JP2007073929A - Method of thinning substrate and method of manufacturing circuit element - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of thinning a substrate which can prevent transfer of a through-hole trace of a support plate onto the surface of a substrate, and can prevent cutting unevenness on the surface of the substrate, and to provide a method of manufacturing a circuit element. <P>SOLUTION: In the support plate 1 integrated with a substrate W by an adhesive 2, the surface where a sheet 6 is pasted is placed on the top surface of a suction head 7, and is sucked and fixed. The top surface of the substrate W (surface where a circuit is not formed) is ground in this state by a grinder 8. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for thinning a substrate such as a semiconductor wafer and a method for manufacturing a circuit element using this method.

  IC cards and mobile phones are required to be thinner, smaller, and lighter. In order to satisfy these demands, a semiconductor chip to be incorporated must be a thin semiconductor chip. For this reason, the thickness of the wafer on which the semiconductor chip is based is currently 125 μm to 150 μm, but it is said that a thickness of 25 μm to 50 μm is required for the next generation chip.

As a method for thinning a semiconductor wafer, a method disclosed in Patent Document 1 has been proposed.
In this method, a glass plate, ceramic plate, metal plate, or other rigid support plate such as a glass plate, a ceramic plate, or a metal plate is attached to the circuit element forming surface of the semiconductor wafer and integrated. Then, the support plate is fixed on the suction head in an integrated state. In this state, the back surface of the semiconductor wafer is ground with a grinder to make it thinner.

JP 2005-150434 A

  By the way, in the thinning method disclosed in Patent Document 1, in order to dice after thinning, the support plate must be peeled from the substrate. However, since the substrate and the support plate are bonded with an adhesive without a gap, they cannot be easily peeled off.

  Therefore, the present inventors have previously proposed a support plate in which a large number of through holes through which a solvent flows are formed.

When thinning (grinding) using such a support plate, as shown in FIG. 6, after the support plate is bonded to one surface (circuit formation surface) of the semiconductor wafer W, a laminated body is formed. In this laminated body, the support plate side is placed and fixed on the suction head, and in this state, the other surface (the surface opposite to the circuit formation surface) of the semiconductor wafer W is ground by a grinder.

  However, in the case of such a thinning method, since it is always sucked (vacuum suction) during grinding, the inside of the through hole is decompressed by the negative pressure at the time of vacuum suction, and the semiconductor thinned by this amount through the adhesive layer The pattern of the through hole may be transferred to the circuit element forming surface of the wafer W.

Further, when the other surface of the semiconductor wafer W is ground by a grinder, the semiconductor wafer W may be pulled to the suction head side through the support plate and the adhesive layer due to the negative pressure of vacuum suction.
In this case, since the wafer W is separated from the grinder, there may be a problem in that the surface of the wafer W (the other surface) is subject to shaving unevenness or deterioration of the surface roughness. This leads to a great influence on the characteristics of the circuit elements formed when the circuit elements are formed on the other surface of the wafer W, for example.

In view of the points described above, the present invention can reduce the transfer of through-hole marks to the substrate,
The present invention provides a method for thinning a substrate and a method for manufacturing a circuit element that can reduce the occurrence of shaving unevenness on the surface of the substrate.

  The thinning method according to the present invention is a method of thinning a substrate using a support plate having a large number of through holes, and a laminated body is formed by bonding one surface of the support plate to the circuit forming surface of the substrate. A step of bonding a sheet to the other surface of the support plate in the laminate, and a step of grinding the surface opposite to the circuit forming surface of the substrate in a state where the laminate is fixed via the sheet It is characterized by having.

According to the substrate thinning method of the present invention, a step of forming a laminated body by bonding one surface of a support plate to a circuit forming surface of the substrate, and a sheet on the other surface of the support plate in the laminated body And the step of grinding the surface opposite to the circuit forming surface of the substrate in a state where the laminate is fixed via the sheet, the laminate is adsorbed via the sheet, for example. In the process of grinding the surface opposite to the circuit formation surface of the substrate while being fixed by vacuum suction by the head, a sheet adhered to the other surface of the support plate prior to this process It is possible to prevent the negative pressure in the through hole from being reduced by blocking the negative pressure. Thereby, it can reduce that the pattern of a through-hole is transcribe | transferred to the circuit element formation surface of a board | substrate.
Further, since the negative pressure during vacuum suction can be blocked by the sheet and the substrate can be prevented from being pulled toward the suction head, for example, it is possible to reduce the occurrence of shaving unevenness on the surface of the substrate.

