration of impurities at high throughput without using ion implantation. Can be doped with Further, by doping the melted semiconductor to a high concentration of impurities, a high concentration region of the impurities is formed, and there is an excellent effect that a gettering ability can be provided to the semiconductor surface layer. In addition, since a low thermal load can be treated by laser light irradiation, even when a circuit is formed on the other surface side, the treatment can be performed without giving heat damage to the circuit on the surface of the semiconductor. Furthermore, since the laser irradiation surface is flat, the bending strength of the wafer is high, and there is also an effect that it is difficult to be broken.

  In the present invention, a crystal defect caused by the high concentration region is formed in the high concentration region of the doped impurity, and the formed crystal defect causes the crystal plane of the semiconductor to be slightly disturbed by the high concentration impurity. Causes stacking faults with slightly misaligned crystal orientations and / or crystal lattice spacings, and does not give a large strain to the semiconductor, and a strong gettering site of metal impurities such as Cu even at a low temperature of about 300 ° C. to 500 ° C. It has a very good effect of acting as

  In the present invention, the high impurity concentration region contains a very large amount of impurities but does not significantly distort the semiconductor substrate, and a strong getter of metal impurities such as Cu even at a low temperature of about 300 ° C. to 500 ° C. It has a very good effect of functioning as a ring site.

It is a flowchart of Embodiment 1 of the present invention. It is density distribution of the depth direction of boron, oxygen, and Cu of the present invention. It is a drawing substitute photograph of the TEM image of the surface layer of the high concentration impurity diffusion layer formed by the boron containing film of the present invention. It is process drawing of Embodiment 2 of this invention. It is concentration distribution of the carbon, oxygen, and Cu of this invention in the depth direction. It is a drawing substitute photograph of the TEM image of the surface layer of the high concentration impurity diffusion layer formed of the carbon containing film of the present invention. It is process drawing of Embodiment 3 of this invention. It is process drawing of Embodiment 4 of this invention. It is a flowchart of Embodiment 5 of the present invention.

(Embodiment 1)
Hereinafter, Embodiment 1 of the present invention will be described based on FIGS. 1 (a) to 1 (e). FIG. 1A is a view of a silicon wafer 1 used in the present embodiment, and the silicon wafer 1 corresponds to the semiconductor of the present invention.
The silicon wafer 1 may have the device layer 2 (including the wiring layer and the like) formed on the main surface 1a through various processes as shown in the drawing, or several tens of μm (eg, 100 μm, for example) by thinning. Furthermore, for example, a thin wafer with a thickness of 50 μm or less may be used, or a normal thick wafer may be used. The silicon wafer 1 may be divided into chips.

FIG. 1 (b) shows the process of forming the impurity-containing film. In this step, an impurity-containing film is formed on the back surface 1 b side of the silicon wafer 1. Various film forming processes can be used to form the film. The back surface 1b corresponds to one surface in the method of the present invention.
First, the formation of the boron-containing film will be described. In the method using coating, a raw material solution for a boron-containing film is prepared, and an impurity-containing raw material liquid film 3a is formed on the back surface 1b side of the silicon wafer 1 by a method such as spin coating. As a raw material liquid for a boron-containing film, for example, PBF polymer which is a reaction product of polyvinyl alcohol and boron oxide can be used. The coating method may be a method other than spin coating, such as a slit coater.

Next, as shown in FIG. 1 (c), the PBF polymer in the film is decomposed at a temperature of 100 ° C. to 400 ° C. to dry and calcine the impurity-containing raw material liquid film 3a to form boron oxide (B ₂ O ₃ ). Form Thus, the impurity-containing film 3b is obtained. Under the present circumstances, decomposition | disassembly may be inadequate and components, such as PBF polymer and a binder, may remain in a film | membrane. The boron-containing film after drying and firing can be formed with a thickness of, for example, 100 nm to 200 nm, but the thickness is not limited to this range. However, since the reflectance for incident light changes depending on the wavelength of the laser beam 4 to be irradiated and the optical characteristics and thickness of the impurity-containing film 3b, it is desirable to make the thickness such that the reflectance is minimum in order to reduce reflection loss.

Further, as another method of forming the impurity-containing film 3b, formation by various vacuum film formation processes such as vacuum evaporation, sputtering, and CVD is also possible. In these film forming methods, the impurity-containing film 3b can be formed directly. As a film to be formed, boron (B), boron oxide (B ₂ O ₃ ), a mixture of silicon and boron (Si: B), a mixture of silicon oxide and boron (SiO ₂ : B), a mixture of silicon and boron oxide (Si: B ₂ O ₃ ), a mixture of silicon oxide and boron oxide (SiO ₂ + B ₂ O ₃ ) can be exemplified. However, the present invention is not limited to these, as long as it contains boron. Preferably, the adhesion between the silicon wafer 1 and the film is improved by various cleaning before the formation of the boron-containing impurity-containing film 3b. For example, in the case where the adhesion is improved by making the surface of the silicon wafer 1 hydrophilic, SC1 cleaning or the like consisting of ammonia water and hydrogen peroxide solution can be performed. The cleaning method is not particularly limited, and various methods can be adopted.

