WO2016142238A1 - Carrier for temporary bonded wafers - Google Patents

Abstract

A carrier is disclosed onto which a wafer can be temporarily bonded. The carrier comprises a plate shaped laminate. The plate shaped laminate comprises a first layer. The first layer comprises a foil, a sheet or a plate. The plate shaped laminate comprises a second layer comprising a porous metal medium with three- dimensional open pores. The porous metal medium comprises metal fibers. The first layer is permanently bonded to the porous metal medium thereby closing the pores of the porous metal medium at the side where the first layer is located. The porous metal medium comprises a first porous layer and a second porous layer. The first porous layer is provided between the first layer and the second porous layer. The porosity of the first porous layer is higher than the porosity of the second porous layer.

Description

Carrier for temporary bonded wafers

Description

Technical Field

[0001 ] The invention relates to the field of carriers for wafers. The carrier can be used for the temporary bonding of wafers during their processing, e.g. in wafer thinning.

Background Art

[0002] The use of temporary bonding of wafers onto a carrier to allow processing of the wafer is well known. A challenge is the subsequent debonding of the wafer from the carrier. Different carriers have been described that allow debonding by means of a solvent. In such processes, the adhesive used for the temporary bonding is chemically dissolved.

[0003] US2009/197070A describes a support plate that bonds to a substrate so as to support the substrate. In the support plate, a plurality of openings penetrate through from a bonding surface to a non-bonding surface. The bonding surface faces the substrate, and the non-bonding surface faces the bonding surface. A porous region, which includes a first region and a second region surrounding the first region, is formed on the bonding surface; and the first region has an opening ratio greater than that of the second region. This way, it is possible to realize a support plate that can be easily peeled off from a semiconductor wafer with a solvent, but does not easily come off from a substrate during a processing operation on the semiconductor wafer.

[0004] US2005/0173064A1 provides a supporting plate that has a structure in which a solvent can be supplied to an adhesive layer between the supporting plate and a substrate - such as a semiconductor wafer - in a short period of time after the substrate is thinned. The document also discloses a method for stripping the supporting plate. The supporting plate may have a larger diameter than the semiconductor wafer, and penetrating holes are formed in the supporting plate. The outer peripheral portion of the supporting plate is a flat portion in which no penetrating hole is formed. When alcohol is poured from above the supporting plate, the alcohol reaches the adhesive layer through the penetrating holes, dissolves and removes the adhesive layer.

[0005] US8882096B2 discloses a perforated support plate for supporting a

surface of a wafer by interposing an adhesive layer. The perforated support plate has penetration holes. Solvent to dissolve the adhesive with which the perforated support plate is adhered to a wafer penetrates through the perforations of the support plate. The perforated support plate comprises a reinforcing part for deflection prevention.

[0006] US2004/0231793A1 discloses the use of a porous sintered metal as

temporary carrier for wafers. The carrier can be released by solvent passing through the thickness of the temporary carrier through its pores in order to dissolve the adhesive used to adhere the wafer to the temporary carrier.

[0007] US2009325467A describes a process wherein a wafer can be thinned without occurrence of dimples. A support plate has a number of through holes. A circuit forming surface of a wafer is adhered to one surface of the support plate by an adhesive member, and a dimple prevention member having a thickness of 100 μιτι or more and having an adhesive layer on one face is adhered to the other surface. Thus the openings at both ends of the through holes are blocked. The support plate is vacuum adsorbed to a support table through the dimple prevention member, and the wafer is ground/ polished to thin the wafer. The dimple prevention member is stripped off, and a solvent is penetrated into the adhesive member through the through holes to detach the wafer from the support plate.

[0008] US2001005043A discloses a technique which performs the thinning of a wafer and the separation thereof from a support substrate with high yields and in a short time. A hole-free support substrate is bonded to a second surface of a support substrate having holes with an adhesive layer melted by heating so as to block the holes. A wafer is bonded to a first surface of the support substrate having the holes with an adhesive layer melted by solvent. The wafer is thinned by grinding and etching. The adhesive layer is melted by heating and the support substrate having the holes is slid with respect to the hole-free support substrate to thereby separate the support substrate having the holes from the hole-free support substrate. The adhesive layer is then dissolved by solvent through the holes defined in the support substrate having the holes. Thereby the wafer is separated from the support substrate having the holes. As no load is put on the wafer, wafer damage is prevented.

