JP5535610B2 - SOI semiconductor substrate manufacturing method - Google Patents

Description

  The present invention relates to an SOI semiconductor substrate manufacturing method and an SOI semiconductor substrate manufacturing apparatus, and more particularly, an SOI (Silicon On Insulator) semiconductor in which a semiconductor layer formed from a semiconductor is formed on an insulator layer formed from an insulator. The present invention relates to an SOI semiconductor substrate manufacturing method and an SOI semiconductor substrate manufacturing apparatus for manufacturing a substrate.

SOI substrates are known. The SOI substrate is formed by stacking a semiconductor layer, a support substrate layer, and an insulator layer. The semiconductor layer is formed of a semiconductor exemplified by silicon Si, silicon carbide SiC, and gallium arsenide GaAs. The support substrate layer is formed of a semiconductor exemplified by silicon Si. The insulator layer is formed from an insulator exemplified by silicon dioxide SiO ₂ . The insulator layer is formed from an insulator exemplified by silicon dioxide SiO ₂ . The semiconductor layer and the support substrate layer are electrically insulated. Such an SOI substrate is used for a high voltage semiconductor device because its semiconductor layer is electrically insulated from its supporting substrate layer. Such an SOI substrate is further used as a substrate for a high-speed and highly integrated circuit by making its semiconductor layer very thin. Such an SOI substrate is further used as a material for manufacturing a MEMS device. When a structure is manufactured by etching, the structure is formed by utilizing a difference in etching characteristics between the semiconductor layer and the insulator layer. It is formed.

FIG. 1 shows a known SOI substrate manufacturing method. In the SOI substrate manufacturing method, first, the active layer substrate 101 and the support substrate 106 are manufactured. The active layer substrate 101 is formed of a semiconductor layer 102 formed of a semiconductor and an insulator layer 103 formed of an insulator. That is, the active layer substrate 101 is formed by thermally oxidizing one surface of a semiconductor substrate formed from a semiconductor, or formed by forming a SiO ₂ film on one surface of the semiconductor substrate. The The support substrate 106 is a semiconductor substrate itself formed from a semiconductor (step S101). The surface of the active layer substrate 101 where the insulator layer 103 is exposed is cleaned (step S102) and subjected to a hydrophilic treatment (step S103). Examples of the hydrophilization treatment include a method of immersing in hydrogen peroxide solution after hydrofluoric acid treatment and a method of irradiating the surface with oxygen plasma. Next, the surface of the active layer substrate 101 that has been cleaned and hydrophilized is bonded to the surface of the support substrate 106 that has been cleaned and hydrophilized, and is heat-treated at 1000 ° C. for about 10 hours to be bonded to the support substrate 106. (Step S104). The bonded substrate 107 manufactured by the bonding is manufactured to the SOI substrate product 110 by thinly grinding the surface where the semiconductor layer 102 is exposed by grinding and further polishing the surface (step S105). .

FIG. 2 shows another known SOI substrate manufacturing method. In the SOI substrate manufacturing method, first, an active layer substrate 111 and a support substrate 116 are manufactured. The active layer substrate 111 is formed of a semiconductor layer 112 formed of a semiconductor and an insulator layer 113 formed of an insulator. That is, the active layer substrate 111 is formed by thermally oxidizing one surface of a semiconductor substrate formed from a semiconductor, or formed by forming a SiO ₂ film on one surface of the semiconductor substrate. (Step S111). The support substrate 116 is a semiconductor substrate itself formed from a semiconductor. The active layer substrate 111 is implanted with hydrogen ions 114. In the active layer substrate 111, hydrogen ions 114 are implanted, whereby hydrogen is unevenly distributed on a surface having a predetermined depth inside the semiconductor layer 112, and an embrittlement layer 115 is formed inside the semiconductor layer 112 (step S112). ). The surface of the active layer substrate 111 where the insulator layer 113 is exposed is washed (step S113) and subjected to a hydrophilic treatment (step S114). Examples of the hydrophilization treatment include a method of immersing in hydrogen peroxide solution after hydrofluoric acid treatment and a method of irradiating the surface with oxygen plasma. Next, the cleaned and hydrophilized surface of the active layer substrate 111 is bonded to the cleaned and hydrophilized surface of the support substrate 116 and heated to 400 to 600 ° C. (step S115). In the bonded bonding substrate 117, the Si layer 119 is peeled from the embrittled layer 115 by such heating or by inserting a razor into the embrittled layer 115 (step S116). The substrate 118 from which the Si layer 119 has been peeled is heat-treated at 1000 ° C. for about 10 hours (step S117), and the surface on which the remaining semiconductor layer 112 is exposed is polished to produce the SOI substrate product 120. (Step S118).

  It is desired to reduce the production cost for producing SOI substrate products.

  In the reprinted WO 01/027999, when a bonded wafer is manufactured by the hydrogen ion delamination method, the bonding does not cause problems such as generation of particles from the peripheral portion of the wafer and cracks in the SOI layer. A method for manufacturing a bonded wafer for manufacturing a wafer is disclosed. The method for manufacturing the bonded wafer includes at least a step of bonding a base wafer and a bond wafer having a microbubble layer formed by gas ion implantation, and a step of peeling with the microbubble layer as a boundary. In a method for manufacturing a bonded wafer by a peeling method, a peripheral portion of a thin film formed on a base wafer is removed after the peeling step.