FIG. 1 (d) shows a laser irradiation process. As an example of the present invention, the case of irradiating a laser having a wavelength that transmits the B ₂ O ₃ film will be described. As an example, the laser beam 4 with a wavelength of 515 nm can be irradiated from the side (back side 1 b side) of the impurity-containing film 3 b of the silicon wafer 1 under the conditions of energy density 6 J / cm ² and pulse half width 300 ns.
The pulse half width and energy density of the laser beam 4 are good as long as they are transmitted through the impurity-containing film 3 b and absorbed by the silicon wafer 1 and the surface layer of the silicon wafer 1 and a part of the impurity-containing film are melted. And can be selected as appropriate. Although the present invention is not limited to a specific condition, for example, a wavelength in the green region of preferably 510 to 540 nm can be suitably used. Thereby, high output can be obtained in consideration of throughput. The half pulse width is preferably 500 ns or less, and more preferably 300 ns or less. The energy density may be, for example, 0.5 to 6.0 J / cm ² to cause melting.

  In this embodiment, since the laser light 4 is a wavelength that is mainly transmitted through the impurity-containing film 3 b and absorbed by the surface layer of the silicon wafer 1, the film is prevented from peeling off, evaporating or scattering at the time of laser light irradiation Since laser irradiation can be performed in a state where the impurity-containing film is in close contact with the silicon wafer, the interface between the silicon substrate and the impurity-containing film can be stably melted. As a result, the melting depth and high impurity doping concentration can be realized with good reproducibility. There is an excellent effect of being able to Secondary to this, for example, it also has the effect of preventing contamination of the optical system by a boron compound.

  In consideration of the thickness and the effect of the gettering layer, the melting depth is preferably 2 μm or less. If the melting depth is relatively large with respect to the thickness of the silicon wafer 1, the device layer 2 of the silicon wafer 1 is easily affected by heat, so the melting depth is more preferably 1.0 μm or less, and 0.5 μm or less Is more desirable. Melting depth can be controlled by energy density and pulse half width. The thickness of the gettering layer obtained as described above is desirably 1 μm or less at the deepest position with the surface of the silicon wafer 1 as a base point. For the same reason, the thickness of the gettering layer is preferably 0.5 μm or less, more preferably 0.25 μm or less on the same basis. In addition, the overlapping ratio (overlap ratio) in the minor axis direction and the major axis direction of the laser beam 4 is appropriately selected (for example, 50 to 90% in the minor axis direction, for example, 10% to 50% in the major axis direction). The present invention is not particularly limited.

Since the irradiated laser light 4 having a wavelength of 515 nm almost passes through the B ₂ O ₃ film, the transmitted laser light reaches the silicon wafer and is absorbed, thereby melting the surface layer of the silicon wafer 1. At that time, part or all of the B ₂ O ₃ film of the impurity-containing film 3 b at the boundary with the melted silicon 5 a is melted. Boron and oxygen are diffused as impurities into the melted silicon 5a.
In this embodiment, oxygen, which is one of the impurities, is contained and supplied in the impurity-containing film 3b. However, in the present invention, oxygen in the atmosphere at the time of melting, natural such as B or Si: B surface layer, etc. An oxide film, a natural oxide film of the surface layer of the silicon wafer, or all or a part of the film may be supplied from oxygen of a SiO ₂ film slightly formed on the surface layer of the silicon wafer by SC1 cleaning. And these may be a composite.

  In addition, in the case where an impurity-containing film having boron is formed as the impurity-containing film, similarly, the case where the light does not transmit even when the laser light 4 having a wavelength of 515 nm is irradiated. In that case, the boron film can be formed as thin as about several tens of nm, and the irradiated laser light 4 can be absorbed by the boron film, and the surface layer of the silicon wafer can be melted by thermal conduction from the high temperature boron film. At that time, the melted silicon becomes high temperature, and boron diffuses from the boron film interface into the melted silicon. As described above, when the semiconductor is indirectly melted by irradiating the impurity-containing film with laser light, the thickness of the impurity-containing film is preferably 10 to 100 nm, for example. However, in the present invention, the thickness is not limited to a specific range.