Disclosure of Invention

[0009] It is an objective of the invention to provide a carrier for temporary wafer bonding. It is the objective to provide such a carrier with improved properties. It is an objective of the invention to provide a carrier that allows easy debonding of the wafer by dissolving the adhesive using a solvent percolating through the pores of the carrier. It is an objective of the invention to provide a carrier that allows that wafers can be thinned thereby obtaining the required quality specifications.

[0010] The first aspect of the invention is a carrier onto which a wafer can be temporarily bonded, e.g. to allow wafer thinning. The carrier comprises a plate shaped laminate. The plate shaped laminate comprises a first layer. The first layer comprises a foil, a sheet or a plate. The plate shaped laminate comprises a second layer comprising a porous metal medium with three-dimensional open pores. The porous metal medium comprises metal fibers or consists out of metal fibers. The first layer is permanently bonded to the porous metal medium thereby closing the pores of the porous metal medium at the side where the first layer is located. The porous metal medium comprises a first porous layer and a second porous layer. The first porous layer is provided between the first layer and the second porous layer. The porosity of the first porous layer is higher than the porosity of the second porous layer.

[001 1 ] The first layer is permanently bonded to the porous metal medium such that during and after debonding a wafer temporarily bonded to the carrier, the first layer remains bonded to the porous metal medium. [0012] Preferably, the carrier has the shape of a disk, possibly wherein the disk deviates from a circular circumference by a linear side. The linear side is present in order to match the shape of a wafer to be bonded to the work carrier. Preferably the diameter of the circular section of the disk is suited for 6 inch, for 8 inch, or for 12 inch wafers. This means that the diameter of the disk is equal or slightly larger than the diameter of the wafer.

[0013] The carrier has the benefit that debonding solvent can flow through the three-dimensional open pores of the porous metal medium, from the side edges of the carrier adhesively bonded onto a wafer, through the whole volume of the porous metal medium. The presence of the first porous layer with its higher porosity ensures rapid penetration of debonding liquid through the first porous layer; and then through the thickness of the second porous layer, so that fast debonding is realized. This way, the debonding solvent can reach the adhesive layer attaching the wafer to the carrier fast. The carrier has sufficient stiffness to transport the bonded wafer through the different process steps without the occurrence of bending or other mechanical deformation nor stresses. The carrier has the further benefit that it has sufficient mechanical properties, e.g. stiffness, in order to allow to reach the required dimensional properties of the thinned wafer, such as total thickness variation (TTV), bow and warp. It is a further benefit of the invention that the carrier can be re-used multiple times. It is a further benefit of the carrier of the invention that thanks to the lower porosity level of the second porous layer the adhesive penetrates less and less deep into the porous metal medium, resulting in less consumption of adhesive used for temporarily bonding the wafer onto the carrier.

Furthermore, as the adhesive penetrates less into the second porous layer, the thickness of the adhesive layer is lower resulting in a decrease of the time required for debonding.

[0014] In a preferred embodiment, the first porous layer is directly bonded to the first layer. In a further preferred embodiment, the second porous layer is directly bonded to the first porous layer. In a further embodiment, the second porous layer is provided for being bonded onto the wafer. [0015] Preferably, the porosity of the first porous layer is more than 50 %; and preferably below 80 %.

[0016] Preferably, the second porous layer has a porosity level less than 60 %; and preferably more than 30 %.

[0017] Preferably, the first layer comprises or consists out of metal, or glass, or silicon or ceramic. In a preferred embodiment, the first layer consists out of metal, or out of glass or out of silicon or out or ceramic.

[0018] Specific examples of the porous metal medium include sintered or welded metal fiber nonwovens.

[0019] Preferably, the first layer covers at least one planar side of the second layer; more preferably, the first layer covers the full surface of at least one planar side of the second layer.

[0020] In a preferred embodiment, the first layer covers the full surface of one planar side of the second layer.

[0021 ] Preferably, the first layer comprises or consists out of metal. Preferably, the first layer comprises or consists out of a metal foil, a metal plate or a metal sheet. Preferably, the first layer comprises the same metal or alloy as the porous metal medium.

[0022] Preferably, the porous metal medium comprises or consists out of

stainless steel, titanium, palladium or tungsten; or comprises or consists out of an alloy comprising for more than 50% by weight of titanium, palladium or tungsten. More preferably, for embodiments where the first layer comprises or consists out of a metal foil, a metal plate or a metal sheet, the first layer comprises the same metal or metal alloy as the porous metal medium.

