In a first ion implantation step (a1), a delamination-intended ion implantation layer 3 is formed by implanting ions at a dosage less than a critical dosage from the insulating film 2 side of a bond wafer 1. In an additional function layer deposition step (b2), an additional function layer 4 is depo
In a first ion implantation step (a1), a delamination-intended ion implantation layer 3 is formed by implanting ions at a dosage less than a critical dosage from the insulating film 2 side of a bond wafer 1. In an additional function layer deposition step (b2), an additional function layer 4 is deposited on the insulating film 2 of the bond wafer 1. In a second ion implantation step (c1), by implanting ions at a dosage, the delamination-intended ion implantation layer 3 is matured into a delamination ion implantation layer 3'. Thereby, the delamination ion implantation layer is formed by two steps of ion implantation having the additional function layer deposition step therebetween, and therefore non-uniformity of the additional function layer does not influence uniformity of a film thickness of a bonded semiconductor thin layer.
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What is claimed is: 1. A manufacturing method of a bond wafer comprising: a first ion implantation step of conducting first ion implantation on a bond wafer so that a concentration peak of ion implantation is located at a position with a predetermined depth in an ion implantation profile in a depth
What is claimed is: 1. A manufacturing method of a bond wafer comprising: a first ion implantation step of conducting first ion implantation on a bond wafer so that a concentration peak of ion implantation is located at a position with a predetermined depth in an ion implantation profile in a depth direction from the surface of the bond wafer; an additional function layer deposition step of depositing an additional function layer on a ion implantation surface side of the bond wafer; a second ion implantation step of conducting second implantation through the additional function layer with the first ion implantation position as a target from the additional function layer side of the bond wafer; a bonding step of bonding the additional function layer side of the bond wafer to a base wafer; and a delamination step of separating the bond wafer off at the position of the first ion implantation, wherein the additional function layer is made of one of a polysilicon layer and an amorphous silicon layer. 2. The manufacturing method of a bonded wafer according to claim 1, wherein the first ion implantation adopts an ion implantation dosage causing no cracking in the bond wafer in a course of a thermal history in growth of the additional function layer. 3. The manufacturing method of a bonded wafer according to claim 1, wherein a dosage of first ion implantation in the first ion implantation step is larger than a dosage of second ion implantation in the second ion implantation step. 4. The manufacturing method of a bonded wafer according to claim 3, wherein a dosage of ion implantation in the first ion implantation is in the range of 70% or more and 90% or less of the critical dosage. 5. The manufacturing method of a bonded wafer according to claim 1, comprising: a planarization polishing step either one of before and after the second ion implantation step wherein the surface of the deposited additional function layer is planarized by polishing. 6. The manufacturing method of a bonded wafer according to claim 1, comprising: an activation step of activating surfaces of one or both of the bond wafer and the base wafer with a plasma before the bonding step. 7. The manufacturing method of a bonded wafer according to claim 6, wherein the delamination step is a step of conducting delamination by blowing one of water laser and gas to the bond wafer after the activation step. 8. The manufacturing method of a bonded wafer according to claim 1, wherein the delamination step is a step of conducting delamination by heat treating the bond wafer. 9. The manufacturing method of a bonded wafer according to claim 1, wherein the ion is one selected from a hydrogen ion, a helium ion, a neon ion, an argon ion, a krypton ion and a xenon ion. 10. A manufacturing method of a bonded wafer comprising: a first ion implantation step of forming a delamination-intended ion implantation layer having a concentration peak of ion implantation at a position having a predetermined depth in an ion implantation profile in a depth direction in the bond wafer by implanting ions at a dosage less than a critical dosage from the insulating film side of the bond wafer forming a single crystal silicon substrate having an insulating film; an additional function layer deposition step of depositing an additional function layer on the insulating film of the bond wafer; a second ion implantation step of forming a delamination ion implantation layer from the delamination-intended ion implantation layer by implanting ions through the additional functional layer at a dosage amounting to more than a critical dosage including the dosage of ion implantation in the first ion implantation step as a total dosage, so that ion implantation is conducted at the same position of depth of ion implantation as in the first ion implantation step from the surface side of the additional function layer; a bonding step of bonding the additional function layer on the bond wafer wherein the delamination ion implantation layer is formed to a base wafer; and a delamination step of separating the bond wafer off at the delamination ion implantation layer, wherein the additional function layer is made of one of a polysilicon layer and an amorphous silicon layer. 11. The manufacturing method of a bonded wafer according to claim 10, wherein the insulating film is one selected from a silicon oxide film, a silicon nitride film and a silicon oxide nitride film. 12. A manufacturing method of a bonded wafer according to claim 10, wherein the base wafer is one selected from a single crystal silicon substrate having an insulating film, a single crystal silicon substrate, an insulating substrate and a compound semiconductor substrate. 13. The manufacturing method of a bonded wafer according to claim 10, wherein a dosage of first ion implantation in the first ion implantation step is larger than a dosage of second ion implantation in the second ion implantation step. 14. The manufacturing method of a bonded wafer according to claim 13, wherein a dosage of ion implantation in the first ion implantation is in the range of 70% or more and 90% or less of the critical dosage. 15. The manufacturing method of a bonded wafer according to claim 10, comprising: a planarization polishing step either one of before and after the second ion implantation step wherein the surface of the deposited additional function layer is planarized by polishing. 16. The manufacturing method of a bonded wafer according to claim 10 comprising: an activation step of activating surfaces of one or both of the bond wafer and the base wafer with a plasma before the bonding step. 17. The manufacturing method of a bonded wafer according to claim 16, wherein the delamination step is a step of conducting delamination by blowing one of water laser and gas to the bond wafer after the activation step. 18. The manufacturing method of a bonded wafer according to claim 10, wherein the delamination step is a step of conducting delamination by heat treating the bond wafer. 19. The manufacturing method of a bonded wafer according to claim 10, wherein the ion is one selected from a hydrogen ion, a helium ion, a neon ion, an argon ion, a krypton ion and a xenon ion.
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