  FIG. 1 (e) shows the formation of the gettering layer. The molten silicon 5a which has been melted together with boron and oxygen is cooled and crystallized as single crystal silicon to return to a solid, and the boron and oxygen dissolved at that time are impurities of high concentration in the crystal of silicon Taken as Thus, the high concentration impurity diffusion layer 5b is formed. In addition, when the B film is formed, the C component can be diffused as an impurity from the binder component to form a gettering layer having the characteristics of both B and C. On the outermost surface side of the high concentration impurity diffusion layer 5b, an ultra high concentration impurity diffusion layer 5c having a further high impurity concentration is formed. The ultra-high concentration impurity diffusion layer 5c corresponds to a portion which is finally crystallized to return to a solid state in molten silicon which is returning to a solid state upon cooling, and the concentration of boron and oxygen as impurities in the crystal is very high. Therefore, as a result of disturbing the crystal orientation of silicon which is to be crystallized as a single crystal, stacking faults slightly different in lattice spacing and crystal orientation are formed. In the drawing, the remaining impurity-containing layer 3 c is seen on the back surface 1 b side of the silicon wafer 1. The remaining impurity-containing layer 3c may be formed by solidifying again in the surface layer a portion of boron and oxygen dissolved in the melted silicon 5a that were not finally taken into the silicon crystal.

SIMS analysis was performed on the concentration distribution of boron and oxygen in the depth direction for the semiconductor subjected to the steps in the above example. The results are shown in FIG.
Before analysis, the layer 3c containing impurities was completely removed and used as a sample. The boron and oxygen concentrations gradually increase in the surface layer from a depth of about 1.6 μm, and this portion melts, and boron and oxygen diffuse as impurities into the melted silicon 5a at a high concentration, and the high concentration impurity diffusion layer 5b It becomes. The boron concentration in the surface layer is a high concentration of 1E17 / cm ³ or more from a depth of about 1.2 μm, and the oxygen concentration in the surface layer is a concentration higher than 1E19 / cm ³ from a depth of about 1.0 μm. Furthermore, in the outermost layer of the surface layer at a depth of 60 nm, an ultra-high concentration impurity diffusion layer 5c having a very high concentration of boron and oxygen is formed, and this portion contains crystal defects. Boron and oxygen form similar peaks around a depth of about 20 nm, and the boron concentration is about 1E18 / cm ^{3 at} maximum, and the oxygen concentration is over 1E20 / cm ³ at a depth of 30 nm.

Since the density of normal solid silicon is about 5E22 / cm ³ , 0.5% is impurity oxygen and very high concentration. A TEM image of the ultra-high concentration impurity diffusion layer 5c on the surface side of the high concentration impurity diffusion layer 5b is shown in FIG. A moiré pattern of stripes is observed from the surface layer to a depth of about 20 nm, which indicates that stacking faults with slightly different lattice spacing and crystal orientation are formed in this region. This type of defect is classified as a surface defect. The silicon wafer on which the gettering layer is formed according to the present embodiment has sufficient bending strength in a flat mirror state as seen from the TEM image, and the silicon wafer is not large in distortion in the wafer. There is no warpage of The silicon wafer on which the gettering layer is formed corresponds to the semiconductor having the gettering layer in the present invention.

Next, the boron-containing impurity-containing layer 3c was completely removed from the silicon wafer on which the gettering layer was formed, and both surfaces were cleaned to evaluate the gettering ability. The evaluation method is the following.
Cleaning was performed until Cu was not detected completely from both sides of the silicon wafer, and the back side of the silicon wafer on which the gettering layer was formed was quantitatively contaminated so that the Cu concentration was about 1E11 / cm ² . Thereafter, the back surface of the silicon wafer was heated at 300 ° C. for 30 minutes to thermally diffuse Cu. Finally, the Cu concentration on the surface of the silicon wafer was measured to evaluate the Cu concentration diffused from the back surface to the front surface. In the evaluation of gettering ability, in order to take into consideration the individual differences existing for each silicon wafer, a gettering layer is formed on only half of one silicon wafer, and half is used as a reference without forming a gettering layer. . First, in the reference portion, Cu of 1.3E10 / cm ^{2 on} average was detected, but in the gettering layer forming portion, Cu was not detected at any measurement point. Thereafter, the Cu concentration was similarly measured after heating for 30 minutes each at 400 ° C. and 500 ° C., however, in the gettering layer forming portion, Cu was not detected at any measurement point. The Cu in FIG. 2 already shown is the concentration distribution of Cu in the depth direction after gettering evaluation, and Cu is captured with a peak of about 20 nm at which the concentration of boron and oxygen is extremely high, and is 20 nm from the surface layer The observation of stacking faults in the TEM image up to the depth indicates that this area works as a strong gettering site. Therefore, the gettering layer of the present embodiment has the gettering ability.

  According to the present embodiment, a crystal defect caused by the high concentration region of boron and oxygen is formed in the high concentration region of boron and oxygen, and the formed crystal defect is a silicon crystal due to the high concentration of boron and oxygen. A slight disturbance of the surface has stacking faults in which the crystal orientation or crystal lattice spacing is slightly deviated, so that the semiconductor substrate is not greatly distorted and even at a low temperature of about 300 ° C. to 500 ° C. It has a very excellent effect of functioning as a strong gettering site for metal impurities such as Cu.