  Japanese Patent Laid-Open No. 2002-313689 improves the bonding strength of the bonding interface of the bonded substrate, and provides a bonded substrate having no void defect or blister defect at the bonded interface of the bonded substrate after bonding heat treatment with high productivity and yield. A method of manufacturing a bonded substrate that can be manufactured is disclosed. The method for manufacturing a bonded substrate is a method for manufacturing a bonded substrate having a step of bonding at least two substrates and a step of applying heat treatment to the bonded substrates and firmly bonding them, and bonding at least the substrates. A cleaning process is performed to remove contaminants on the substrate surface before, and then the cleaned substrate surface is dried. In the drying process, the water replacement method is not used. It is characterized in that the bonding strength after bonding the substrates is increased by leaving

No. WO01 / 027999 JP 2002-313689 A

An object of the present invention is to provide an SOI semiconductor substrate manufacturing method and an SOI semiconductor substrate manufacturing apparatus for more easily manufacturing an SOI semiconductor substrate.
Another object of the present invention is to provide an SOI semiconductor substrate manufacturing method and an SOI semiconductor substrate manufacturing apparatus for manufacturing an SOI semiconductor substrate at a higher speed.
Still another object of the present invention is to provide an SOI semiconductor substrate in which residual stress / strain is further reduced.

  In the following, means for solving the problems will be described using the reference numerals used in the modes and examples for carrying out the invention in parentheses. This symbol is added to clarify the correspondence between the description of the claims and the description of the modes and embodiments for carrying out the invention. Do not use to interpret the technical scope.

The method for manufacturing an SOI semiconductor substrate according to the present invention provides insulation of an insulating layer forming substrate layer (73) in which a thick semiconductor layer (75) formed of a semiconductor and an insulating layer (76) formed of an insulator are laminated. A step of producing a pre-grinding substrate by adhering a support substrate for grinding to the body layer (76) (S32), and forming a thick semiconductor layer into a semiconductor layer having a predetermined thickness by grinding, and then bonding to the semiconductor layer A step of producing a pre-peeling substrate by bonding the support substrate (S34), a step of producing an active layer substrate by peeling the support substrate for grinding from the insulator layer (S35), and among the active layer substrates Irradiating particles to the surface of the insulating layer from which the insulating layer is exposed and the supporting substrate surface of the supporting substrate, thereby activating the supporting substrate surface and the insulating layer surface (S37). A step of bonding the support substrate and the active layer substrate by bringing the support substrate surface and the insulator layer surface into contact with each other (S38), and after the support substrate and the active layer substrate are bonded, the bonding support substrate and a step (S39) of peeling off the.
Such SOI semiconductor substrate manufacturing method, the support substrate and the active layer board (91) and without heating, and can be joined to its support substrate and the active layer board (91), as a result, The SOI semiconductor substrate (21) in which the insulator layer ( 76) is formed between the semiconductor layer ( 82) and the supporting substrate can be manufactured more easily and at higher speed. The support substrate and the active layer board (91) and is fabricated SOI semiconductor substrate without being heated (21), another SOI semiconductor substrate manufactured by the active layer substrate and the supporting substrate is heated Compared to the above, the residual stress / strain is further reduced.
Further, according to the SOI semiconductor substrate manufacturing method of the present invention, the semiconductor layer (82) can be formed to a predetermined thickness before the supporting substrate and the active layer substrate (91) are joined, and the semiconductor An insulating layer can be formed before the layer (82) is formed to a predetermined thickness.

SOI semiconductor substrate manufacturing process according to the invention, before its supporting substrate and the active layer board (91) are joined, further comprising a step of forming a structure on the insulator layer surface. The SOI semiconductor substrate (21) manufactured by such an SOI semiconductor substrate manufacturing method is suitable as a material for manufacturing a MEMS that needs to be processed into the insulator layer ( 76).

SOI semiconductor substrate manufacturing method according to the invention, before its supporting substrate and the active layer board (91) are joined, further comprising a step of forming a structure on the support substrate surface. The SOI semiconductor substrate (21) manufactured by such an SOI semiconductor substrate manufacturing method is suitable as a material for manufacturing a MEMS that needs to be processed into a support substrate.

The SOI semiconductor substrate manufacturing method and the SOI semiconductor substrate manufacturing apparatus according to the present invention can bond the supporting substrate and the active layer substrate without heating the supporting substrate and the active layer substrate, and as a result, An SOI semiconductor substrate in which an insulator layer is formed between the semiconductor layer and the supporting substrate layer can be manufactured more easily and at higher speed.
In the SOI semiconductor substrate according to the present invention, the insulator layer and the support substrate layer can be bonded without being heated, and the insulator layer and the support substrate layer are bonded without being heated. Sometimes it can be made faster.

FIG. 1 is a flowchart showing a known SOI semiconductor substrate manufacturing method. FIG. 2 is a flowchart showing another known SOI semiconductor substrate manufacturing method. FIG. 3 is a sectional view showing an SOI semiconductor substrate according to the present invention. FIG. 4 is a sectional view showing an SOI semiconductor substrate manufacturing apparatus according to the present invention. FIG. 5 is a flowchart showing an embodiment of an SOI semiconductor substrate manufacturing method according to a reference example of the present invention. FIG. 6 is a cross-sectional view showing the active layer substrate. FIG. 7 is a cross-sectional view showing a bonded substrate bonded at room temperature. FIG. 8 is a flowchart showing another embodiment of the SOI semiconductor substrate manufacturing method according to the reference example of the present invention. FIG. 9 is a cross-sectional view showing an embrittlement layer. FIG. 10 is a cross-sectional view showing a bonded substrate bonded at room temperature. FIG. 11 is a cross-sectional view showing the substrate from which the semiconductor layer has been peeled off. FIG. 12 is a flowchart showing still another embodiment of the SOI semiconductor substrate manufacturing method according to the reference example of the present invention. FIG. 13 is a cross-sectional view showing a substrate to which a bonding support substrate is bonded. FIG. 14 is a cross-sectional view showing the substrate after the semiconductor layer has been ground and polished. FIG. 15 is a cross-sectional view showing the substrate after the insulator layer is formed. FIG. 16 is a cross-sectional view showing a bonded substrate bonded at room temperature. FIG. 17 is a flowchart showing still another embodiment of the SOI semiconductor substrate manufacturing method according to the present invention. FIG. 18 is a cross-sectional view showing a substrate to which a grinding support substrate is bonded. FIG. 19 is a cross-sectional view showing the substrate after the semiconductor layer has been ground and polished. FIG. 20 is a cross-sectional view showing a substrate to which a bonding support substrate is bonded. FIG. 21 is a cross-sectional view showing the substrate from which the grinding support substrate has been peeled off. FIG. 22 is a cross-sectional view showing a bonded substrate bonded at room temperature.