  A method for manufacturing a circuit element according to the present invention is a method for manufacturing a circuit element using the above-described method for thinning a substrate, wherein the sheet is formed following the step of grinding the surface of the substrate opposite to the circuit forming surface. The step of peeling, the step of bonding dicing tape to the surface of the substrate opposite to the circuit formation surface, and the solvent are used to dissolve the adhesive layer interposed between the support plate and the circuit formation surface of the substrate. And a step of peeling the support plate from the substrate.

  According to the above-described method of manufacturing a circuit element according to the present invention, following the step of grinding the surface of the substrate opposite to the circuit formation surface, the step of peeling the sheet and the substrate opposite to the circuit formation surface A step of bonding a dicing tape to the surface, a step of dissolving an adhesive layer interposed between the support plate and the circuit forming surface of the substrate using a solvent, and a step of peeling the support plate from the substrate. Therefore, for example, when a process of cutting the substrate for each element is performed thereafter, it is possible to obtain a circuit element that does not affect the characteristics in addition to the above-described action.

  A circuit element manufacturing method according to the present invention is a circuit element manufacturing method using the above-described substrate thinning method, following the step of grinding the surface of the substrate opposite to the circuit forming surface, Adhesive layer interposed between the support plate and the circuit forming surface of the substrate using a solvent, a step of attaching dicing tape to the surface opposite to the circuit forming surface of the substrate, a step of peeling the sheet, and a solvent A step of dissolving and a step of peeling the support plate from the substrate.

  According to the above-described method for manufacturing a circuit element according to the present invention, following the step of grinding the surface of the substrate opposite to the circuit formation surface, the dicing tape is applied to the surface of the substrate opposite to the circuit formation surface. A step of bonding, a step of peeling off the sheet, a step of dissolving the adhesive layer interposed between the support plate and the circuit forming surface of the substrate using a solvent, and a step of peeling the support plate from the substrate Therefore, for example, when a process of cutting the substrate for each element is performed thereafter, it is possible to obtain a circuit element that does not affect the characteristics in addition to the above-described action.

ADVANTAGE OF THE INVENTION According to this invention, while being able to reduce that the pattern of a through-hole is transcribe | transferred to a board | substrate, the thinning method of a board | substrate and the formation method of a circuit element which can suppress reduction of the shaving nonuniformity of a board | substrate and deterioration of surface roughness It becomes possible to provide.
Therefore, it is possible to manufacture a circuit element having good characteristics and to improve the reliability in the manufacturing process.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
FIG. 1 is a schematic cross-sectional view showing an embodiment of a wafer thinning method according to the present invention.
2 is a perspective view of the support plate, and FIG. 3 is a cross-sectional view of the support plate.
FIG. 1 shows a state where a sheet has already been attached to the other surface of the support plate.

In FIG. 1, reference numeral 1 denotes a support plate made of a glass plate, a ceramic plate, a metal plate or the like, and one surface of the support plate 1 and a circuit forming surface of the semiconductor wafer W are bonded together by an adhesive layer 2.

In the support plate 1, as shown in FIGS. 2 and 3, a large number of through holes 3 through which the solvent flows are formed in the thickness direction. The outer peripheral portion (edge peripheral portion) of the support plate 1 is a flat portion 4 in which the through hole 3 is not formed.
The number of through-holes 3 formed and the positions where they are formed are not limited, and various modes are conceivable.
As the solvent (chemical solution), for example, an alcohol type or alkaline type can be used.
In addition, as the support plate 1 shown in FIGS. 1-3, although the outer peripheral part used what was the flat part 4 in which the through-hole 3 is not formed, in addition to this, it is the substantially whole area to an outer peripheral part. It is also conceivable to use one having through-holes 3 formed therein.

