Patent Grant
11712747
The present invention relates to a wafer processing method for processing a wafer formed on a front surface thereof with a plurality of devices having projection-shaped electrodes, the devices being partitioned by streets.
A wafer formed on a front surface thereof with a plurality of devices such as integrated circuits (ICs) and large-scale integrated circuits (LSIs), the devices being partitioned by streets, has a back surface thereof ground by a grinding apparatus to a predetermined thickness, and is thereafter divided into individual device chips, which are used for electric apparatuses such as mobile phones and personal computers.
In addition, a wafer formed on a front surface thereof with a plurality of devices having projection-shaped electrodes is conveyed to a cutting apparatus, for making uniform head portions (top portions) of the electrodes in height and for removing an oxide film and/or contaminants on surfaces thereof, a back surface of the wafer is held on a holding surface of a chuck table, and the head portions of the projection-shaped electrodes (bumps) are cut by a cutting tool slewed in parallel to the holding surface (see, for example, Japanese Patent Laid-open No. 2000-319697).
The wafer conveyed to the cutting apparatus, where the head portions of the projection-shaped electrodes are cut to be made uniform in height and metallic surfaces of the electrodes are exposed, is in a state suitable for bonding, but the wafer is not necessarily divided into individual device chips and subjected to a bonding step immediately after the head portions of the electrodes are cut. As time elapses, an oxide film may be formed on the metallic surfaces of the electrodes, and contaminants may be adhered to the electrodes in some storage conditions, which may hamper the bonding in a subsequent step.
It is accordingly an object of the present invention to provide a wafer processing method which ensures that even when time elapses after head portions of projection-shaped electrodes are cut, bonding performed thereafter is not hampered.
In accordance with an aspect of the present invention, there is provided a wafer processing method for processing a wafer formed on a front surface thereof with a plurality of devices having projection-shaped electrodes, the devices being partitioned by streets, the wafer processing method including a cutting step of holding a back surface of the wafer by a holding surface of a chuck table and cutting head portions of the projection-shaped electrodes by a cutting tool slewed in parallel to the holding surface, to make uniform the electrodes in height and to expose metallic surfaces of the electrodes, a thermocompression bonding sheet laying step of laying a thermocompression bonding sheet on the front surface of the wafer, a thermocompression bonding step of heating and pressing the thermocompression bonding sheet to perform thermocompression bonding, and a peeling step of peeling off the thermocompression bonding sheet before dividing the wafer into individual device chips and bonding the electrodes to a circuit board.
In the described aspect of the present invention, the wafer processing method preferably includes a plating step of forming a plating layer on the metallic surfaces formed at the head portions of the electrodes, after the cutting step but before performing the thermocompression bonding step.
In addition, in the described aspect of the present invention, the thermocompression bonding sheet is preferably a polyolefin-based sheet or a polyester-based sheet. The thermocompression bonding sheet is preferably one of a polyethylene sheet, a polypropylene sheet, a polystyrene sheet, a polyethylene terephthalate sheet, and a polyethylene naphthalate sheet. Further, the heating temperature at the time of heating the thermocompression bonding sheet in the thermocompression bonding step is preferably 120° C. to 140° C. in the case where the polyethylene sheet is selected as the thermocompression bonding sheet, preferably 160° C. to 180° C. in the case where the polypropylene sheet is selected, preferably 220° C. to 240° C. in the case where the polystyrene sheet is selected, preferably 250° C. to 270° C. in the case where the polyethylene terephthalate sheet is selected, and preferably 160° C. to 180° C. in the case where the polyethylene naphthalate is selected.
According to the wafer processing method according to the described aspect of the present invention, during the period after the head portions of the electrodes are cut and until the wafer is divided into individual device chips and bonded, the electrodes are shielded from the outside air, so that oxidation and/or contamination of the metallic surfaces of the electrodes is avoided, and bonding is less likely to be hampered.
The above and other objects, features and advantages of the present invention and the manner of realizing them will become more apparent, and the invention itself will best be understood from a study of the following description and appended claims with reference to the attached drawings showing a preferred embodiment of the invention.
An embodiment of a wafer processing method of the present invention will be described in detail below, referring to the attached drawings.
