JP2017204555A - Cutting method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a processing method that is able to hinder occurrence of crack.SOLUTION: A cutting step comprises: a first cutting step in which, after a holding step, a stuck wafer is cut up to the support wafer along an internal circumferential edge of an annular area by a first cutting blade thinner than a predetermined width of an annular area, the wafer is cut along an internal circumferential edge by the first cutting blade while the first cutting blade and a holding table are moved relative to each other, and part of the annular area is removed to form a first cut groove; and a second cutting step in which, after the first cutting step, the stuck wafer is cut up to the support wafer while a second cutting blade thicker than the first cutting blade is placed over part of the first cutting groove in the annular area further on the outer peripheral side than the first cut groove, the wafer is cut by the second cutting blade while the second cutting blade and the holding table are moved relative to each other, and a remaining portion of the annular area is removed.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a cutting method for removing an annular region having a predetermined width from the outer peripheral edge of a bonded wafer in which a wafer is bonded to a support wafer via an adhesive member.

  A semiconductor wafer has devices (elements) such as ICs and LSIs formed on the surface, and each device is partitioned by division planned lines called streets formed in a lattice shape. Thereafter, the back surface of the semiconductor wafer is ground and thinned to a predetermined thickness, and then cut along the streets by a cutting device to be divided into individual chips. The divided chips are widely used by being mounted on various electronic devices such as mobile phones and personal computers.

  In recent years, with the downsizing and thinning of electronic devices, there is a demand for downsizing and thinning of chips mounted on the electronic devices. For this reason, a semiconductor wafer (hereinafter simply referred to as a wafer) in which a plurality of devices are formed may be thinly ground to a thickness of, for example, 100 μm or less.

  In general, a wafer is chamfered so that the outer shape of the wafer has an arc shape in order to prevent cracking and dust generation during the manufacturing process. Then, when the wafer is thinly ground as described above, the chamfered portion is sharply sharp like a knife edge, and the wafer is damaged due to chipping from the outer periphery of the wafer.

  Therefore, the wafer is processed before being thinly ground, and the chamfered portion is removed along the outer periphery of the wafer (see, for example, Patent Document 1 and Patent Document 2). Cutting along the outer peripheral edge of the wafer in this way is sometimes called trimming.

  By the way, in order to improve the handleability of thin wafers or to prevent warping or breakage of the wafer during processing, the wafer is bonded to another support wafer to form a bonded wafer, and the bonded wafer There is known a technical idea of processing as a unit (see, for example, Patent Document 3). The bonded wafer is composed of a wafer, a support wafer having the same diameter as the wafer, and an adhesive member for bonding the both.

JP 2003-273053 A Japanese Patent Laid-Open No. 2004-207459 JP-A-4-263425

  In the process of removing a region having a predetermined width along the outer peripheral edge of the wafer, a cutting blade having a thickness larger than that of a cutting blade used in a normal dicing process is used. This is because a larger area is cut as compared with a normal dicing process. For example, the thickness of the cutting blade used in a normal dicing process or the like is about 15 μm to 30 μm. On the other hand, when removing an annular region having a predetermined width from the outer peripheral edge of the wafer, a cutting blade having a thickness of about 0.5 mm to 1 mm is used.

  However, as the thickness of the cutting blade used for wafer cutting increases, the load (processing load) applied to the processed wafer also increases, and large chips and cracks are generated at the cutting edge cut by the cutting blade. It becomes easy. If a crack occurs in the wafer, the crack may reach the device and damage the device.

  In order to suppress the occurrence of such chips and cracks, a cutting blade containing abrasive grains having a small particle diameter may be used. When a cutting blade having a small abrasive grain size is used, the processing load applied to the wafer can be reduced. However, since a cutting blade with a small abrasive grain size has a small cutting ability, the time required for the cutting process increases and the productivity tends to decrease.