Second Embodiment
In Embodiment 2, formation of a gettering layer using a carbon-containing film will be described. Since the main part is the same as that of Embodiment 1, only the different part will be described based on FIG.
FIG. 4B shows the process of forming the impurity-containing film. In the formation of the carbon-containing film, a raw material solution serving as a raw material of the carbon-containing film is prepared, and the impurity-containing film raw material liquid film 6a is formed on the back surface 1b of the silicon wafer 1 by spin coating or the like. For example, a mixture of carbon black and an organic binder can be used as a raw material solution for the carbon-containing film. Further, various resin films and polymer films formed by coating an acrylic resin can also be used. The coating method may be a method other than spin coating, such as a slit coater.

  Next, as shown in FIG. 4C, in order to dry the impurity-containing film raw material liquid film 6a, the organic binder in the film is dried at a temperature of about room temperature to 100 ° C. to form a carbon-containing film. Thus, the impurity-containing film 6b is obtained. At this time, the decomposition may be insufficient and the binder component may remain in the film. The carbon-containing film after drying can be formed, for example, with a thickness of 100 nm to 200 nm, but the thickness is not limited to this range. However, since the reflectance for incident light changes depending on the laser wavelength to be irradiated and the optical characteristics and thickness of the carbon-containing film, it is desirable to make the thickness such that the reflectance is minimum in order to reduce the reflection loss. Preferably, the adhesion between the silicon wafer and the film is improved by various cleaning before the formation of the carbon-containing film. For example, in the case where the adhesion is improved by making the surface of the silicon wafer 1 hydrophilic, SC1 cleaning consisting of ammonia water and hydrogen peroxide solution can be exemplified.

FIG. 4D shows a laser irradiation process. As an example of the present invention, a case where a black carbon-containing film formed of a mixture of carbon black and an organic binder is irradiated with laser light of a wavelength which does not pass through the film will be described. As an example, the laser beam 4 with a wavelength of 515 nm is irradiated from the side of the impurity-containing film 6 b of the silicon wafer 1 under the conditions of energy density 3 J / cm ² and pulse half width 300 ns. The pulse half width and energy density of the laser beam 4 are mainly absorbed by the impurity-containing film 6 b and may be appropriately selected as long as the surface layer of the silicon wafer is melted. Although this invention is not limited to a specific condition, the wavelength can use the wavelength of a green area | region of 510-540 nm, for example. Thereby, high output can be obtained in consideration of throughput. The half pulse width is preferably 1200 ns or less, and more preferably 300 ns or less. The energy density may be, for example, 0.5 to 6.0 J / cm ² to cause melting.

  However, in consideration of the thickness and the effect of the gettering layer, the melting depth is preferably 2 μm or less. If the melting depth is relatively large with respect to the thickness of the silicon wafer 1, the device layer 2 of the silicon wafer 1 is easily affected by heat, so the melting depth is more preferably 1.0 μm or less, and 0.5 μm or less Is more desirable. Melting depth can be controlled by energy density and pulse half width. The thickness of the gettering layer obtained as described above is preferably 1 μm or less at the deepest position with respect to the silicon wafer surface. For the same reason, the thickness of the gettering layer is desirably 0.5 μm or less on the same basis, and more desirably 0.25 μm or less.

In addition, the overlapping ratio (overlap ratio) in the minor axis direction and the major axis direction of the laser beam 4 is appropriately selected (for example, 50 to 90% in the minor axis direction, for example, 10% to 50% in the major axis direction). The present invention is not particularly limited. Since the irradiated laser beam 4 having a wavelength of 515 nm is substantially absorbed by the carbon-containing impurity-containing film 6b, the absorbed laser beam 4 is converted to heat, and the heat reaches the silicon wafer 1 and the silicon wafer surface layer Melt down. At this time, carbon and oxygen are diffused as impurities from the carbon-containing film at the boundary with the melted silicon 7a into the melted silicon 7a.
Further, when an acrylic resin film is formed as the impurity-containing film 6b, it corresponds to the case of transmitting the laser light 4 having a wavelength of 515 nm as well. In that case, the irradiated laser beam 4 having a wavelength of 515 nm almost passes through the acrylic resin film, reaches the silicon wafer 1 and is absorbed, thereby melting the silicon wafer surface layer. At that time, carbon and oxygen are diffused as impurities because a part or all of the acrylic resin film at the boundary with the melted silicon is taken into the melted silicon 7a.