As the sheet 6 attached to the other surface of the support plate 1, a sheet having characteristics such as resistance to heat generated when the sheet is actually thinned and resistance to a solvent to be used is preferable. Further, it is more preferable if these characteristics have characteristics such as moderate adhesiveness to the support plate 1 and peelability.
In the present embodiment, for example, a resin sheet (for example, polyimide) is used as the sheet 6 having such characteristics.

  Next, an embodiment of a substrate thinning method using the support plate 1 having such a configuration will be described.

First, one surface of the support plate 1 is bonded to the circuit forming surface of the semiconductor wafer W via the adhesive layer 2 to form a laminate.

  Next, the sheet 6 is bonded to the other surface of the support plate 1 in the laminate.

Next, the surface of the support plate 1 to which the sheet 6 is adhered is placed on the upper surface of the suction head 7 and sucked and fixed. In this state, the surface of the semiconductor wafer W on which no circuit is formed is ground by the grinder 8. . In this way, the semiconductor wafer W is thinned.

In the present embodiment, since the sheet 6 is adhered between the suction head 7 and the support plate 1, even if the sheet 6 is always sucked during grinding, the negative pressure can be blocked by the sheet 6. The pressure reduction by the suction head 7 can be prevented from reaching the through hole 3. For this reason, it can reduce that the pattern of the through-hole 3 is transcribe | transferred to the semiconductor wafer W thinned.
In addition, since the negative pressure can be blocked or alleviated by the sheet 6, the semiconductor wafer W can be prevented from being pulled and the occurrence of grinding unevenness or the like can be suppressed.

Further, the grinding is performed while the processing liquid (for example, water) is supplied. However, the sheet 6 can prevent water from entering the through hole 3 from between the suction head 7 and the support plate 1, for example. Thereby, it is possible to prevent the support plate 1 from being peeled off from the semiconductor wafer W. In addition, when the support plate 1 is used again, the time required for drying the support plate 1 can be greatly reduced.
Further, it is possible to prevent grinding scraps from entering the through hole 3 by the sheet 6.
In addition, since the sheet | seat 6 is excellent in chemical resistance, it is also possible to prevent the support plate 1 from being damaged.

Next, the peeling process of the support plate 1 performed after the thinning of the semiconductor wafer W will be described.

First, as shown in FIG. 4, the laminated body in which the thinned semiconductor wafer W and the support plate 1 are bonded to each other is removed from the suction head, and the surface of the semiconductor wafer W on which the circuit is not formed (that is, the circuit forming surface). Is attached to the dicing tape 9.

  Next, the sheet 6 is peeled from the support plate 1, and the plate (solvent supply plate) 10 is pressed against the other surface of the support plate 1.

  In this state, as shown in FIG. 4, when the solvent is supplied through the solvent supply hole 11 of the plate 10, the solvent spreads to the adhesive layer 2 through the numerous through holes 3 of the support plate 1 and the adhesive layer 2. Dissolve.

  Then, the solvent in which the adhesive layer 2 is dissolved is discharged (collected) to the outside through the solvent discharge hole 12 of the plate 10.

Thereafter, in order to peel the support plate 1 from the semiconductor wafer W, the support plate 1 is sandwiched and pulled up by, for example, a clamp-shaped arm.
As a result, the semiconductor wafer W remains on the dicing tape 9, and only the support plate 1 is peeled off.
Then, the semiconductor wafer W on the dicing tape 9 is cut with a cutter along the streets to obtain individual circuit elements.

When forming circuits (including through electrodes) on both sides of the semiconductor wafer W, the semiconductor wafer W and the support plate 1 are integrated after the semiconductor wafer W is thinned. A new circuit is formed on the other surface (ground surface).
In this case, in the present embodiment, it is possible to reduce the occurrence of shaving unevenness on the other surface of the semiconductor wafer W during grinding as described above, so that a circuit element that does not affect the characteristics can be formed.

  In the embodiment described above, the case where a resin sheet (polyimide) is used as the sheet 6 has been described. However, a so-called reaction tape in which the adhesive force is reduced by remote means such as UV irradiation or heating, A pressure sensitive tape such as BG tape or dicing tape can be used.

In the above-described embodiment, the case where the sheet 6 is attached has been described. However, for example, a protective film may be formed instead of the sheet 6. In this case, a protective film such as a water-soluble resin liquid or a solubilizer resin is formed on the other surface of the support plate 1.
In this case as well, the same action as when the sheet 6 is pasted can be obtained.

In the above-described embodiment, the surface of the semiconductor wafer W on which the circuit is not formed (that is, the surface opposite to the circuit forming surface) is ground by the grinder 8, and then the dicing tape 9 is bonded to this surface. The case where the sheet 6 is peeled off is described.
However, after grinding the surface of the semiconductor wafer W where the circuit is not formed with the grinder 8,
The sheet 6 may be peeled off, and the dicing tape 9 may be bonded to the surface of the semiconductor wafer W where the circuit is not formed.
That is, the difference is whether the sheet 6 is peeled off after the dicing tape 9 is bonded, or the dicing tape 9 is bonded after the sheet 6 is peeled off.
Even in this case, the same effect as the above-described embodiment can be obtained.

FIG. 5 is a graph obtained by measuring the flatness of the ground surface of the semiconductor wafer W when the sheet 6 is adhered and when the sheet 6 is not adhered.
In addition, this graph has shown the case where it carries out for every 3 diameter of each through-hole of a support plate.
Also, X is shown when there is a tape, and Y is shown when there is no tape.

  As shown in FIG. 5, when the sheet 6 is adhered, the pattern of the through hole 3 can be reduced from being transferred to the semiconductor wafer and the unevenness is reduced as compared with the case where the sheet 6 is not adhered. I understand.

  The present invention is not limited to the above-described embodiment, and various other configurations can be taken without departing from the gist of the present invention.

Sectional drawing of one implementation state of the wafer thinning method which concerns on this invention. The perspective view of a support plate. Sectional drawing of a support plate. Sectional drawing of the state which has melt | dissolved the adhesive agent. The graph which measured the flatness of the grinding surface of a board | substrate when not sticking a sheet | seat. The figure explaining the subject before improvement.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Support plate, 2 ... Adhesive layer, 3 ... Through-hole, 4 ... Flat part, 6 ... Sheet, 7 ... Adsorption head, 8 ... Grinder, 9 ... Dicing tape, 10 ... Plate, 11 ... Solvent supply hole, 12 ... Solvent discharge hole, 13 ... Vacuum drawing hole, 14 ... Recess

Claims (5)

A method of thinning a substrate using a support plate having a large number of through holes,
Forming a laminate by bonding one surface of the support plate to the circuit forming surface of the substrate;
In the laminate, a step of bonding a sheet to the other surface of the support plate;
Grinding the surface of the substrate opposite to the circuit forming surface in a state where the laminate is fixed via the sheet. In the manufacturing method of the circuit element using the thinning method according to claim 1,
Following the step of grinding the surface of the substrate opposite to the circuit forming surface, the step of peeling the sheet,
A step of bonding a dicing tape to a surface opposite to the circuit forming surface of the substrate;
Using a solvent, dissolving the adhesive layer interposed between the support plate and the circuit forming surface of the substrate;
And a step of peeling the support plate from the substrate. 3. The method of manufacturing a circuit element according to claim 2, wherein a circuit is formed on a surface opposite to the circuit formation surface immediately after the step of grinding the surface opposite to the circuit formation surface of the substrate, and thereafter A method for producing a circuit element, comprising performing a step of peeling the sheet. In the manufacturing method of the circuit element using the thinning method according to claim 1,
Subsequent to the step of grinding the surface of the substrate opposite to the circuit forming surface, a step of bonding a dicing tape to the surface of the substrate opposite to the circuit forming surface;
Peeling the sheet;
Using a solvent, dissolving the adhesive layer interposed between the support plate and the circuit forming surface of the substrate;
And a step of peeling the support plate from the substrate. 5. The method of manufacturing a circuit element according to claim 4, wherein a circuit is formed on a surface opposite to the circuit forming surface immediately after the step of grinding the surface of the substrate opposite to the circuit forming surface. A method for manufacturing a circuit element, comprising performing a step of peeling the sheet later.