Embodiments of an SOI semiconductor substrate according to the present invention will be described with reference to the drawings. The SOI semiconductor substrate 21 includes a support substrate layer 22, a semiconductor layer 23, and an insulator layer 24, as shown in FIG. The support substrate layer 22 is formed from a semiconductor. As the semiconductor, silicon Si is exemplified. The semiconductor layer 23 is made of a semiconductor. Examples of the semiconductor include silicon Si, silicon carbide SiC, and gallium arsenide GaAs. The insulator layer 24 is formed from an insulator. As the insulator, silicon dioxide SiO ₂ is exemplified.

  Such an SOI semiconductor substrate 21 is suitable for a high voltage semiconductor device because the semiconductor layer 23 is electrically insulated from the support substrate layer 22. Such an SOI semiconductor substrate 21 further easily forms a structure in the semiconductor layer 23 and the insulator layer 24 by etching using the difference in etching characteristics between the semiconductor layer 23 and the insulator layer 24. It is suitable as a material for manufacturing MEMS devices.

  The insulator layer 24 can be replaced with another insulator layer in which a structure is processed. An example of the structure is a cavity. The support substrate layer 22 may be replaced with another support substrate layer in which a structure is processed. An example of the structure is a cavity. Such an SOI semiconductor substrate does not need to be formed after the SOI semiconductor substrate is completed when it is formed in a MEMS that requires a structure in the insulator layer or support substrate layer, i.e. It is suitable as a material for manufacturing MEMS.

  FIG. 4 shows an SOI semiconductor substrate manufacturing apparatus according to the present invention. The SOI semiconductor substrate manufacturing apparatus 1 is applied to a bonding system. That is, the bonding system includes a bonding apparatus control apparatus 10 and an SOI semiconductor substrate manufacturing apparatus 1. The SOI semiconductor substrate manufacturing apparatus 1 includes a bonding chamber 2 and a load lock chamber 3. The joining chamber 2 and the load lock chamber 3 are containers that seal the inside from the environment. The SOI semiconductor substrate manufacturing apparatus 1 further includes a gate valve 5. The gate valve 5 is interposed between the bonding chamber 2 and the load lock chamber 3, and forms a gate that connects the inside of the bonding chamber 2 and the inside of the load lock chamber 3. The gate valve 5 is controlled by the bonding apparatus control device 10 to close the gate or open the gate. The load lock chamber 3 includes a lid (not shown). The lid closes the gate connecting the outside and the inside of the load lock chamber 3 or opens the gate.

  The load lock chamber 3 includes a vacuum pump 4. The vacuum pump 4 exhausts gas from the inside of the load lock chamber 3 by being controlled by the bonding device control device 10. Examples of the vacuum pump 4 include a turbo molecular pump, a cryopump, and an oil diffusion pump. The load lock chamber 3 further includes a transport mechanism 6 therein. The transfer mechanism 6 is controlled by the bonding apparatus control device 10 to transfer the wafer disposed inside the load lock chamber 3 to the bonding chamber 2 via the gate valve 5 or via the gate valve 5. The wafer placed in the bonding chamber 2 is transferred into the load lock chamber 3.

  The bonding chamber 2 includes a vacuum pump 9. The vacuum pump 9 exhausts gas from the inside of the bonding chamber 2 by being controlled by the bonding apparatus control device 10. Examples of the vacuum pump 9 include a turbo molecular pump, a cryopump, and an oil diffusion pump.

  The bonding chamber 2 further includes a stage carriage 16 and an alignment mechanism 12. The stage carriage 16 is disposed inside the bonding chamber 2 and is supported so as to be able to move in parallel in the horizontal direction and to be rotatable around a rotation axis that is parallel to the vertical direction. The alignment mechanism 12 is further controlled by the bonding apparatus control device 10 so that the stage carriage 16 translates in the horizontal direction or around the rotation axis where the stage carriage 16 is parallel to the vertical direction. The stage carriage 16 is driven so as to rotate. The alignment mechanism 12 further includes a plurality of alignment mechanisms not shown. Each of the plurality of alignment mechanisms is controlled by the bonding apparatus controller 10 to capture an image of the wafer held on the stage carriage 16 and to capture an image of the wafer attracted by the electrostatic chuck 18.

  The bonding chamber 2 further includes a pressure contact mechanism 11, a pressure contact shaft 13, an electrostatic chuck 18, and a load meter 19. The press contact shaft 13 is supported so as to be movable in the vertical direction with respect to the bonding chamber 2. The electrostatic chuck 18 is disposed at the lower end of the press contact shaft 13. The electrostatic chuck 18 has an internal electrode disposed inside the dielectric layer. The dielectric layer is made of ceramic and has a flat surface. The electrostatic chuck 18 is controlled by the bonding apparatus controller 10 so that a predetermined applied voltage is applied to its internal electrode. The electrostatic chuck 18 attracts a wafer disposed near the flat surface of the dielectric layer by electrostatic force when a predetermined applied voltage is applied to the internal electrode. The pressure welding mechanism 11 is controlled by the bonding device control device 10 to translate the pressure welding shaft 13 in the vertical direction with respect to the bonding chamber 2. The pressure contact mechanism 11 further measures the position where the electrostatic chuck 18 is disposed, and outputs the position to the bonding apparatus control device 10. The load meter 19 measures the load applied to the pressure contact shaft 13, thereby measuring the load applied to the wafer held by the electrostatic chuck 18, and outputs the load to the bonding apparatus control device 10.