  FIG. 4 (e) shows the formation of the gettering layer. The molten silicon 7a which has been melted together with carbon and oxygen is cooled and crystallized as single crystal silicon to return to a solid, and carbon and oxygen dissolved at that time are impurities of high concentration in the crystal of silicon Taken as Thus, the high concentration impurity diffusion layer 7b is formed. On the outermost surface side of the high concentration impurity diffusion layer 7b, an ultra-high concentration impurity diffusion layer 7c having a further high impurity concentration is formed. The ultra-high concentration impurity diffusion layer 7c corresponds to a portion which is finally crystallized to return to a solid state in molten silicon which is returning to a solid state upon cooling, but no noticeable defect is formed. In the drawing, the remaining impurity-containing layer 6 c is seen on the back surface 1 b side of the silicon wafer 1. The remaining impurity-containing layer 6c may be formed by solidifying again in the surface layer a portion of the carbon dissolved in the melted silicon 7a that has not been finally taken into the silicon crystal.

About the semiconductor which passed through the process in the said example, the result of a SIMS analysis is shown in FIG. 5 about concentration distribution of carbon and oxygen in the depth direction. Prior to analysis, the carbon-containing impurity-containing layer 6c was completely removed and used as a sample. The carbon and oxygen concentrations gradually increase in the surface layer from a depth of about 1.0 μm, and carbon and oxygen diffuse as impurities to a high concentration in the melted silicon 7a in this portion to form a high concentration impurity diffusion layer 7b. The carbon concentration in the surface layer is a high concentration of 1E19 / cm ³ or more from a depth of about 0.22 μm. Further, in the outermost layer of the surface layer from 100 nm, an ultra-high concentration impurity diffusion layer 7c having a very high concentration of carbon and oxygen is formed. Carbon and oxygen of about 30nm depth around forms a similar peak, carbon concentration up to 5E21 / cm at about ³ to 50nm depth exceeds 1E21 / cm ^3, an oxygen concentration up to 30nm depth 5E20 / cm ³ Is over.

Since the density of conventional solid silicon is about 5E22 / cm ^3, a carbon 10%, a very high concentration for 1% oxygen. A TEM image of the ultra-high concentration impurity diffusion layer 7c on the surface side of the high concentration impurity diffusion layer 7b is shown in FIG. Since the ultra-high concentration impurity diffusion layer 7c located on the surface side of the high concentration impurity diffusion layer 7b formed by this method has a slight surface roughness of about 10 nm, the structure of about 10 nm visible in the surface layer has this unevenness It is a region where the concentration of carbon and oxygen is particularly high at a depth of about 25 nm from there. No noticeable defects are observed from the surface layer to the deep portion of the high concentration impurity diffusion layer 7b, and no dislocation or stacking fault is considered to be formed. However, since approximately 10% of carbon is contained, it is possible that carbon atoms occupy a part of silicon atomic positions of single crystal silicon and may form a single crystal in which a part is substituted. Absent. By replacing carbon with carbon of different atomic size, strain or stress may be generated. Further, since dislocations and stacking faults are not formed, it is not clear that 10% of carbon atoms and 1% of oxygen atoms may be point defects such as interstitial atoms. The silicon wafer on which the gettering layer formed according to the present invention is formed has a slight surface roughness as seen from the TEM image, but has sufficient bending strength and a large distortion in the wafer. There is no warpage of the silicon wafer because it is not. The silicon wafer on which the gettering layer is formed in this embodiment corresponds to a semiconductor having the gettering layer of the present invention.

Next, the carbon-containing impurity-containing layer 6c was completely removed from the silicon wafer on which the gettering layer was formed, and both surfaces were washed to evaluate the gettering ability. The evaluation method is the following. Cleaning was performed until Cu was not detected completely from both sides of the silicon wafer, and the back side of the silicon wafer on which the gettering layer was formed was quantitatively contaminated so that the Cu concentration was about 1E11 / cm ² . Thereafter, the back surface of the silicon wafer was heated at 300 ° C. for 30 minutes to thermally diffuse Cu. Finally, the Cu concentration on the surface of the silicon wafer was measured to evaluate the Cu concentration diffused from the back surface to the front surface. In the evaluation of gettering ability, in order to take into consideration the individual differences existing for each silicon wafer, a gettering layer is formed on only half of one silicon wafer, and half is used as a reference without forming a gettering layer. . First, in the reference portion, Cu of an average of 2.1E10 / cm ² was detected, but in the gettering layer forming portion, Cu was not detected at any measurement point. Thereafter, the Cu concentration was similarly measured after heating for 30 minutes each at 400 ° C. and 500 ° C., however, in the gettering layer forming portion, Cu was not detected at any measurement point. Cu in FIG. 5 already shown is the concentration distribution of Cu in the depth direction after gettering evaluation, because Cu is captured with a peak at a depth of about 30 nm at which carbon and oxygen are very high concentration. This indicates that this area acts as a strong gettering site. Therefore, the gettering layer of the present embodiment has the gettering ability.

  According to the present embodiment, the high concentration region of carbon and oxygen contains a large amount of carbon and oxygen, but without giving a large strain to the silicon substrate, and at a low temperature of about 300 ° C. to 500 ° C. It has a very good effect of acting as a strong gettering site for metal impurities.