[0023] In a preferred embodiment, wherein the first layer comprises or consists out of metal, the first layer is permanently bonded to the porous metal medium by means of metallic bonds, preferably by means of diffusion bonding, such as sintering, or by means of welding (and preferably by means of welding wherein no additional filler material is used in the welding process). An example of a welding process that can be used is capacity discharge welding (CDW). [0024] In a preferred embodiment, the first layer is permanently bonded to the porous metal medium by means of an adhesive. The adhesive can be selected from the wide range of adhesives that are not attacked by the debonding liquid used when debonding the temporarily bonded wafer from the carrier. Examples of suitable adhesives are adhesives based on epoxy.

[0025] Preferably, the carrier has a thickness between 650 μιτι and 750 μιτι.

[0026] Preferably, the first layer has a thickness between 20 μιτι and 650 μιτι, more preferably between 150 μιτι and 650 μιτι.

[0027] Preferably, the porous metal medium has a thickness between 50 μιτι and

150 μιτι, more preferably between 50 μιτι and 150 μιτι.

[0028] Preferably, the diameter of the metal fibers is between 2 and 50 μιτι, more preferably between 2 and 40 μιτι, even more preferably between 2 and 25 μιτι. Even more preferably between 10 and 25 μιτι.

[0029] In a preferred embodiment, the first porous layer comprises or consists out of metal fibers of a first equivalent diameter and the second porous layer comprises or consists out of metal fibers of a second equivalent diameter. In a more preferred embodiment, the first equivalent diameter is larger than the second equivalent diameter. With equivalent diameter is meant the diameter of the circle having the same area as the cross section of a fiber, cross sectional shape which can deviate from a circular shape.

[0030] Preferably, the porous metal medium has a surface for being bonded onto a wafer, wherein this surface is parallel with the first layer. This surface is polished so that the carrier has a total thickness variation (TTV) less than 10 μιτι. The total thickness variation (TTV) is measured by a drop gauge measurement on 5 points, selected randomly over the surface of the material. For the test method, the diameter of the drop gauge is 5.99. The TTV is defined as the difference between the maximum thickness measured and the minimum thickness measured.

[0031 ] Preferably, the second layer comprises a contact layer for being bonded onto a wafer. The contact layer comprises a mixture of metal fibers and metal powder. The metal fibers and the metal powder are permanently bonded to each other at their contacting points. In a preferred such embodiment, the porosity of the porous metal medium is more than 20% and preferably more than 30%, more preferably more than 40%, even more preferably more than 50%, even more preferably more than 60%. And preferably the porosity is less than 80%, more preferably less than 60%.

In a preferred such embodiment, the porosity of the contact layer is more than 20% and preferably more than 30%. And preferably the porosity of the contact layer is less than 50%, more preferably less than 40%.

In a more preferred embodiment, the porous metal medium comprises an additional porous layer, provided between the first layer and the contact layer. The additional porous layer can comprise metal fibers, metal powder, or metal foam. Specific examples of the additional porous layer include sintered or welded metal fiber nonwovens, sintered metal powders, and metal foam.

Preferably, the metal powder in the contact layer has a diameter within the range of 2 to 30 μιτι, preferably within the range of 2 to 20 μιτι, more preferably within the range of 2 to 10 m. In a preferred embodiment, the side edges of the porous metal medium are permanently sealed so that no open pores are present at the side edges of the porous metal medium. Preferably, the sealing of the side edges is fully provided by metal.

The side edges can be sealed by means of welding of the edges, or by means of laser cutting to size and shape operation of the porous metal medium, or by means of a welding of the edges or by means of laser cutting operation to size and shape of the combination of the first layer and the second layer after bonding the first layer to the second layer.

An alternative method for creating the sealing edges is by machining a plate so that the upstanding edges are created, and the porous metal medium is inserted in the cup that is created by the machining, and subsequent bonding of the porous metal medium onto the first layer.

When a temporary bonded wafer is to be debonded from a carrier with permanently sealed edges, initially no wicking of the debonding liquid occurs in the porous metal medium. Initial debonding happens on the thin layer of adhesive between the carrier and the wafer. When this thin adhesive layer is broken down, the debonding speed increases by having increased wicking of the debonding liquid in the porous metal medium through the openings created by dissolving the glue layer at the edge.