  The bonding chamber 2 further includes an ion gun 14 and an electron source 15. The ion gun 14 is disposed so as to face the space between the alignment mechanism 12 and the electrostatic chuck 18 when the electrostatic chuck 18 is disposed above. The ion gun 14 is controlled by the bonding apparatus control device 10, thereby passing argon ions along the irradiation axis passing through the space between the alignment mechanism 12 and the electrostatic chuck 18 and intersecting the inner surface of the bonding chamber 2. Is accelerated and released. Similar to the ion gun 14, the electron source 15 is disposed so as to face the space between the alignment mechanism 12 and the electrostatic chuck 18. The electron source 15 is controlled by the bonding apparatus control device 10, thereby passing through the space between the alignment mechanism 12 and the electrostatic chuck 18 and along another irradiation axis that intersects the inner surface of the bonding chamber 2. , Accelerating and releasing electrons. It should be noted that the ion gun 14 can be replaced with another accelerator that emits other particles different from the argon ions. Examples of the particles include neutral argon atoms.

  The ion gun 14 may further include a metal target (not shown). The metal target is formed from a plurality of metal elements and is arranged at a position where the argon ions are irradiated. The metal target releases the plurality of metal particles to the atmosphere inside the bonding chamber 2 when the argon ions are irradiated. The metal target can also be replaced with a metal grid. The metal grid is a metal member having an opening, and is disposed at the exit end of the ion gun 14. In the same manner as the metal target, the metal grid emits the plurality of metal particles to the atmosphere inside the bonding chamber 2 by being irradiated with the argon ions. The metal target is omitted when it is not necessary to attach metal to the bonding surface of the wafer.

  The joining device control device 10 is a computer, and includes a CPU, a storage device, a removable memory drive, an input device, and an interface (not shown). The CPU executes a computer program installed in the bonding apparatus control device 10 to control the storage device, the input device, and the interface. The storage device records the computer program and temporarily records information generated by the CPU. The removable memory drive is used to read data recorded on the recording medium when the recording medium is inserted. The removable memory drive is used particularly when the computer program is installed in the bonding apparatus control device 10 when a recording medium in which the computer program is recorded is inserted. The input device generates information when operated by the user, and outputs the information to the CPU. The input device is exemplified by a keyboard. The interface outputs information generated by an external device connected to the bonding apparatus control apparatus 10 to the CPU, and outputs information generated by the CPU to the external device. The external devices include a vacuum pump 4, a transport mechanism 6, a vacuum pump 9, a pressure contact mechanism 11, an alignment mechanism 12, an ion gun 14, an electron source 15, an electrostatic chuck 18, and a load meter 19.

  The computer program installed in the joining apparatus control apparatus 10 is formed from a plurality of computer programs for causing the joining apparatus control apparatus 10 to realize a plurality of functions. The plurality of functions are based on information input via an input device, and include a vacuum pump 4, a transport mechanism 6, a vacuum pump 9, a pressure contact mechanism 11, an alignment mechanism 12, an ion gun 14, an electron source 15, and an electrostatic chuck. 18 and load meter 19 are controlled.

FIG. 5 shows an embodiment of an SOI semiconductor substrate manufacturing method according to a reference example of the present invention. An operator produces an active layer substrate by thermally oxidizing a semiconductor substrate formed of single crystal silicon Si (step S1). As shown in FIG. 6, the active layer substrate 26 has a semiconductor layer 27 and an insulator layer 28 stacked thereon. The semiconductor layer 27 is made of single crystal silicon Si. Insulator layer 28 is formed of silicon dioxide SiO _2. The insulator layer 28 is further processed into a structure. The workpiece is exemplified by a cavity. An example of the processing method is etching. The processing is omitted when the structure is not necessary. The insulator layer 28 can also be formed by another process different from the thermal oxidation process. As the process, a process of forming a thin film formed of an insulator is exemplified. The silicon Si can also be formed from other semiconductors. Examples of the semiconductor include silicon carbide SiC and gallium arsenide GaAs.

  The operator further creates a support substrate formed of single crystal silicon Si. The support substrate is further processed with a structure on the front surface. The workpiece is exemplified by a cavity. An example of the processing method is etching. The processing is omitted when the structure is not necessary.

  The operator cleans the insulator layer surface 29 of the active layer substrate 26 where the insulator layer 28 is exposed. The operator cleans the front side surface of the support substrate (step S2).

  The operator uses the SOI semiconductor substrate manufacturing apparatus 1 to bond the active layer substrate 26 and its supporting substrate at room temperature (steps S3 and S4). That is, the operator first controls the gate valve 5 so that the gate connecting the bonding chamber 2 and the load lock chamber 3 is closed, so that a vacuum atmosphere is generated in the bonding chamber 2. The pump 9 is controlled, and the vacuum pump 4 is controlled so that an atmospheric pressure atmosphere is generated inside the load lock chamber 3. The operator places the active layer substrate 26 on the cartridge 17 and places the support substrate on another cartridge 17. After an atmospheric pressure atmosphere is generated inside the load lock chamber 3, the operator opens the lid of the load lock chamber 3 and carries the active layer substrate 26 together with the cartridge 17 into the load lock chamber 3. 17 and the supporting substrate are carried in. Next, the operator closes the lid of the load lock chamber 3 to generate a vacuum atmosphere inside the load lock chamber 3.