  In the first and second embodiments, a circuit is formed on the main surface, and a step of forming an impurity-containing film on the back surface of the silicon wafer thinned from the back surface side, and laser light is irradiated from the impurity-containing film side. The step of melting the impurity-containing film and the surface of the silicon wafer causes the molten silicon to be highly doped with boron, carbon, and oxygen, and causes crystal defects due to high concentration regions of boron and oxygen, and the reactive concentration of carbon and oxygen Since the gettering layer is formed on the back surface of the thinned silicon wafer by forming the region, metal impurities are gettered to the gettering layer even if metal contamination occurs, so that the yield is not lowered, and the semiconductor wafer is in use over the years It has an industrially excellent effect that the semiconductor device is less in failure or deterioration.

(Embodiment 3)
In the third embodiment, an example of a manufacturing process in the case of applying the silicon wafer 1 having the gettering layer of the present invention to a three-dimensionally stacked semiconductor device will be described based on FIG.
First, a silicon wafer 1 (for example, 775 μm thick) thicker than the final thickness is prepared, a device layer 2 is provided on the main surface of the silicon wafer 1, and electrode embedding and bumps 10 are performed on the device layer (FIG. 7 (a )). Next, the back surface side of the silicon wafer 1 is ground and polished to be thinned to, for example, about 10 μm thickness (FIG. 7B). After that, the impurity-containing raw material liquid film 3a is formed on the ground and polished back surface side ((FIG. 7 (c)). Thereafter, the impurity-containing raw material liquid film 3a is dried and fired to form the impurity-containing film 3b. Then, the laser beam 4 described above is irradiated from the surface side having the impurity-containing film 3b in the air to melt the surface layer portion of the silicon wafer 1 to generate the melted silicon 5a (FIG. 7 (d)). The melted silicon 5a has a depth of 2 μm or less from the surface on the back surface side, in which the impurity-containing film is melted by melting a part or all of the impurity-containing film, and boron is an impurity from the impurity-containing film 3b on the surface. And oxygen diffuse to dope a high concentration of impurities.

  Then, when the laser light 4 is pulse-off, the silicon is crystallized while taking in impurities from the liquid phase / solid phase interface toward the surface by quenching, thereby forming the high concentration impurity diffusion layer 5 b and the ultra high concentration impurity layer 5 c. The ultra-high concentration impurity layer 5c which is the outermost layer is formed. A layer having a further high impurity concentration including crystal defects and% high concentration impurities is formed in the ultrahigh concentration impurity layer 5c which is the outermost layer, and the high concentration impurity diffusion layer 5b including the high concentration impurity layer 5c is a getter. It has a function as a ring layer. The remaining impurity-containing film is removed if unnecessary. Subsequently, the process proceeds to a through silicon via (TSV) forming step, in which an overcoat 13 is first formed on the back side as TSV forming and a via 14 is opened on the back side (FIG. 7 (e)). Cu is embedded to form an electrode 11 (FIG. 7 (f)), and the overcoat 13 on the back side is further ground, and then a back bump 12 connected to the electrode 11 is formed (FIG. 7 (g)) Cut out. By sequentially stacking and joining these chips in the longitudinal direction, a semiconductor device in which a silicon wafer having a gettering layer is three-dimensionally stacked can be obtained.

(Embodiment 4)
Moreover, FIG. 8 is a figure which shows the process of using the impurity containing raw material liquid film 6a as an impurity containing layer. In addition, about the same structure as the above, the same code | symbol is attached | subjected and description is abbreviate | omitted. The high purity impurity diffusion layer 7b and the ultrahigh concentration impurity layer 7c are formed based on the impurity containing film 6b, and the semiconductor device can be manufactured by the same process.

  Although C to C in which chips are stacked on chips has been described in the third and fourth embodiments, silicon wafers having a gettering layer also by C to W in which chips are stacked on a wafer or W to W in which a wafer is stacked on a wafer Thus, a semiconductor device in which the three Furthermore, although the case where the TSV formation process is formed by the so-called via last method in which a via is opened from the back surface of the wafer after the formation of the device layer (including the wiring process) 2 is described here, the TSV formation process is included in the device layer The same can be applied to a via middle method in which a via is opened from the wafer surface after formation and an electrode is formed after the formation of the electrode by a via middle method.

  In the third and fourth embodiments, the semiconductor device according to the present invention has a through electrode inside a thinned silicon wafer, and one having a gettering layer on the back surface is stacked, and the wafers are stacked with the through electrode provided in the wafer. Can be used by electrically connecting them, which has the excellent effect of being able to produce a highly reliable three-dimensional laminated semiconductor.