[0033] Preferably, the carrier is provided such that when applying a pressure of 4 bar onto it, the permanent deformation of the carrier is less than 5 % of its original thickness before applying the pressure. This can be tested by measuring the thickness of the carrier before and after applying a pressure of 4 bar during a time period of 20 seconds. A carrier according to this embodiment can be made by prepressing the carrier or the porous metal layer or porous metal layers in it so that future permanent deformation is limited. Such embodiments surprisingly synergistically improve the properties of the wafer after its processing (e.g. thinning) while being temporarily adhered to the carrier.

[0034] A second aspect of the invention is an assembly (or stack) of a wafer and a carrier as in the first aspect of the invention. The wafer is bonded by means of an adhesive onto the second porous layer. Preferably, the adhesive is an adhesive that can be removed by means of contacting a suitable debonding liquid to the adhesive.

[0035] A third aspect of the invention is a method for the processing of wafers.

The method comprises the steps of

- temporarily adhering a wafer to a carrier as in the first aspect of the invention by means of an adhesive,

- processing the wafer temporarily adhered to the carrier, e.g. thinning the wafer;

- debonding the wafer from the carrier, by means of a debonding liquid breaking up the temporary adhesive bond between the wafer and the carrier; wherein the debonding liquid penetrates into the porous metal medium from the side edges of the assembly of the wafer bonded by means of adhesive to the carrier.

During and after debonding a wafer temporarily bonded to the carrier, the first layer remains bonded to the porous metal medium. In a preferred method, the carrier is after debonding re-used one or more times for temporarily adhering another wafer onto it. Preferably, the carrier can be used at least 5 times, more preferably at least 10 times.

Brief Description of Figures in the Drawings

[0036] Figure 1 shows a top view of an exemplary carrier according to the

invention.

Figure 2 shows the cross section of an exemplary carrier according to the invention.

Figure 3 shows an example of an assembly of a wafer temporarily bonded to an inventive carrier.

Mode(s) for Carrying Out the Invention

[0037] Figure 1 shows the top view of a carrier 100 according to the invention.

The carrier 100 has the shape of a disk deviating from a circular circumference (with diameter D) by a linear side 102. The linear side 102 is present in order to match the shape of a wafer to be bonded to the work carrier.

[0038] Figure 2 shows a cross section of an exemplary carrier 200 according to the invention. The carrier 200 comprises a first layer 210. The first layer is a metal foil or a metal sheet. The carrier 200 further comprises a first porous layer, e.g. a sintered nonwoven metal fiber web 222; and a second porous layer, e.g. another sintered nonwoven metal fiber web 224 sintered or bonded by means of welding (e.g. capacity discharge welding). The porosity of the first porous layer is higher than the porosity of the second porous layer.

Preferably, the metal foil or metal sheet and the fibers of the nonwoven metal fiber webs are out of the same metal or alloy.

The nonwoven metal fiber webs 222, 224 are permanently bonded to each other and to the first layer 210, e.g. by means of an adhesive (e.g. an epoxy adhesive) or by means of sintering or by means of welding (e.g. capacity discharge welding). Instead of one or both of the nonwoven metal fiber webs, sintered porous metal powder layers and/or metal foam layers can be used for the first porous layer and/or the second porous layer.

Instead of a metal foil or a metal sheet, e.g. a glass, ceramic or silicon sheet or plate can be used as first layer. The first and the second porous layers are bonded to each other by means of metallic bonds, e.g. sintering and the bonding with the first layer can then be done by means of an adhesive, e.g. epoxy.

[0039] Figure 3 shows an example of an assembly or stack 301 of a wafer

temporarily bonded to a carrier, e.g. the carrier 200 of the example of figure 2. Same reference numbers as in figure 2 have the same meaning as described for figure 2. A temporary adhesive layer 370 is applied onto the porous metal medium of the carrier 200, and a wafer is 380 is temporarily bonded to the carrier 200 via this adhesive layer 370.