The cutting unit 3 includes a moving base 31 and a spindle unit 32 mounted to the moving base 31. The moving base 31 is formed with guided grooves for slidable engagement with the pair of guide rails 312. A support member 313 is mounted to a front surface of the moving base 31 slidably mounted to the pair of guide rails 312 provided on the upright wall 22, and the spindle unit 32 is attached to the support member 313.
The spindle unit 32 includes a spindle housing 321 mounted to the support member 313; a rotating spindle 322 disposed rotatably in the spindle housing 321; and a servo motor 323 as a drive source for rotationally driving a rotating spindle 322. A lower end portion of the rotating spindle 322 projects downward beyond a lower end of the spindle housing 321 and is provided at its lower end portion with a disk-shaped cutting tool member mounting member 324.
The cutting tool member mounting member 324 is provided with a cutting tool mounting hole 324a penetrating a part of an outer peripheral portion spaced from a rotational axis in the vertical direction. A cutting tool 331 constituting a cutting tool member 33 is inserted in the cutting tool mounting hole 324a, and a fastening bolt 330 is brought into screw engagement through a female screw hole formed at a lateral side of the cutting tool member mounting member 324 and is fastened, thereby fixing the cutting tool 331. Note that the cutting tool 331 is formed in a rod shape from a tool steel such as sintered hard alloy, and a cutting blade formed from diamond or the like is provided at a lower tip portion of the cutting tool 331, in the depicted embodiment. With the rotating spindle 332 rotated, the cutting tool member 33 mounted to the cutting tool member mounting member 324 configured as described above is rotated in the direction indicated by an arrow R1 together with the cutting tool member mounting member 324.
The cutting apparatus 1 illustrated includes a cutting-in feeding mechanism 4 for moving the cutting unit 3 in the vertical direction (the direction indicated by an arrow Z) along the pair of guide rails 312. The cutting-in feeding mechanism 4 includes a male screw rod 41 disposed on the front side of the upright wall 22 and extending substantially vertically. The male screw rod 41 is rotatably supported by a bearing member of which an upper end portion and a lower end portion are attached to the upright wall 22. A pulse motor 44 as a drive source for rotationally driving the male screw rod 41 fixed to the upright wall 22 is disposed at an upper end portion of the male screw rod 41, and an output shaft of the pulse motor 44 is connected to the male screw rod 41. A rear surface of the moving base 31 is formed with a connection section (not illustrated) projecting rearward from a width directionally central portion of the rear surface, and the male screw rod 41 is put in screw engagement with a female screw hole formed in the connection section. Therefore, when the pulse motor 44 is rotated normally, the cutting unit 3 is lowered together with the moving base 31, and when the pulse motor 44 is rotated reversely, the cutting unit 3 is raised together with the moving base 31.
A chuck table mechanism 5 is disposed on an upper surface of the main section 21 of the apparatus housing 2. The chuck table mechanism 5 includes a disk-shaped chuck table 52 disposed rotatably. At an upper surface of the chuck table 52, a holding surface is configured by a gas-permeable suction chuck 52a, which is connected to an unillustrated suction source, and by operating the suction source, a negative pressure is caused to act on the holding surface. The chuck table mechanism 5 includes an unillustrated moving mechanism accommodated in the inside of the main section 21, the chuck table 52 can be moved together with a cover member 54 in the direction indicated by an arrow X1, and the chuck table 52 can be reciprocated between a workpiece conveying-in/out region where the chuck table 52 is located in
The cutting apparatus 1 depicted in
A workpiece in the present embodiment is, for example, a wafer 10 including a semiconductor formed on a front surface 10a thereof with a plurality of devices 12, which are partitioned by streets 14, as illustrated in
In
After the wafer 10 is held under suction on the chuck table 52, the servo motor 323 of the spindle unit 32 described based on
After the cutting step is conducted as above, a thermocompression bonding sheet laying step is carried out next. Referring to
At the time of performing the thermocompression bonding sheet laying step, the wafer 10 subjected to cutting by the cutting step is conveyed to a thermocompression bonding apparatus 70 (only a part is depicted) depicted in
The thermocompression bonding sheet 60 is suitably a polyolefin-based sheet or a polyester based sheet. In the case of adopting the polyolefin-based sheet, the sheet is preferably selected from a polyethylene (PE) sheet, a polypropylene (PP) sheet, and a polystyrene (PS) sheet, and in the case of adopting the polyester-based sheet, the sheet is preferably selected from either a polyethylene terephthalate (PET) sheet or a polyethylene naphthalate (PEN) sheet. Note that, in the present embodiment, the following description will be made on the assumption that a polyethylene sheet is selected as the thermocompression bonding sheet 60. Note that a glue layer is not formed on that adhesion surface of the thermocompression bonding sheet 60 which faces the wafer 10. By such an operation, the thermocompression bonding sheet laying step is completed.