  The bonding apparatus control apparatus 10 opens the gate valve 5 after a vacuum atmosphere is generated inside the load lock chamber 3. First, the bonding apparatus control apparatus 10 controls the transport mechanism 6 so that the cartridge 17 on which the active layer substrate 26 is placed is held by the stage carriage 16. The bonding apparatus control device 10 controls the transport mechanism 6 so that the transport mechanism 6 is retracted into the load lock chamber 3. Next, the bonding apparatus control apparatus 10 controls the alignment mechanism of the alignment mechanism 12 so that an image of the alignment mark formed on the active layer substrate 26 is taken. The bonding apparatus control apparatus 10 controls the alignment mechanism 12 based on the image so that the horizontal position of the active layer substrate 26 is arranged at a predetermined position. The bonding apparatus controller 10 controls the pressure contact mechanism 11 so that the dielectric layer of the electrostatic chuck 18 contacts the active layer substrate 26, and the electrostatic chuck 18 attracts the active layer substrate 26. 18 is controlled. The bonding apparatus control device 10 controls the pressure contact mechanism 11 so that the active layer substrate 26 is separated from the cartridge 17. The bonding apparatus control device 10 transfers the cartridge 17 on which the active layer substrate 26 is not placed from the stage carriage 16 into the load lock chamber 3 after the active layer substrate 26 is separated from the cartridge 17. The mechanism 6 is controlled.

  The bonding apparatus control apparatus 10 controls the transport mechanism 6 so that the cartridge 17 on which the support substrate is placed is held by the stage carriage 16 after the active layer substrate 26 is held by the electrostatic chuck 18. Next, the bonding apparatus control apparatus 10 controls the alignment mechanism of the alignment mechanism 12 so that an image of the alignment mark formed on the support substrate is taken. The bonding apparatus control device 10 controls the alignment mechanism 12 based on the image so that the horizontal position of the support substrate is arranged at a predetermined position.

  Next, the bonding apparatus control device 10 closes the gate valve 5 and controls the vacuum pump 9 so that a bonding atmosphere having a predetermined degree of vacuum is generated inside the bonding chamber 2. When the bonding atmosphere is generated inside the bonding chamber 2, the bonding apparatus control apparatus 10 separates the active layer substrate 26 held by the electrostatic chuck 18 from the support substrate held by the stage carriage 16. In this state, the ion gun 14 is controlled so that the particles are emitted between the active layer substrate 26 and the support substrate. The particles are irradiated on the insulator layer surface 29 of the active layer substrate 26 and the surface on the front side of the support substrate, and activated by removing deposits such as an oxide film and carbon C formed on the surface. (Step S3).

  The bonding apparatus control apparatus 10 controls the pressure contact mechanism 11 so that the active layer substrate 26 and the supporting substrate are separated from each other by a predetermined distance. Next, the bonding apparatus control apparatus 10 controls the alignment mechanism of the alignment mechanism 12 so that an image in which the alignment mark formed on the active layer substrate 26 and the alignment mark formed on the support substrate are projected is captured. . The bonding apparatus control apparatus 10 controls the alignment mechanism 12 based on the photographed image so that the active layer substrate 26 and the support substrate are bonded as designed. Note that such advanced alignment can be omitted when not necessary. Examples of the case where the alignment is not necessary include a case where a structure is not formed on the active layer substrate 26 or the support substrate.

  The bonding apparatus control apparatus 10 controls the pressure contact mechanism 11 so that the insulator layer surface 29 of the active layer substrate 26 is in contact with the surface on the front side of the support substrate. The active layer substrate 26 and the support substrate are bonded by the contact and formed on one bonded substrate. As shown in FIG. 7, the bonding substrate 31 is formed by laminating a support substrate layer 32, a semiconductor layer 27, and an insulator layer 28. The support substrate layer 32 is formed from, for example, the support substrate, and is formed from single crystal silicon Si.

  The bonding apparatus control apparatus 10 controls the electrostatic chuck 18 so that the electrostatic chuck 18 dechucks the bonded substrate 31 and controls the pressure contact mechanism 11 so that the electrostatic chuck 18 moves upward in the vertical direction. Next, the bonding apparatus control apparatus 10 opens the gate valve 5 and controls the transfer mechanism 6 so that the cartridge 17 on which the bonded substrate 31 is placed is transferred from the stage carriage 16 to the load lock chamber 3. The bonding apparatus controller 10 controls the vacuum pump 4 so that the atmospheric pressure atmosphere is generated inside the load lock chamber 3 by closing the gate valve 5. After an atmospheric pressure atmosphere is generated inside the load lock chamber 3, the operator opens the load lock chamber 3 and takes out the bonded substrate 31.

  An operator grinds the surface 34 where the semiconductor layer 27 of the bonding substrate 31 is exposed so that the semiconductor layer 27 of the bonding substrate 31 is formed to a predetermined thickness. The operator further polishes the ground surface of the bonding substrate 31 to produce an SOI semiconductor substrate product (step S5).

  Such an SOI semiconductor substrate manufacturing method can join the active layer substrate 26 and its support substrate without heating the active layer substrate 26 and its support substrate. When the substrate is not heated, the active layer substrate 26 and its supporting substrate can be bonded to each other in about 10 to 20 minutes after cleaning. A known method of bonding the active layer substrate 26 and its supporting substrate by heating includes two steps of cleaning and bonding after cleaning, and requires about 10 hours for bonding. That is, such an SOI semiconductor substrate manufacturing method makes it easier to connect the active layer substrate 26 and its support substrate to each other than other methods of joining the active layer substrate 26 and its support substrate by heating. Bonding can be performed at higher speed, and the production cost of the SOI semiconductor substrate can be reduced.