  Further, when the wafer attached to the support wafer is completely cut, the cutting blade reaches the adhesive member under the wafer. When the adhesive member is cut with the cutting blade, the cutting blade may be clogged with the generated cutting waste. When a clogged cutting blade is used as it is, cracks are likely to occur in the wafer, but clogging is particularly likely to occur in a cutting blade having a small abrasive grain size.

  In this way, when removing the annular region of a predetermined width of the wafer adhered on the support wafer along the outer peripheral edge, if a cutting blade having a large thickness is used, the processing load increases and a crack occurs in the wafer. It becomes easy. However, simply using a thin cutting blade increases the time required for cutting. In addition, since a cutting blade having a small abrasive grain size is clogged, the probability of occurrence of cracks cannot be sufficiently reduced.

  The present invention has been made in view of such problems. The purpose is to reduce the occurrence of cracks when trimming a wafer attached to a support wafer without significantly increasing the processing time compared to processing using only a thick cutting blade. It is to provide a processing method that can be suppressed.

  According to one aspect of the present invention, a cutting blade is cut into the support wafer on the bonded wafer in which the wafer is bonded onto the support wafer via the adhesive member, and the wafer is cut along the outer peripheral edge of the wafer. A cutting method for removing an annular region having a predetermined width from the outer peripheral edge of the wafer, the holding step of holding the support wafer side of the bonded wafer by a holding table, and after the holding step, A first cutting blade having a thickness smaller than the predetermined width of the annular region is cut into the bonded wafer along the inner periphery of the annular region up to the support wafer, and the first cutting blade and the holding table are A part of the annular region is removed by cutting the wafer along the inner peripheral edge with the first cutting blade by relative movement and the first cutting blade removes the first cutting. A first cutting step for forming the first cutting groove and a second cutting blade thicker than the first cutting blade in the annular region on the outer peripheral side of the first cutting groove after performing the first cutting step. And cutting the wafer with the second cutting blade by moving the second cutting blade and the holding table relative to each other. And a second cutting step for removing the remaining portion.

  In the cutting method according to the present invention, a cutting groove is provided in the wafer in advance using a thin first cutting blade that does not easily generate cracks, and then a portion radially outside the cutting groove with a thick second cutting blade. Remove the wafer. Even when a crack is generated in the process of cutting with the second cutting blade, the extension of the crack is prevented by the cutting groove. Therefore, the occurrence of cracks in the wafer can be suppressed without significantly increasing the processing time as compared with the case of processing using only a thick cutting blade.

FIG. 1A is a diagram schematically showing a cross-sectional structure of a bonded wafer. FIG. 1B is a cross-sectional view schematically showing the bonded wafer and the holding table in the holding step. FIG. 2A is a schematic cross-sectional view showing the first cutting blade, the bonded wafer, and the holding table in the first cutting step, and FIG. 2B illustrates the cutting groove formed by the first cutting step. It is a cross-sectional schematic diagram to do. FIG. 3A is a schematic cross-sectional view showing a second cutting blade, a bonded wafer, and a holding table in the second cutting step, and FIG. 3B illustrates an area to be cut and removed by the second cutting step. It is a cross-sectional schematic diagram to do. FIG. 4A is a schematic diagram illustrating a cross-sectional structure of a bonded wafer after the second cutting step is performed, and FIG. 4B is a schematic cross-sectional diagram illustrating a wafer thinning process.

  Embodiments according to the present invention will be described with reference to the accompanying drawings. The processing method according to the present embodiment includes a holding step, a first cutting step, and a second cutting step. Further, a wafer thinning step after the second cutting step may be included.

  FIG. 1 is a cross-sectional view schematically showing an example of a bonded wafer which is a workpiece of the processing method according to the present invention.

  The bonded wafer 1 includes a wafer 3 and a support wafer 5, both of which are bonded via an adhesive member 7 provided between the surface 3 a of the wafer 3 and the first surface 5 a of the support wafer 5. Affixed and integrated. By handling the wafer 3 integrally with the support wafer 5, it is possible to improve the handleability of the wafer, which has recently been remarkably thinned, and to prevent warping and breakage of the wafer during processing.