After the thermocompression bonding sheet laying step is conducted as above, a thermocompression bonding step is carried out next. Referring to
After the thermocompression bonding sheet 60 is laid on the suction table 72 as mentioned above, the unillustrated suction source is operated to cause a negative pressure Vm to act on the suction table 72, whereby the wafer 10 placed on the suction chuck 74 and the thermocompression bonding sheet 60 are sucked. Next, as illustrated in
After the thermocompression bonding means 80 is located on the thermocompression bonding sheet 60, the thermocompression bonding sheet 60 is pressed while being heated by the heating roller 84, and, while the heating roller 84 is rotated in the direction indicated by the arrow R2, as illustrated in
In the present embodiment, the thermocompression bonding sheet 60 undergoes thermocompression bonding to the wafer 10, whereby direct contact of the metallic surfaces 122 of the projection-shaped electrodes 120 formed on the devices 12 with the outside air is avoided, and formation of an oxide film on the metallic surfaces 122 of the electrodes 120 is restrained until the thermocompression bonding sheet 60 is peeled off. In addition, with the thermocompression bonding sheet 60 having undergone thermocompression bonding, direct adhesion of contaminants to the metallic surfaces 122 of the electrodes 120 of the devices 12 is also prevented.
Note that the present invention is not limited to the above-described embodiment; for example, at any timing after the cutting step but before the thermocompression bonding step is performed, a plating step (for example, electroplating or the like) may be applied to the metallic surfaces 122 of the electrode 120 subjected to cutting, to form plating layers 18, as illustrated in
After the above thermocompression bonding step is conducted, preferably, an outer periphery removing step is performed in which an outer peripheral region 60a of the thermocompression bonding sheet 60 protruding from the wafer 10 is removed, as depicted in
For carrying out the outer periphery removing step, as illustrated in
After the thermocompression bonding step and the outer periphery removing step that is performed if necessary are carried out as mentioned above, a back grinding step may be performed such as to process the wafer 10 integrated with the thermocompression bonding sheet 60 to a desired thickness. To perform the back grinding step, the wafer 10 integrated with the thermocompression bonding sheet 60 is conveyed to a grinding apparatus 100, as depicted in
The wafer 10 conveyed to the grinding apparatus 100 (only a part is depicted) depicted in
After the wafer 10 is held under suction on the chuck table 110, as illustrated in
After the wafer 10 is integrated with the thermocompression bonding sheet 60 as described above, the devices 12 formed on the wafer 10 are divided into the individual device chips, which are each bonded onto a predetermined circuit board. Before bonding the electrodes 120 of the device 12 to the circuit board, a dividing step for dividing the wafer 10 into the individual device chips is thus conducted.
At the time of performing the dividing step, as depicted in
The cutting apparatus 140 includes a chuck table omitted from illustration and includes a spindle unit 142. The spindle unit 142 rotatably supports a rotating spindle 144, and a disk-shaped cutting blade 146 is mounted to a tip portion of the rotating spindle 144. An unillustrated driving motor is disposed at a rear end portion of the spindle unit 142, and the cutting blade 146 is rotationally driven at a desired rotating speed in the direction indicated by an arrow R8 together with the rotating spindle 144. The chuck table can be moved in an X-axis direction indicted by an arrow X by unillustrated moving means, and the spindle unit 142 can be moved in a Y-axis direction indicated by an arrow Y orthogonal to the X-axis direction and in the vertical direction orthogonal to both the X-axis direction and the Y-axis direction by unillustrated moving means.