  The SOI semiconductor substrate 21 manufactured without heating the active layer substrate 26 and its supporting substrate is compared with other SOI semiconductor substrates manufactured by heating the active layer substrate 26 and its supporting substrate. Thus, the residual stress / strain is further reduced. Further, in the case where a structure is formed on the active layer substrate 26 or its supporting substrate, when the active layer substrate 26 and the supporting substrate are joined by heating, the structural definition is distorted by the heating. There is. According to such an SOI semiconductor substrate manufacturing method, the active layer substrate 26 or the structure formed on the support substrate thereof is produced by the SOI semiconductor substrate 21 without heating the active layer substrate 26 and the support substrate thereof. When this is done, the residual stress / strain is further reduced as compared with other SOI semiconductor substrates manufactured by heating the active layer substrate 26 and its supporting substrate.

FIG. 8 shows another embodiment of the SOI semiconductor substrate manufacturing method according to the reference example of the present invention. An operator produces an active layer substrate by thermally oxidizing a semiconductor substrate formed of single crystal silicon Si (step S11). As shown in FIG. 9, the active layer substrate 35 has a semiconductor layer 36 and an insulator layer 37 stacked thereon. The semiconductor layer 36 is made of single crystal silicon Si. Insulator layer 37 is formed of silicon dioxide SiO _2. The operator further creates a support substrate formed of single crystal silicon Si.

  The operator implants hydrogen ions 38 into the insulator layer surface 40 of the active layer substrate 35 where the insulator layer 37 is exposed (step S12). According to such implantation of hydrogen ions, the embrittlement layer 39 is formed in the active layer substrate 35 at a predetermined depth of the semiconductor layer 36. The embrittlement layer 39 is formed in a region where hydrogen derived from the hydrogen ions is unevenly distributed.

  The operator cleans the insulator layer surface 40 of the active layer substrate 35 where the insulator layer 37 is exposed. The operator cleans the front surface of the support substrate (step S13).

  An operator uses the SOI semiconductor substrate manufacturing apparatus 1 to perform normal temperature bonding of the active layer substrate 35 and its supporting substrate in the same manner as steps S3 and S4 in the above-described embodiment. That is, the bonding apparatus control apparatus 10 removes impurities such as oxides formed on the insulator layer surface 40 of the active layer substrate 35 and the surface on the front side of the support substrate, so that the insulator layer surface of the active layer substrate 35 is removed. The SOI semiconductor substrate manufacturing apparatus 1 is controlled so that 40 and the front surface of the supporting substrate and metal particles are deposited (step S14). The bonding apparatus control apparatus 10 further controls the SOI semiconductor substrate manufacturing apparatus 1 so that the insulator layer surface 40 of the active layer substrate 35 is in contact with the front surface of the support substrate (step S15).

  The active layer substrate 35 and the supporting substrate are bonded by the contact and formed on one bonded substrate. As shown in FIG. 10, the bonding substrate 41 is formed by laminating a support substrate layer 42, a semiconductor layer 36, and an insulator layer 37. The support substrate layer 42 is formed from the support substrate, and is formed from single crystal silicon Si.

  The operator heats the bonding substrate 41 to 400 to 600 ° C. As a result of such heating, the brittle layer 39 is broken in the bonding substrate 41, and the bonding substrate 41 is peeled into the substrate portion 45 and the peeling portion 46 as shown in FIG. 11 (step S16). In addition, the peeling can also be performed based on a process different from heating. As the treatment, a razor is inserted into the embrittlement layer 39. The substrate portion 45 is formed by laminating a support substrate layer 42, an insulator layer 37, and a semiconductor layer 47. The semiconductor layer 47 is formed from the semiconductor layer 36 and has a predetermined thickness that is smaller than the thickness of the semiconductor layer 36. The peeling portion 46 is formed from the semiconductor layer 36 and is thinner than the thickness of the semiconductor layer 36 by a predetermined thickness. The substrate portion 45 is fabricated into an SOI semiconductor substrate product by polishing the surface 48 where the semiconductor layer 47 is exposed (step S17).

  Such an SOI semiconductor substrate manufacturing method can join the active layer substrate 35 and its supporting substrate more easily and at a higher speed in the same manner as the SOI semiconductor substrate manufacturing method in the embodiment described above. The production cost of the SOI semiconductor substrate can be reduced. In the SOI semiconductor substrate manufactured by such an SOI semiconductor substrate manufacturing method, the residual stress / strain is further reduced in the same manner as the SOI semiconductor substrate manufactured by the SOI semiconductor substrate manufacturing method in the above-described embodiment. . In such an SOI semiconductor substrate manufacturing method, compared to the SOI semiconductor substrate manufacturing method in the above-described embodiment, the semiconductor layer 36 can be formed more easily and thinly after the active layer substrate 35 and its supporting substrate are bonded. Can do.

FIG. 12 shows still another embodiment of the SOI semiconductor substrate manufacturing method according to the reference example of the present invention. The operator creates a pre-grinding substrate by adhering a bonding support substrate to a semiconductor substrate formed of single crystal silicon Si (step S21). As shown in FIG. 13, the pre-grinding substrate 51 includes a bonding support substrate layer 52, a semiconductor layer 53, and an adhesive layer 54. The bonding support substrate layer 52 is formed from the bonding support substrate. The bonding support substrate is formed of a transparent body such as a glass plate or a quartz plate, or a single crystal Si substrate. The semiconductor layer 53 is formed from the semiconductor substrate. The adhesive layer 54 is formed of an adhesive and adheres the bonding support substrate layer 52 and the semiconductor layer 53. The adhesive loses its adhesive ability when heated to a predetermined temperature. The adhesive can be replaced with other adhesives that lose their adhesive ability due to other processes different from heating. As the processing, irradiation with a predetermined laser is exemplified.

  An operator grinds the surface 55 where the semiconductor layer 53 of the substrate 51 before grinding is exposed so that the semiconductor layer 53 of the substrate 51 before grinding is formed to a predetermined thickness. The operator further polishes the ground surface of the unground substrate 51 to produce a ground substrate (step S22). As shown in FIG. 14, the ground substrate 56 includes a bonding support substrate layer 52, a semiconductor layer 57, and an adhesive layer 54. The semiconductor layer 57 is formed from the semiconductor layer 53 and has a predetermined thickness that is smaller than the thickness of the semiconductor layer 53.