  The front surface 3a on which the device 3c of the wafer 3 is formed faces the first surface 5a of the support wafer 5, and the back surface 3b of the wafer 3 is an upper surface when the bonded wafer 1 is held on the holding table. Further, the second surface 5 b of the support wafer 5 is a lower surface (held surface) when the bonded wafer 1 is held by the holding table 2.

  The wafer 3 is made of a material such as silicon, sapphire, SiC (silicon carbide), or other compound semiconductor, and a device 3c such as an IC, LSI, or MEMS is formed on the surface. As the support wafer 5, for example, a wafer made of the same material as that used for the wafer 3 may be used.

  Next, the holding step in the cutting method according to the present embodiment will be described with reference to FIG. FIG. 1B is a cross-sectional view schematically showing the bonded wafer 1 and the holding table 2 in the holding step. The holding table 2 can rotate around an axis perpendicular to the surface thereof, and the bonded wafer 1 held by the holding table 2 also rotates. In the subsequent first cutting step and second cutting step, the annular region 9 having a predetermined width is cut from the outer peripheral edge of the wafer 3 by rotating the holding table 2.

  The holding table 2 includes a disk-shaped member 4 made of a metal material such as stainless steel and having a recess at the center of the upper surface, and a porous member 6 made of porous ceramic or the like disposed in the recess. The porous member 6 has a holding surface 6a for holding the bonded wafer on the upper surface, and is connected to a suction source (not shown). The porous member 6 has a plurality of minute suction holes on the holding surface 6a, and can suck and hold the bonded wafer 1 placed on the holding surface 6a by the action of the negative pressure generated by the suction source.

  In the holding step, first, the bonded wafer 1 is placed on the porous member 6 so that the second surface 5b of the support wafer 5 is in contact with the holding surface 6a. Next, the bonded wafer 1 is sucked and held by the porous member 6 by applying a negative pressure generated by a suction source through the plurality of suction holes of the porous member 6. Note that the bonded wafer 1 continues to be held by the porous member 6 while the processing method according to the present embodiment is performed thereafter.

  Next, the first cutting step in the processing method according to the present embodiment will be described with reference to FIG. The first cutting step is performed after the holding step is performed. In the processing method according to the present embodiment, the annular region 9 having a predetermined width is finally removed from the outer peripheral edge of the wafer 3, but in this step, first, the first having a thickness smaller than the width of the annular region 9. A first cutting groove 11 is formed along the inner peripheral edge of the annular region 9 by the cutting blade 8a.

  The first cutting unit 8 used in the first cutting step will be described. As shown in FIG. 2A, the first cutting unit 8 includes a first spindle 8b and a first cutting blade 8a connected to the tip of the first spindle 8b. The first cutting unit 8 can rotate around the first spindle 8b, and the first cutting blade 8a rotates together with the first spindle 8b. The first cutting unit 8 can be moved up and down, and the rotating first cutting blade 8 a can be vertically lowered to a predetermined depth in the bonded wafer 1.

  The first cutting blade 8a has a thickness smaller than the width of the annular region 9, and the thickness is smaller than the thickness of a second cutting blade 10a (see FIG. 3A) described later. Moreover, the 1st cutting blade 8a has an abrasive grain with a particle size smaller than the particle size of the abrasive grain which the 2nd cutting blade 10a mentioned later has.

  Accordingly, the first cutting blade 8a has a narrower cutting range and lower cutting ability than the second cutting blade 10a. On the other hand, since the first cutting blade 8a has a smaller load (processing load) applied to the workpiece by cutting than the second cutting blade 10a, the possibility of causing damage such as cracks to the workpiece is small.