Embodiment 5
In the fifth embodiment, an example of a manufacturing process in the case of applying to an SOI (Silicon On Insulator) wafer having a gettering layer of the present invention will be described based on FIG.
First, as the silicon wafer 21 used in the present invention, a silicon non-defective area 21 a formed on the surface layer (main surface) of the wafer is used for forming a device layer. In addition, a silicon epitaxial growth layer 21b may be formed on the surface layer of the wafer for forming a device layer (FIG. 9A).
Next, the impurity-containing film 3b or the impurity-containing film 6b of the present invention is formed on the side of the silicon non-defective region 21a or the silicon epitaxial growth layer 21b of the silicon wafer 21 and irradiated with the laser light 4 to obtain a gettering layer. A high concentration impurity diffusion layer 5b including the ultrahigh concentration impurity layer 5c or a high concentration impurity diffusion layer 7b including the ultrahigh concentration impurity layer 7c is formed (FIG. 9B). The impurity containing film 3b or the impurity containing film 6b is removed after the gettering layer is formed.

  Next, the insulating film 22 is formed on the high concentration impurity diffusion layer 5b or the high concentration impurity diffusion layer 7b, and the surface of the insulating film 22 is planarized. This planarization is performed by, for example, chemical mechanical polishing. As a result, the surface of the insulating film 22 is brought into a surface state adapted to the bonding with the support substrate. Next, the split layer 23 is formed in the silicon wafer 21 by hydrogen ion implantation. The position of the split layer 23 is, for example, inside the silicon non-defective region 21a (or the silicon epitaxial growth layer 21b) or before and after the boundary with the silicon wafer 21 so that the silicon wafer 21 can be peeled off in a later step. Here, the case of forming before and after the boundary with the silicon wafer 21 will be described. By injecting hydrogen ions, the fragile split layer 23 to be a split surface is formed (FIG. 9C).

Next, a support substrate 24 is attached on the insulating film 22. A silicon wafer is used as the support substrate 24. Alternatively, a glass substrate or a resin substrate can also be used. For bonding at this time, bonding using a heat resistant resin or bonding using plasma treatment is used (FIG. 9 (d)).
Next, the silicon wafer 21 side is peeled off by the split layer 23. As a result, the silicon non-defective region 21a or the silicon epitaxial growth layer 21b is formed on the support substrate 24 side. When split layer 23 is formed before and after the boundary between silicon non-defective region 21a or silicon epitaxial growth layer 21b and silicon wafer 21, silicon wafer 21 is partially left on silicon non-defective region 21a or silicon epitaxial growth layer 21b. . The peeling of the silicon wafer 21 is performed by, for example, thermal shock due to heat treatment at less than 400.degree. Or, it is performed by applying physical impact using nitrogen (N ₂ ) blow or pure water jet flow. Thus, processing at 400 ° C. or lower is possible. And since the split layer 23 formed by volume expansion of the implanted ion by ion implantation is a weak layer, peeling of the silicon wafer 21 in the split layer 23 is easy. At this time, the split surface 23a which is a part of the split layer remains on the surface layer of the silicon non-defective region 21a or the silicon epitaxial growth layer 21b (FIG. 9 (e)).

  Next, the split surface 23 a on the surface of the silicon non-defective region 21 a or the silicon epitaxial growth layer 21 b is planarized. This planarization process is performed by, for example, hydrogen annealing and polishing. This polishing uses, for example, chemical mechanical polishing (CMP). At this time, if the split surface 23a and the silicon wafer 21 remain, they are removed to expose the silicon non-defective region 21a or the silicon epitaxial growth layer 21b (FIG. 9 (f)).

  As described above, since an SOI wafer having the high concentration impurity diffusion layer 5b or the high concentration impurity diffusion layer 7b which is a gettering layer can be manufactured, the metal in the silicon non-defective region 21a or the silicon epitaxial growth layer 21b is high concentration impurity The gettering to the diffusion layer 5 b or the high concentration impurity diffusion layer 7 b is facilitated, and the influence of metal contamination can be eliminated. Therefore, the SOI substrate according to the manufacturing method of the present invention can be expected to have a gettering action during the device manufacturing process, be robust to the metal contamination level in the process, and enable high-quality, high-quality device manufacturing.

  As mentioned above, although this invention was demonstrated based on the said embodiment, unless it deviates from the scope of the present invention, an appropriate change is possible.