An operator produces an active layer substrate by thermally oxidizing the surface 58 where the semiconductor layer 57 of the substrate 56 is exposed after grinding (step S23). As shown in FIG. 15, the active layer substrate 61 is formed by laminating a bonding support substrate layer 52, an adhesive layer 54, an insulator layer 62 and a semiconductor layer 63. Insulator layer 62 is formed color by a portion of the semiconductor layer 53 is oxidized, and is formed of silicon dioxide SiO _2. The semiconductor layer 63 is formed from a part of the semiconductor layer 53 and is formed from single crystal silicon Si.

  The operator cleans the insulator layer surface 64 of the active layer substrate 61 where the insulator layer 62 is exposed. The operator cleans the front surface of the support substrate (step S24).

  The operator uses the SOI semiconductor substrate manufacturing apparatus 1 to bond the active layer substrate 61 and its supporting substrate at room temperature in the same manner as in steps S3 and S4 in the above-described embodiment. In other words, the bonding apparatus control apparatus 10 includes the SOI semiconductor substrate manufacturing apparatus 1 so that impurities such as oxides formed on the insulator layer surface 64 of the active layer substrate 61 and the front surface of the support substrate are removed. Is controlled (step S25). The bonding apparatus control apparatus 10 further controls the SOI semiconductor substrate manufacturing apparatus 1 so that the insulator layer surface 64 of the active layer substrate 61 is in contact with the surface on the front side of the support substrate (step S26).

  The active layer substrate 61 and the support substrate are bonded by the contact and formed on one bonded substrate. As shown in FIG. 16, the bonding substrate 65 includes a bonding support substrate layer 52, an adhesive layer 54, an insulator layer 62, a semiconductor layer 63, and a support substrate layer 66.

  The operator heats the bonding substrate 65 to the predetermined temperature. The bonding support substrate layer 52 is peeled off by such heating, and the bonding substrate 65 is manufactured as an SOI semiconductor substrate product (step S27).

  In such an SOI semiconductor substrate manufacturing method, the semiconductor layer 63 can be formed to a predetermined thickness before the active layer substrate 61 and its supporting substrate are bonded. Such an SOI semiconductor substrate manufacturing method can join the active layer substrate 61 and its supporting substrate more easily and at a higher speed in the same manner as the SOI semiconductor substrate manufacturing method in the embodiment described above. The production cost of the SOI semiconductor substrate can be reduced. In the SOI semiconductor substrate manufactured by such an SOI semiconductor substrate manufacturing method, the residual stress / strain is further reduced in the same manner as the SOI semiconductor substrate manufactured by the SOI semiconductor substrate manufacturing method in the above-described embodiment. .

  FIG. 17 shows still another embodiment of the SOI semiconductor substrate manufacturing method according to the present invention. An operator produces an insulator layer forming substrate by thermally oxidizing a semiconductor substrate formed of single crystal silicon Si (step S31).

The operator creates a pre-grinding substrate by bonding the grinding support substrate to the insulator layer forming substrate (step S32). The grinding support substrate is formed of a transparent body such as a glass plate or a quartz plate, or a single crystal Si substrate. As shown in FIG. 18, the pre-grinding substrate 71 has a pre-grinding substrate 71 in which a grinding support substrate layer 72 and an insulator layer forming substrate layer 73 are bonded via an adhesive layer 74. Yes. The insulator layer forming substrate layer 73 is formed by stacking a semiconductor layer 75 and an insulator layer 76. The grinding support substrate layer 72 is formed from the grinding support substrate. The semiconductor layer 75 is made of single crystal silicon Si. Insulator layer 76 is formed of silicon dioxide SiO _2. The adhesive layer 74 is formed of an adhesive and adheres the grinding support substrate layer 72 and the insulator layer 76. The adhesive loses its adhesive ability when heated to a predetermined first temperature. The adhesive can be replaced with other adhesives that lose their adhesive ability due to other processes different from heating. As the processing, irradiation with a predetermined laser is exemplified.

  An operator grinds the surface 77 where the semiconductor layer 75 of the substrate 71 before grinding is exposed so that the semiconductor layer is formed to a predetermined thickness. The operator further polishes the ground surface of the pre-grind substrate 71 to produce a post-grind substrate (step S33). As shown in FIG. 19, the ground substrate 81 is formed by laminating a grinding support substrate layer 72, an adhesive layer 74, an insulator layer 76, and a semiconductor layer 82. The semiconductor layer 82 is formed from the semiconductor layer 75 and has a predetermined thickness that is smaller than the thickness of the semiconductor layer 75.

  The operator creates a pre-peeling substrate by bonding the bonding support substrate to the surface 83 of the substrate 81 where the semiconductor layer 82 is exposed after grinding (step S34). The bonding support substrate is formed of a transparent body such as a glass plate or a quartz plate, or a single crystal Si substrate. As shown in FIG. 20, the substrate 85 before peeling includes a bonding support substrate layer 86, an adhesive layer 87, a semiconductor layer 82, an insulator layer 76, an adhesive layer 54, and a grinding support substrate layer 72. Are stacked. The bonding support substrate layer 86 is formed from the bonding support substrate. The adhesive layer 87 is formed of an adhesive and adheres the bonding support substrate layer 86 and the semiconductor layer 82. The adhesive loses its bonding ability by being heated to a predetermined second temperature higher than the first temperature. The adhesive can be replaced with other adhesives that lose their adhesive ability due to other processes different from heating. As the processing, irradiation with a predetermined laser is exemplified.