  In order to prepare for cutting in the first cutting step, the first cutting unit 8 is disposed above the bonded wafer 1 with the first spindle 8 b oriented substantially parallel to the radial direction of the bonded wafer 1. Further, the position of the first cutting blade 8 a is adjusted so that the end of the first cutting blade 8 a on the center side of the bonded wafer 1 is directly above the inner peripheral edge of the annular region 9.

  Next, cutting in the first cutting step is performed. First, the rotation of the first spindle 8b is started and the first cutting blade 8a is in a rotating state. Next, the first cutting unit 8 is vertically lowered toward the bonded wafer 1 while maintaining the rotation of the first cutting blade 8 a. Then, in order to completely cut the wafer 3, the first cutting blade 8 a is cut through the wafer 3 and the adhesive member 7 until a predetermined depth of the support wafer 5 is reached.

  FIG. 2A schematically shows a cross-sectional structure of the bonded wafer 1, the first cutting unit 8, and the holding table 2 in a state where the first cutting blade 8 a is cut to the predetermined depth of the support wafer 5. It is the figure shown in.

  Next, the rotation of the holding table 2 is started while maintaining the rotation of the first cutting blade 8a. Then, the annular region 9 is continuously cut along the inner peripheral edge while the bonded wafer 1 is rotated, and the annular first cutting groove 11 is formed. The first cutting groove 11 may be formed by starting the rotation of the holding table 2 before lowering the rotating first cutting unit 8 and then lowering the rotating first cutting unit 8.

  FIG. 2B schematically shows a cross-sectional structure of the bonded wafer 1 after the first cutting step is performed. By this step, the annular first cutting groove 11 is formed.

  In the first cutting step in the processing method according to the present embodiment, the first cutting blade 8a is positioned immediately above the inner peripheral edge of the annular region 9, and the first cutting blade 8a is brought to a predetermined depth of the support wafer 5 from above. It is not limited to descending until it reaches.

  For example, the first cutting blade 8 a may be lowered in advance to a position where it can be cut to the predetermined depth at a position away from the bonded wafer 1, and then horizontally moved toward the bonded wafer 1. The first cutting blade 8a is rotated and horizontally cut to the inner periphery of the annular region 9, and then the holding table 2 is rotated while maintaining the rotation of the first cutting blade 8a. The groove 11 may be formed.

  Next, the second cutting step in the processing method according to the present embodiment will be described with reference to FIG. The second cutting step is performed after the first cutting step is performed. The annular region 9 in the vicinity of the outer peripheral edge of the wafer 3 has already been partially removed through the first cutting step, and the first cutting groove 11 has been formed. In this second cutting step, the remaining annular region 9 remains. 9a (see FIG. 3B) is removed.

  The second cutting unit 10 used in the second cutting step will be described. The second cutting unit 10 includes a second spindle 10b and a second cutting blade 10a connected to the tip of the second spindle 10b. The second cutting unit 10 can rotate about the second spindle 10b, and the second cutting blade 10a rotates together with the second spindle 10b.

  The second cutting blade 10a has a thickness larger than the width of the remaining portion 9a of the annular region 9, and the thickness is larger than the thickness of the first cutting blade 8a. Moreover, the 2nd cutting blade 10a has an abrasive grain with a larger particle size than the particle size of the abrasive grain which the above-mentioned 1st cutting blade 8a has.

  Therefore, the second cutting blade 10a has a wider cutting range and higher cutting ability than the first cutting blade 8a. On the other hand, since the load (working load) applied to the workpiece by cutting is greater than that of the first cutting blade 8a, the second cutting blade 10a is likely to cause damage such as cracks on the workpiece.

  However, even if damage such as cracks occurs in the annular region 9 by cutting the remaining portion 9a of the annular region 9, the first cutting groove 11 is present, so that cracks toward the radial center of the wafer 3 occur. Is prevented from extending. Therefore, cracks do not extend in the device 3c formed on the surface 3a of the wafer 3, and the device 3c is not damaged in the second cutting step.