The wafer 10 conveyed to the cutting apparatus 140 is placed and held on the chuck table together with the frame F, and a to-be-cut position (street 14) of the wafer 10 is detected by unillustrated alignment means (alignment). Based on position information obtained by carrying out the alignment, a tip portion of the cutting blade 146 is positioned at a predetermined processing starting position and is located at a depth for cutting the wafer 10. After the cutting blade 146 is positioned at the processing starting position, the chuck table holding the wafer 10 is moved in the X-axis direction along the street 14 of the wafer 10, to form a division groove 130 for dividing the wafer 10 into individual devices. Further, while indexing feeding of the spindle unit 142 is appropriately performed in the Y-axis direction, the division grooves 130 are formed along the remaining streets 14 parallel to the predetermined direction. After the division grooves 130 are formed along all the streets 14 along the predetermined direction, the chuck table is rotated by 90 degrees, and the division grooves 130 for cutting the wafer 10 are formed along all the streets 14 formed in the direction orthogonal to the predetermined direction. As a result, the plurality of devices 12 having been formed on the wafer 10 are individually divided from the wafer 10, to be device chips. The devices 12 made into the individual device chips are conveyed to a bonding step and are each appropriately bonded to a circuit board.
According to the present embodiment, until the wafer 10 is divided into the individual device chips and the device chips are bonded to the circuit boards, the thermocompression bonding sheet 60 is put in thermocompression bonding to the front surface 10a of the wafer 10, so that the metallic surfaces 122 of the electrodes 120 exposed on the devices 12 are shielded from outside air. Therefore, an oxide film is not formed on the metallic surfaces 122 of the electrodes 120 and the metallic surfaces 122 are not contaminated, preventing the bonding from being hampered. Further, since the thermocompression bonding sheet 60 is peeled off from the wafer 10 at the time of performing the bonding, it is ensured that burs, if any, remaining on the electrodes 120 on the devices 12 are removed together with the thermocompression bonding sheet 60.
Note that while the thermocompression bonding sheet 60 is peeled off from the front surface 10a of the wafer 10 at the time of performing the dividing step in the above-described embodiment, the device chips divided individually may not be immediately bonded to the circuit boards after the dividing step is conducted; in the case where there is some time until the bonding, the devices 12 may be divided into the individual device chips in the state in which the thermocompression bonding sheet 60 is adhered onto the wafer 10, and, thereafter, the thermocompression bonding sheet 60 may be peeled off from the device chips at the time of bonding the device chips to the circuit boards.
In addition, while a polyethylene sheet is used for the thermocompression bonding sheet 60 in the above embodiment, the present invention is not limited to this, and the thermocompression bonding sheet 60 may be appropriately selected from polyolefin-based sheets and polyester-based sheets.
In the case of selecting the thermocompression bonding sheet 60 from the polyolefin-based sheets, the sheet may not only be the polyethylene sheet selected in the above embodiment but also be one selected from either a polypropylene sheet or a polystyrene sheet.
In the case of selecting the polypropylene sheet as the thermocompression bonding sheet 60, the heating temperature at the time of performing the thermocompression bonding step is preferably 160° C. to 180° C. Besides, in the case of selecting the polystyrene sheet as the thermocompression bonding sheet 60, the heating temperature at the time of performing the thermocompression bonding step is preferably 220° C. to 240° C.
Further, in the case of selecting the thermocompression bonding sheet 60 from the polyester-based sheets, the sheet may be selected from either a polyethylene terephthalate sheet or a polyethylene naphthalate sheet.
In the case where the polyethylene terephthalate sheet is selected as the thermocompression bonding sheet 60, the heating temperature at the time of performing the thermocompression bonding step is preferably 250° C. to 270° C. Besides, in the case where the polyethylene naphthalate sheet is selected as the thermocompression bonding sheet 60, the heating temperature at the time of performing the thermocompression bonding step is preferably 160° C. to 180° C.
As described above, the thermocompression bonding sheet 60 can be appropriately selected from a polyethylene sheet, a polypropylene sheet, a polystyrene sheet, a polyethylene terephthalate sheet, and a polyethylene naphthalate sheet.
The present invention is not limited to the details of the above described preferred embodiment. The scope of the invention is defined by the appended claims and all changes and modifications as fall within the equivalence of the scope of the claims are therefore to be embraced by the invention.
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