  The operator heats the pre-peeling substrate 85 to the predetermined first temperature. The support substrate layer 72 for grinding is peeled off from the pre-peeling substrate 85 by such heating, and is formed on the active layer substrate (step S35). As shown in FIG. 21, the active layer substrate 91 is formed by laminating a bonding support substrate layer 86, an adhesive layer 87, a semiconductor layer 82, and an insulator layer 76. The operator cleans the insulator layer surface 92 of the active layer substrate 91 where the insulator layer 76 is exposed. The operator further cleans the surface on the front side of the support substrate (step S36).

  The operator uses the SOI semiconductor substrate manufacturing apparatus 1 to bond the active layer substrate 91 and its supporting substrate at room temperature in the same manner as in steps S3 and S4 in the above-described embodiment. In other words, the bonding apparatus control apparatus 10 includes the SOI semiconductor substrate manufacturing apparatus 1 so that impurities such as oxides formed on the insulator layer surface 92 of the active layer substrate 91 and the front surface of the support substrate are removed. Is controlled (step S37). The bonding apparatus control apparatus 10 further controls the SOI semiconductor substrate manufacturing apparatus 1 so that the insulator layer surface 92 of the active layer substrate 91 is in contact with the surface on the front side of the support substrate (step S38).

  The active layer substrate 91 and the support substrate are bonded by the contact to form a single bonded substrate. As shown in FIG. 22, the bonding substrate 95 includes a bonding support substrate layer 86, an adhesive layer 87, a semiconductor layer 82, an insulator layer 76, and a support substrate layer 96.

  The operator heats the bonding substrate 95 to the predetermined second temperature. The bonding support substrate layer 86 is peeled off from the bonding substrate 95 by such heating, and the bonding substrate 95 is manufactured as an SOI semiconductor substrate product (step S39).

  In such an SOI semiconductor substrate manufacturing method, the semiconductor layer 82 can be formed to a predetermined thickness after the insulator layer 76 is formed, and the semiconductor layer 82 is bonded to the active layer substrate 91 and its supporting substrate before bonding. 82 can be formed to a predetermined thickness. Such an SOI semiconductor substrate manufacturing method can join the active layer substrate 91 and its supporting substrate more easily and at a higher speed in the same manner as the SOI semiconductor substrate manufacturing method in the embodiment described above. The production cost of the SOI semiconductor substrate can be reduced. In the SOI semiconductor substrate manufactured by such an SOI semiconductor substrate manufacturing method, the residual stress / strain is further reduced in the same manner as the SOI semiconductor substrate manufactured by the SOI semiconductor substrate manufacturing method in the above-described embodiment. .

DESCRIPTION OF SYMBOLS 1: SOI semiconductor substrate manufacturing apparatus 2: Bonding chamber 3: Load lock chamber 4: Vacuum pump 5: Gate valve 6: Transfer mechanism 9: Vacuum pump 10: Bonding device control device 11: Pressure contact mechanism 12: Positioning mechanism 13: Pressure contact Axis 14: Ion gun 15: Electron source 16: Stage carriage 17: Cartridge 18: Electrostatic chuck 19: Load cell 21: SOI semiconductor substrate 22: Support substrate layer 23: Semiconductor layer 24: Insulator layer 25: Amorphous layer 26: Active Layer substrate 27: Semiconductor layer 28: Insulator layer 29: Insulator layer surface 31: Bonding substrate 32: Support substrate layer 33: Amorphous layer 34: Surface 35: Active layer substrate 36: Semiconductor layer 37: Insulator layer 38: Hydrogen Ion 39: Embrittlement layer 40: Insulator layer surface 41: Bonding substrate 42: Support substrate layer 43: Amor Gas layer 45: Substrate portion 46: Peeling portion 47: Semiconductor layer 48: Surface 51: Substrate before grinding 52: Support substrate layer for bonding 53: Semiconductor layer 54: Adhesive layer 55: Surface 56: Substrate after grinding 57: Semiconductor Layer 58: Surface 61: Active layer substrate 62: Insulator layer 63: Semiconductor layer 64: Insulator layer surface 65: Bonded substrate 66: Support substrate layer 67: Amorphous layer 71: Pre-grinding substrate 72: Support substrate layer for grinding 73 : Insulator layer forming substrate layer 74: Adhesive layer 75: Semiconductor layer 76: Insulator layer 77: Surface 81: Substrate after grinding 82: Semiconductor layer 83: Surface 85: Substrate before peeling 86: Support substrate layer for bonding 87: Adhesive layer 91: Active layer substrate 92: Insulator layer surface 95: Bonded substrate 96: Support substrate layer 97: Amorphous layer

Claims (3)

A pre-grinding substrate is prepared by adhering a support substrate for grinding to the insulator layer of the insulator layer forming substrate layer in which a thick semiconductor layer formed of a semiconductor and an insulator layer formed of an insulator are laminated. And steps to
After forming the thick semiconductor layer into a semiconductor layer having a predetermined thickness by grinding, bonding a support substrate for bonding to the semiconductor layer, thereby producing a pre-peeling substrate;
Producing an active layer substrate by peeling the support substrate for grinding from the insulator layer;
By irradiating particles on the surface of the insulator layer where the insulator layer of the active layer substrate is exposed and the surface of the support substrate of the support substrate, the surface of the support substrate and the surface of the insulator layer are An activating step ;
Bonding the support substrate and the active layer substrate by contacting the support substrate surface and the insulator layer surface;
Peeling the support substrate for bonding after the support substrate and the active layer substrate are bonded;
An SOI semiconductor substrate manufacturing method comprising: Oite to claim 1,
An SOI semiconductor substrate manufacturing method further comprising a step of forming a structure on a surface of the insulator layer before the support substrate and the active layer substrate are bonded. Oite to claim 1 or claim 2,
An SOI semiconductor substrate manufacturing method further comprising a step of forming a structure on a surface of the support substrate before the support substrate and the active layer substrate are bonded to each other.

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