[0040] An exemplary carrier was made having a total thickness of 700 μιτι; and for use with an 8 inch wafer. The carrier has as first layer a titanium foil of 250 μιτι thickness. On top of that a nonwoven titanium fiber web (of titanium fibers of equivalent diameter 22 μιτι) is applied as first porous layer and a sintering operation is performed to sinter the first porous layer to the titanium foil. In the final carrier, this first porous layer has a specific weight of 500 g/m² and a porosity of 56%. On top of this first porous layer, a second porous layer of 200 μιτι thickness is applied consisting out of a nonwoven titanium fiber web out of titanium fibers of 14 μιτι equivalent diameter. The second porous layer has a density of 500g/m² and 45% porosity in the final carrier. The second porous layer is bonded into the carrier by means of a separate sintering operation. The surface of the carrier to be bonded onto a wafer can be polished below a total thickness variation (TTV) of the carrier of 10 μιτι.

By means of spin coating, a silicon based adhesive was applied to the second porous layer of the carrier. The device wafer was bonded at 25°C and 0.8 bar pressure during 10 minutes. By having the lower porosity in the second porous layer, it was shown in a cross section that the adhesive did not penetrate further in the porous layers than in the second porous layer. The wafer could be thinned down to 50 μηη while being adhered to the carrier. In the debonding step, immersing the bonded stack (the stack being the combination of the wafer temporarily bonded to the carrier) in Daeclean 300 - a commercially available solvent system for removal of cured silicone adhesive - at 25°C it was shown that the device wafer was fully debonded in 4 minutes 50 seconds.

Claims

Claims

1 . Carrier onto which a wafer can be temporarily bonded,

wherein the carrier comprises a plate shaped laminate,

the plate shaped laminate comprises:

- a first layer, wherein the first layer comprises a foil, a sheet or a plate; and

- a second layer comprising a porous metal medium with three-dimensional open pores; wherein the porous metal medium comprises metal fibers;

wherein the first layer is permanently bonded to the porous metal medium thereby closing the pores of the porous metal medium at the side where the first layer is located;

wherein the porous metal medium comprises a first porous layer and a second porous layer,

wherein the first porous layer is provided between the first layer and the second porous layer; and

wherein the porosity of the first porous layer is higher than the porosity of the second porous layer.

2. Carrier as in claim 1 , wherein the porosity of the first porous layer is more than 50 %.

3. Carrier as in any of the preceding claims, wherein the porosity of the second porous layer is less than 60 %.

4. Carrier as in any of the preceding claims, wherein the first layer comprises metal, or glass, or silicon or ceramic.

5. Carrier as in any of the preceding claims, wherein the first layer comprises metal;

and wherein the first layer comprises the same metal or alloy as the porous metal medium.

6. Carrier as in any of the preceding claims, wherein said porous metal medium comprises stainless steel, titanium, palladium or tungsten; or an alloy comprising for more than 50% by weight of titanium, palladium or tungsten.

7. Carrier as in any of the claims 1 - 6,

wherein the first layer comprises metal; and

wherein the first layer is permanently bonded to the porous metal medium by means of metallic bonds.

8. Carrier as in any of the claims 1 - 7, wherein the first layer is permanently bonded to the porous metal medium by means of an adhesive.

9. Carrier as in any of the preceding claims, wherein the equivalent diameter of the metal fibers is between 2 and 50 μιτι.

10. Camer as in any of the preceding claims, wherein the porous metal medium has a surface for being bonded onto a wafer, wherein this surface is parallel with the first layer; and wherein this surface is polished so that the carrier has a total thickness variation (TTV) less than 10 μιτι.

1 1 . Carrier as in any of the preceding claims, wherein the second layer comprises a contact layer for being bonded onto a wafer,

wherein the contact layer comprises a mixture of metal fibers and metal powder,

wherein the metal fibers and the metal powder are permanently bonded to each other at their contacting points.

12. Carrier as in any of the preceding claims, wherein the side edges of the

porous metal medium are permanently sealed so that no open pores are present at the side edges of the porous metal medium.

13. Assembly of a wafer and a carrier as in any of the preceding claims,

wherein the wafer is bonded by means of an adhesive onto said second porous layer.

14. Method for the processing of wafers, comprising the steps of

- temporarily adhering a wafer to a carrier as in any of the claims 1 - 12 by means of an adhesive,

- processing the wafer temporarily adhered to the carrier;

- debonding the wafer from the carrier, by means of a debonding liquid breaking up the temporary adhesive bond between the wafer and the carrier; wherein the debonding liquid penetrates into the porous metal medium from the side edges of the assembly of the wafer bonded by means of adhesive to the carrier.