DESCRIPTION OF SYMBOLS 1 silicon wafer 1a main surface 1b back surface 2 device layer 3a impurity containing raw material liquid film 3b impurity containing film 3c impurity containing layer 4 laser beam 5a molten silicon 5b high concentration impurity diffusion layer 5c super high concentration impurity layer 6a impurity containing raw material liquid film 6b Impurity Containing Film 6c Impurity Containing Layer 7a Fused Silicon 7b High Concentration Impurity Diffusion Layer 7c Super High Concentration Impurity Layer 10 Bump 11 Electrode 12 Back Bump 13 Overcoat 14 Via 21 Silicon Wafer 21a Silicon Defective Area 21b Silicon Epitaxial Growth Layer 22 Insulation Membrane 23 Split Layer 23a Split Surface 24 Support Substrate

Claims (16)

A method of manufacturing a semiconductor having a gettering layer,
A film forming step of forming an impurity-containing film which is a boron oxide film on one surface of the semiconductor which is the back surface side of the surface on which a device structure is to be provided;
And a melting step of melting the semiconductor surface layer by irradiating the semiconductor with a laser beam from the one surface side,
The gettering layer is formed by doping the impurity into the melted semiconductor to form a high concentration region of the impurity in the melting step;
The laser beam passes through the impurity-containing film, has a wavelength of 510 to 540 nm absorbed by the surface layer of the semiconductor, and has a half width of 300 ns or less and an energy density of 0.5 to 6.0 J / cm ² A method of manufacturing a semiconductor having a gettering layer characterized in that the impurity-containing layer is irradiated. The method of claim 1, wherein the impurities doped in the semiconductor are boron and oxygen. A method of manufacturing a semiconductor having a gettering layer,
A film forming step of forming a carbon-containing film or an impurity-containing film which is a film containing boron and carbon on one surface of the semiconductor which is the back side of the surface on which a device structure is provided;
And a melting step of melting the semiconductor surface layer by irradiating the semiconductor with a laser beam from the one surface side,
The gettering layer is formed by doping the impurity into the melted semiconductor to form a high concentration region of the impurity in the melting step;
The laser beam has a wavelength of 510 to 540 nm absorbed by the impurity-containing film, is irradiated with a half-width of 300 ns or less, and has an energy density of 0.5 to 6.0 J / cm ^2. A method of manufacturing a semiconductor having a gettering layer, wherein the surface layer of the semiconductor is melted by heat conduction from the impurity-containing film which has been heated to a high temperature by the irradiation of the laser light. 4. The gettering layer according to claim 3 , wherein the semiconductor surface layer is melted by heat conduction from the impurity-containing film which is absorbed by the impurity-containing film and becomes high temperature by the irradiation of the laser light. Semiconductor manufacturing method. Impurity to be doped in the semiconductor is carbon and oxygen, boron and wherein the carbon and oxygen, a combination of any of the semiconductor manufacturing method having a gettering layer according to claim 3 or 4 . In the film forming step, coating an impurity-containing solution having said impurity and a solvent on said one surface of said semiconductor film, then, claim fired to characterized in that said impurity-containing layer 1-5 A method of manufacturing a semiconductor having the gettering layer according to any one of the above. The method for manufacturing a semiconductor having a gettering layer according to any one of claims 1 to 6 , wherein a crystal defect caused by a high concentration impurity is formed in the high concentration region. The crystal defect is characterized in that the crystal plane of the semiconductor is disturbed by impurities other than high concentration oxygen and oxygen, and the crystal defect has a stacking fault in which crystal orientation or / and crystal lattice spacing is deviated. 7. A method of manufacturing a semiconductor having the gettering layer according to 7 . The method further comprises the steps of: forming a circuit on the other surface of the semiconductor; and polishing the one surface side of the semiconductor on which the circuit is formed to thin the layer before the film forming step. semiconductor manufacturing method having a gettering layer according to any one of 1-8. A semiconductor having a gettering layer manufactured by the method according to any one of claims 1 to 9 is stacked, a through electrode is provided inside the stacked semiconductor, and the stacked semiconductors are electrically connected by the through electrode. A manufacturing method of a semiconductor device characterized by doing. An impurity is doped in the semiconductor according to the method for producing a semiconductor having a gettering layer according to any one of claims 1 to 8 , wherein a circuit is formed on the main surface, and the semiconductor is thinned on the back side. 1. A semiconductor device characterized in that a gettering layer is formed by a high concentration region. The impurity-containing film is a boron oxide film or a carbon-containing film, or a film containing boron and carbon, and the impurities to be highly doped in silicon include boron and oxygen, carbon and oxygen, boron and carbon and oxygen The semiconductor device according to claim 11 , wherein the semiconductor device is configured by any combination of the above. The high the concentration region, the semiconductor device according to claim 11 or 12, characterized in that crystal defects due to the high concentration impurity is formed. 14. The semiconductor according to claim 13 , wherein the crystal defects have stacking defects in which crystal planes of the semiconductor are disturbed by high concentrations of boron and oxygen, and crystal orientation or / and crystal lattice spacing is deviated. apparatus. Semiconductor having a gettering layer is laminated on the back surface has a stacked semiconductor inside the through electrodes, claims 11 to 14, between the semiconductor laminated by the through electrode is characterized in that it is electrically connected The semiconductor device according to any one of the above. The semiconductor device according to any one of claims 11 to 14 , wherein the semiconductor is semiconductor silicon.