  Before using a cutting blade with a high cutting ability, the first cutting groove is formed in the minimum necessary time using a cutting blade with a small processing load, so that the time required for the cutting process is not significantly increased. Damage to the work piece can be prevented.

  In order to prepare for cutting in the second cutting step, the second cutting unit 10 is disposed above the bonded wafer 1 with the second spindle 10b oriented substantially parallel to the radial direction of the bonded wafer 1. Further, the position of the second cutting unit 10 is adjusted so that the second cutting blade 10 a covers the entire width of the remaining portion 9 a of the annular region 9.

  At this time, the second cutting blade 10a is positioned so as to overlap with a part of the first cutting groove 11 so that the remaining portion 9a of the annular region 9 is surely cut by the second cutting step. Here, FIG. 3B schematically shows a cross-sectional structure in the vicinity of the outer peripheral edge of the bonded wafer 1 before the second cutting step is performed. That is, a region including a part of the first cutting groove 11 and the remaining portion 9a of the annular region 9 becomes a portion 9b where the second cutting blade 10a descends.

  Cutting in the second cutting step is performed. First, the rotation of the second spindle 10b is started, and the second cutting blade 10a is in a rotating state. Next, the second cutting unit 10 is vertically lowered toward the bonded wafer 1 while maintaining the rotation of the second cutting blade 10 a. Then, in order to completely cut the wafer 3, the second cutting blade 10a is cut through the wafer 3 and the adhesive member 7 until a predetermined depth of the support wafer 5 is reached.

  3A shows the bonded wafer 1 and the second cutting unit 10 in a state where the second cutting blade 10a is cut to a predetermined depth through the wafer 3 and the adhesive member 7 from above the bonded wafer 1. FIG. FIG. 3 is a diagram schematically showing a cross-sectional structure of the holding table 2.

  Next, the rotation of the holding table 2 is started while maintaining the rotation of the second cutting blade 10a. Then, the remaining portion 9a of the annular region 9 is continuously cut while the bonded wafer 1 rotates. Even if the holding table 2 starts rotating before the rotating second cutting unit 10 is lowered, the rotating second cutting unit 10 is lowered and then the remaining portion 9a of the annular region 9 is cut. Good.

  FIG. 4A schematically shows a cross-sectional structure of the bonded wafer 1 after the second cutting step is performed. Although the annular region 9 is entirely cut, the wafer 3 is prevented from being damaged because it is cut through the first cutting step and the second cutting step.

  In the second cutting step in the processing method according to the present embodiment, the second cutting blade 10a is positioned above the bonded wafer 1, and the second cutting blade 10a is reached from above to reach a predetermined depth of the support wafer 5. Not limited to descending.

  For example, the second cutting blade 10 a may be lowered in advance to a position where it can be cut to the predetermined depth at a position away from the bonded wafer 1, and then horizontally moved toward the bonded wafer 1. The second cutting blade 10a is rotated while horizontally cutting a part of the first cutting groove 11, and then the holding table 2 is rotated while maintaining the rotation of the second cutting blade 10a. The remaining portion 9a may be cut.

  By the way, the wafer 3 is chamfered at the outer edge portion, and the cross section has an arc shape before the second cutting step is performed. Therefore, before the second cutting step is performed, the adhesive member 7 between the wafer 3 and the support wafer 5 is formed thick in the vicinity of the outer peripheral edge of the bonded wafer 1 as shown in FIG. Yes. Therefore, when the vicinity of the outer peripheral edge of the bonded wafer 1 is cut, a large amount of cutting waste is generated.

  Although the 1st cutting blade 8a has an abrasive grain with a small particle diameter, the cutting blade which has such an abrasive grain tends to be clogged with cutting waste. In order to suppress damage such as cracks given to the wafer 3, it is conceivable to cut the entire annular region 9 with the first cutting blade 8a. In that case, even in the region where the adhesive member 7 is formed thick. Cutting is performed using the first cutting blade 8a. Then, clogging is particularly likely to occur due to the large amount of generated cutting waste, and the wafer 3 is susceptible to damage such as cracks.

  In the processing method according to the present embodiment, the place where the adhesive member 7 is formed thick is cut using the second cutting blade 10a having a large grain size, so that even if a large amount of cutting waste is generated. Less likely to clog. Therefore, the processing method according to the present embodiment can suppress clogging of the blade due to the cutting waste generated from the adhesive member, and can prevent damage to the wafer.

  After the second cutting step is performed, for example, a thinning step for thinning the wafer is performed. The thinning of the wafer will be described with reference to FIG. The bonded wafer 1 sucked and held on the holding table 2 is ground from the back surface 3b side, and the wafer 3 is thinned. FIG. 4B is a cross-sectional view schematically showing the wafer thinning step. The grinding wheel 12 supports the plurality of grinding wheels 14 downward, and the grinding wheel 14 gradually descends while rotating, whereby the grinding wheel 14 grinds the surface of the workpiece.

  As shown in FIG. 4B, in the thinning step, first, while rotating at least one of the holding table 2 and the grinding wheel 12, the grinding 12 is lowered and the grinding wheel is moved to the back surface 3b side of the wafer 3. Twelve grinding wheels 14 are brought into contact. In this state, the grinding wheel 12 is gradually lowered further, whereby the back surface 3b side is ground and the wafer 3 is processed thinly.

  The annular region 9 near the outer edge of the wafer 3 is cut by the first cutting step and the second cutting step, and the chamfered portion is removed. Therefore, the outer edge portion of the wafer 3 when the wafer 3 is thinned is no longer sharply sharpened like a knife edge, and the wafer 3 is not damaged due to chipping from the outer periphery of the wafer 3.

  In addition, this invention is not limited to description of the said embodiment, A various change can be implemented. For example, in the above embodiment, the first cutting groove is formed using the first cutting blade, but the method of forming the first cutting groove is not limited to this. For example, the first cutting groove may be formed by ablation processing using a laser processing apparatus.

  In addition, the structure, method, and the like according to the above-described embodiment can be appropriately modified and implemented without departing from the scope of the object of the present invention.

DESCRIPTION OF SYMBOLS 1 Bonded wafer 3 Wafer 3a Front surface 3b Back surface 3c Device 5 Support wafer 5a 1st surface 5b 2nd surface 7 Adhesive member 9 Annular area 9a The remaining part of the annular area 9b The part where the 2nd cutting blade descends 11 1st Cutting groove 2 Holding table 4 Disk-like member 6 Porous member 8 First cutting unit 8a First cutting blade 8b First spindle 10 Second cutting unit 10a Second cutting blade 10b Second spindle 12 Grinding wheel 14 Grinding wheel

Claims (1)

A cutting blade is cut to the support wafer on the bonded wafer in which the wafer is bonded onto the support wafer via an adhesive member, and the wafer is cut along the outer peripheral edge of the wafer to obtain a predetermined width from the outer peripheral edge of the wafer. A cutting method for removing an annular region having
A holding step of holding the support wafer side of the bonded wafer by a holding table;
After performing the holding step, a first cutting blade having a thickness smaller than the predetermined width of the annular region is cut along the inner peripheral edge of the annular region into the bonded wafer to the support wafer, and the first The first cutting blade and the holding table are moved relative to each other, and the wafer is cut along the inner peripheral edge by the first cutting blade, thereby removing a part of the annular region and forming a first cutting groove. 1 cutting step,
After performing the first cutting step, a second cutting blade thicker than the first cutting blade is overlapped with a part of the first cutting groove in the annular region on the outer peripheral side of the first cutting groove, and bonded to the wafer. To the support wafer, the second cutting blade and the holding table are moved relative to each other, and the wafer is cut with the second cutting blade to remove the remaining portion of the annular region. Steps,
A cutting method comprising: