JP2017220602A - Wafer processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wafer processing method by which, while a determination is reliably made by probing whether the device chip is satisfactory or not, the device chip is efficiently produced.SOLUTION: A wafer processing method by which a wafer 10 on which a device 12 with a plurality of electrodes 121 is formed is processed into a device chip on which the device is supported by a substrate, comprises: a separation groove formation step in which a separation groove 16 is formed along a dividing schedule line so as to have a depth corresponding to the thickness of the device chip but not reaching the rear face of the wafer, and the form of the wafer is maintained; a quality inspection step for inspecting whether the quality of each device is satisfactory or not by probing conducted to the electrodes of each device of the wafer in which the separation grooves is formed; and a rear face grinding step in which a protective member is disposed on the surface of the wafer, the rear face of the wafer is ground, the separation groove is exposed from the rear face, and the wafer is divided into individual device chips.SELECTED DRAWING: Figure 2

Description

  The present invention processes a wafer in which a functional layer is laminated on a surface of a substrate and a device having a plurality of electrodes is formed in a plurality of regions defined by division lines into a device chip in which the device is supported by the substrate. The present invention relates to a wafer processing method.

  A wafer in which a functional layer is laminated on the surface of a substrate and a device having a plurality of electrodes is formed in a plurality of regions divided by a predetermined division line irradiates a dicing apparatus having a cutting blade or a laser beam. A device is divided into device chips supported by a substrate by a laser processing apparatus, and is used for electric devices such as a mobile phone and a personal computer.

  On the substrate surface of the wafer, an interlayer insulating film (IDL), which is an insulator that fills between the wirings of the functional layers constituting the device, is formed, and the impact when the wafer is cut by a cutting blade damages the wafer. In some cases, an interlayer insulating film is peeled off or damage is caused, and a device disposed adjacent to a division planned line becomes defective.

  In addition, when the above-described functional layer is composed of a low dielectric constant insulator (Low-k film), the above phenomenon becomes more prominent. Therefore, the condensing points of the laser beam are positioned on both sides of the division line. After irradiation and fusing the functional layer to form two shallow grooves along the line to be divided, the cutting blade is positioned at the center of the two shallow grooves to divide the wafer into individual device chips. A technique (see, for example, Patent Document 1) has also been proposed, but a device chip failure cannot be completely eliminated.

  A prober is known as means for detecting a failure of a device formed on a wafer. The prober includes a plurality of probe needles that are in contact with device electrodes formed on a wafer, and a tester that is electrically connected to the probe needles. An electric signal sent from the tester is transmitted to the device via the probe needles. Probing is possible that detects whether the device is good or bad based on an electrical signal returned from the device (see, for example, Patent Document 2).

Japanese Patent Laying-Open No. 2005-064230 JP 2003-059987 A

  Conventionally, after a device is formed on a wafer, probing is performed in order to detect a defective device before performing a process for dividing the device into individual device chips. However, as described above, since defects may occur in the process of separating the wafer into device chips, in order to more reliably determine a device chip defect, after dividing the wafer into individual device chips, Although it is necessary to perform probing in which current is applied to the electrodes of individual device chips by a prober, there is a problem that it takes time and productivity is very poor as compared with the case of probing in units of wafers.

  The present invention has been made in view of the above-mentioned facts, and its main technical problem is to provide a wafer processing method for efficiently producing device chips while reliably determining whether the device chips are good or defective by probing. It is in.

  In order to solve the above-mentioned main technical problem, according to the present invention, there is provided a device in which a functional layer is laminated on a surface of a substrate and a device having a plurality of electrodes is formed in a plurality of regions partitioned by a division line. Is a method of processing a wafer to be processed into a device chip supported by a substrate, and forming a separation groove along a planned division line at a depth corresponding to at least the thickness of the device chip and not reaching the back surface of the wafer A separation groove forming step for maintaining the shape of the wafer, a quality inspection step for inspecting the quality of the device by probing energizing the electrodes of each device of the wafer on which the separation groove is formed, A protective member is provided on the front surface of the wafer, the back surface of the wafer is ground, and the separation grooves are exposed on the back surface to divide the wafer into individual device chips. And the back grinding step, the processing method at least consists wafer is provided from the.

  According to the separation groove forming step, the cutting blade is positioned on the planned division line, and a separation groove that does not reach the back surface of the wafer at a depth corresponding to at least the thickness of the device chip can be formed along the planned division line. . Alternatively, the condensing point of the laser beam is positioned and irradiated on the planned division line, and a separation groove having a depth corresponding to at least the thickness of the device chip can be formed along the planned division line. Furthermore, the laser beam condensing points are positioned on both sides of the division line, the functional layer is cut, and two shallow grooves shallower than the depth corresponding to the thickness of the device chip are formed along the division line. And a separation groove forming step in which the cutting blade is positioned at the center of the two shallow grooves and a separation groove having a depth corresponding to at least the thickness of the device chip is formed along the planned division line. It can also be.

  In the wafer processing method according to the present invention, a separation groove forming step for forming a separation groove along a planned division line at a depth corresponding to the thickness of the device chip and not reaching the back surface of the wafer, and maintaining the shape of the wafer. A quality inspection process for inspecting the quality of the device by probing energizing the electrodes of each device of the wafer in which the separation grooves are formed, and a protective member is disposed on the surface of the wafer, There is a risk of causing peeling or damage to the functional layer of the device chip by comprising at least a back grinding process in which the back surface is ground and the separation grooves are exposed on the back surface to divide the wafer into individual device chips. After performing a certain separation groove forming process, probing is performed in a state where the wafer shape is maintained, and then a back surface grinding process is performed to perform individual degaussing. It was to obtain the Isuchippu. This makes it possible to efficiently perform probing in a state where the wafer form is maintained after performing the separation groove forming process that may damage the functional layer of the device chip. It is possible to efficiently produce chips while reliably discriminating chips.

It is explanatory drawing for demonstrating the separation groove formation process in 1st embodiment implemented based on this invention. It is explanatory drawing for demonstrating the probing of the quality inspection process implemented based on this invention. It is explanatory drawing for demonstrating the process of sticking a protective tape on the wafer of the back surface grinding process implemented based on this invention. It is explanatory drawing for demonstrating the back surface grinding process implemented based on this invention. It is explanatory drawing for demonstrating the transfer process implemented in the processing method of the wafer based on this invention. It is explanatory drawing for demonstrating the isolation | separation groove | channel formation process in 2nd embodiment implemented based on this invention. It is explanatory drawing for demonstrating the isolation | separation groove | channel formation process in 3rd embodiment implemented based on this invention.

  Hereinafter, a first embodiment of a wafer processing method according to the present invention will be described in detail with reference to FIGS. FIG. 1A shows a dicing apparatus 20 (entire view is omitted) for executing a separation groove forming step in a wafer processing method constructed according to the present invention. The dicing apparatus 20 includes a cutting blade 22 that is rotated at a high speed by a rotating spindle (not shown). An operator prepares a wafer 10 having a thickness of 770 μm, for example, in which the device 12 is formed in each of a plurality of regions partitioned by the scheduled division line 14. Next, the wafer 10 is placed on the holding means 24 of the dicing apparatus 20 with the surface 10a facing upward, and suction means (not shown) is operated to hold the suction. As shown in FIG. 1B, the functional layer 11 constituting the device 12 is formed on the surface 10 a side of the wafer 10, and a plurality of electrodes are disposed on the surface of the device 12.

  When the operator performs alignment for aligning the position of the cutting blade 22 of the dicing apparatus 20 and the planned dividing line 14 of the wafer 10, the cutting blade 22 is positioned at one end of the planned dividing line 14 and rotated. The spindle is driven to rotate the cutting blade 22, and the holding means 24 is relatively moved in the direction indicated by the arrow X to cut along the scheduled division line 14. Thereby, as shown in a partially enlarged cross-sectional view in FIG. 1B, at least the finished thickness of each device 12 (this embodiment) along the scheduled division line 14 of the wafer 10 placed on the holding means 24 (this embodiment). In the embodiment, a cutting groove 16a corresponding to 100 μm) and serving as a separation groove 16 that does not reach the back surface 10b of the wafer is formed. When the cutting blade 22 reaches the other end portion of the scheduled division line 14, the holding means 24 is appropriately moved and rotated so that the cutting position is adjusted to the unprocessed scheduled division line 14 position, and all the divisions are performed. A similar cutting process is performed on the planned line 14 to form the separation groove 16. As a result, the separation groove forming step is completed while maintaining the wafer shape. In the present invention, the “state in which the wafer shape is maintained” does not simply mean that the wafer shape is maintained, but in the separation groove forming step, the separation groove is divided into the lines 14 to be divided. Is formed so that the separation groove does not reach the back surface of the wafer. This is because if the separation groove is formed so as to reach the back surface of the wafer, the position of each device chip will be slightly shifted even if the wafer shape is apparently maintained, and this will be performed in the quality inspection process described later. This is because it becomes difficult to align the probe needle terminals with the device electrodes when performing bing. Therefore, in the present invention, when the separation groove is formed along the planned dividing line 14 and the separation groove reaches the back surface of the wafer, it is excluded from the “state in which the wafer shape is maintained”. Shall. The depth of the separation groove 16 is set based on the finished thickness of the device 12, but it is not necessarily set to the finished thickness. The separation groove depth is set to a value larger than the finished thickness. May be.

  When the separation groove forming step is carried out, the holding means 24 is moved to the inspection position of the prober 30 (the whole drawing is omitted) as shown in FIG. 2 through the steps of cleaning and drying the wafer (not shown). Perform probing. The prober 30 has a probe 32 having a plurality of needle-like terminals 34 for contacting the plurality of electrodes 121 of the device 12 at the tip, and the needle-like terminals 34 are arranged in the probe 32. It is connected to a tester (not shown) by a cable. FIG. 2 shows a state in which the device 12 is inspected with two needle-shaped terminals 34 with respect to eight electrodes, but the present invention is not particularly limited to this. By providing eight, the needle-like terminal may be brought into contact with all the electrodes of the device 12 at a time, and the quality inspection may be performed.

  The holding unit 24 is provided with a drive mechanism for moving to any position in the X, Y, and Z directions, and is controlled by a control unit disposed in the prober 30. At the inspection position, the holding means 24 is moved, the device 12 to be inspected is set, the position of the holding means 24 is controlled, and the electrode 121 of the device 12 is brought into contact with the needle-like terminal 34 of the probe 32. If the electrode 121 is brought into contact with the needle-shaped terminal 34 of the probe 32, an electrical signal for inspection is sent from the tester through the needle-shaped terminal 34 for transmission of the probe 32, and the electrical signal passing through the circuit in the device 12 is Then, it is sent to the tester via the receiving needle terminal 34. Here, if the device 12 is normal (good), the tester receives a specified electrical signal indicating that it is normal, but if the device 12 has an abnormality such as damage, the tester receives the specified electrical signal. It cannot be determined that the product is defective. By performing such an inspection on all the devices 12 on the wafer 10, the quality of each device 12 is determined. If a defect is detected by the quality inspection, the coordinate position of the defective device 12 on the wafer 10 is stored and stored in the control means of the prober 30. In this way, the quality inspection process is completed. In this embodiment, the holding means 24 that holds the wafer 10 when the separation groove forming step is performed is moved to the inspection position and the probing is executed. However, the present invention is not limited to this. The wafer 10 may be transferred from the holding unit 24 to a separately prepared holding unit for quality inspection, and the quality inspection process may be performed.

  When the quality inspection process is completed, a back grinding process is performed. In order to carry out the back surface grinding step, first, as shown in FIG. 3A, a protective tape that functions as a protective member on the surface 10a side of the wafer 10 on which the separation groove 16 is formed by the separation groove forming step. T1 is stuck and the back surface 10b side is set upward as shown in FIG. 3 (b). As shown in FIG. 4A, the grinding apparatus 40 used in the back grinding process relatively rotates the holding means 42 that holds the wafer 10 and the grinding wheel 46 of the grinding unit 44, and also the grinding wheel 46. The back surface 10b of the wafer 10 placed on the holding means 42 and sucked and held can be ground by abutting the grinding wheel 48 disposed on the surface. In the grinding apparatus 40 of this embodiment, the grinding wheel 46 is rotated at 6000 rpm and the holding means 42 is rotated at 300 rpm, and the grinding wheel 46 is moved toward the holding means 42, that is, at a speed of 1.0 μm / second toward the vertically lower side. Feed to grinding.

  When starting the back surface grinding process, the separation grooves 16 of the wafer 10 do not reach the back surface 10b side, and thus are not separated into individual devices 12. Here, by proceeding the back surface grinding under the above-described processing conditions, as shown in FIG. 4B, the wafer 10 is thinned and the separation groove 16 is exposed on the back surface 10b side. At this time, the device 12 of the wafer 10 is divided into individual device chips and ground to a predetermined thickness (100 μm), and then the back grinding process is completed.

  When the back grinding process is completed, as shown in FIG. 5, a transfer process is performed in which the chip F is held on the frame F via the adhesive tape T2 in order to pick up the individually divided device chips. More specifically, a pressure-sensitive adhesive tape T2 that is held by suction on the holding means 42 of the grinding apparatus 40 and that has the separation groove 16 exposed is attached to the back surface 10b side of the wafer 10, and the adhesive tape T2 The outer periphery is adhered to the frame F and held and integrated. When the wafer 10 is integrated with the frame F, the protective tape T1 is peeled off and transferred to a pickup device (not shown) that performs a pickup process. In the pickup device, the adhesive tape T2 is expanded to increase the interval between the individually divided device chips, and the device chips are sucked by the pickup collet and stored in the storage case. At this time, the coordinate position information of the device chip determined to be defective is transmitted and stored from the control unit of the prober 30 to the control unit of the pickup apparatus that performs the pickup process, and the defective device chip is a normal device. It is picked up separately from the chip and stored in a waste container that is not transported to the next process.

  As described above, the wafer processing method of the present invention is completed. When the present invention is configured as described above, the following effects can be obtained.

  A separation groove is formed along the planned dividing line 14 at a depth corresponding to the thickness of the device chip and does not reach the back surface of the wafer with respect to the wafer, and each of the devices of the wafer on which the separation groove is formed. A quality inspection process is performed to inspect the quality of the device by the probing that energizes the electrodes. This quality inspection process is performed after the separation groove forming process, which may damage the device, and before being divided into individual device chips, that is, while maintaining the wafer configuration. The Therefore, the quality inspection can be executed for all device chips in a shorter time than when the device chips are divided individually. In addition, the specific embodiment in the transfer process and the pickup process described above is not an essential requirement for solving the problem to be solved by the present invention, and the back grinding process for dividing the wafer into individual device chips is completed. After that, the worker may accommodate each device chip by a method appropriately selected.

  In the first embodiment described above, the separation groove forming step is performed using the cutting device 20 shown in FIG. 1 and the separation groove 16 is formed by the cutting blade 22, but the present invention is not limited to this. . A second embodiment in which the separation groove forming step is performed by another method will be described with reference to FIG. In the following description, only differences from the first embodiment will be described, and description of the same steps will be omitted.

FIG. 6A shows a laser processing apparatus 50 for forming the separation groove (the whole view is omitted). Similar to the first embodiment, if a wafer 10 is prepared in which a functional layer is laminated on the surface of a substrate and a device having a plurality of electrodes is formed in a plurality of regions defined by the division lines 14, a laser is prepared. The wafer 10 is placed on the holding means 54 of the processing apparatus 50 with the surface 10a side facing upward, and suction means (not shown) is operated and sucked and held. The holding means 54 is moved, and one end of the scheduled division line 14 of the wafer 10 fixed to the holding means 54 is aligned with the condenser 52 of the laser beam irradiation means of the laser processing apparatus 50, and the division is scheduled. The laser beam irradiation and the holding means 54 are moved relative to each other in the direction of the arrow X so as to form a laser processing groove 16b having a predetermined depth (100 μm in this embodiment) along the line 14. In addition, the processing conditions of this laser processing are set as follows, for example.
Wavelength: 355nm
Pulse width: 12 ps
Repetition frequency: 200 kHz
Output: 5W
Condensing spot diameter: φ10μm
Processing feed rate: 400 mm / sec

  The laser beam irradiated under the above-described processing conditions is set to a wavelength that absorbs the wafer 10, and the output is set so as to divide the functional layer. Then, a laser processing groove 16b having a predetermined depth is formed on the planned division line 14 by the laser beam LB as shown in a partially enlarged sectional view in FIG. Then, by irradiating the laser beam while moving the holding means 54 in the indexing feed direction and the rotation direction, the same laser processing is performed on all the division lines 14 and the separation grooves 16 are formed by the laser processing grooves 16b. Form. Note that the laser processing conditions in the present embodiment are not limited to the above processing conditions. For example, the output is set low so as not to cause damage to the device chip, and divided into several scheduled lines 14. On the other hand, the laser processing groove 16b may be formed, and the separation groove 16 having a predetermined depth may be formed.

  If the separation groove forming process is completed by forming the separation grooves 16 for all the division lines 14, the quality inspection process, the back surface grinding process, and the pickup process performed in the first embodiment are performed thereafter. In practice, the individual device chips can be divided from the wafer 10. Also according to the second embodiment, it is possible to obtain the same effects as those of the first embodiment.

  Further, a third embodiment having a different configuration for performing the separation groove forming step from the first and second embodiments will be described with reference to FIG. In the following description, like the description of the second embodiment, only differences from the first embodiment will be described, and the description of the same steps will be omitted.

As in the first embodiment, when the unprocessed wafer 10 is prepared, it is placed on the holding means 64 of the laser processing apparatus 60 with the surface 10a side up as shown in FIG. Then, the suction means (not shown) is operated to hold the suction. The laser beam LB1 and LB2 are irradiated from the condenser 62 of the laser beam irradiation means disposed in the laser processing apparatus 60, and the movement control of the holding means 64 is performed to form the wafer 10 on the surface 10a side. A shallow groove forming step for forming a shallow groove 16c that is a depth that divides the functional layer 11 and is shallower than the depth corresponding to the thickness of the device chip is performed. By the shallow groove forming step, two shallow grooves 16c for cutting the functional layer 11 are formed on both sides in all the division lines 14 as shown in a partially enlarged sectional view in FIG. Is done. In addition, the processing conditions in this laser processing are set as follows, for example.
Wavelength: 355nm
Pulse width: 12 ps
Repetition frequency: 200 kHz
Output: 2W
Condensing spot diameter: φ10μm
Processing feed rate: 400 mm / sec

  When the shallow groove 16c is formed by the above-described shallow groove forming step, the shallow groove 16c is transferred to the cutting device 20 shown in FIG. 7C, placed on the holding means 24, and sucked and held. The cutting groove 16d provided in the cutting device 20 with respect to the planned dividing line 14 of the wafer 10 held by the holding means 24 is used to cut the cutting groove 16d having a depth corresponding to the thickness of the device chip along the planned dividing line 14. A separation groove forming step is performed in which the separation groove 16 having a predetermined depth is formed. As shown in FIG. 7D, the blade width of the cutting blade 22 is set to be smaller than the distance between the shallow grooves 16 c and 16 c, and the shallow grooves 16 c and 16 c exist between the cutting blade and the device 12. As a result, propagation of destructive force by the cutting blade is cut off, so that even if the functional layer 11 is composed of a low dielectric constant insulator (Low-k film), the functional layer is peeled off from the substrate. It is possible to avoid problems such as As described above, the shallow groove forming step and the separation groove forming step are executed, and the separation groove forming process is completed.

  According to the third embodiment described above, it is possible to obtain the same effect as the first embodiment described above, avoiding the impact when the wafer is cut by the cutting blade from reaching the device chip, It is possible to more effectively prevent the device disposed adjacent to the planned dividing line from becoming defective by peeling off the interlayer insulating film or causing damage.

DESCRIPTION OF SYMBOLS 10: Wafer 12: Device 14: Planned division line 16: Separation groove 20: Cutting device 22: Cutting blade 30: Prober 32: Probe 34: Needle terminal 40: Grinding device 50, 60: Laser processing device

Claims (4)

A wafer processing method for processing a wafer in which a functional layer is stacked on a surface of a substrate and a device having a plurality of electrodes is formed in a plurality of regions defined by division lines into a device chip in which the device is supported by the substrate Because
A separation groove forming step of forming a separation groove at a depth corresponding to at least the thickness of the device chip and not reaching the back surface of the wafer along the planned dividing line, and maintaining the shape of the wafer;
A quality inspection step for inspecting the quality of the device by probing energizing the electrodes of each device of the wafer in which the separation grooves are formed; and
A back surface grinding step in which a protective member is disposed on the front surface of the wafer, the back surface of the wafer is ground and the separation grooves are exposed on the back surface to divide the wafer into individual device chips;
A method for processing a wafer comprising at least   2. The separation groove forming step according to claim 1, wherein in the separation groove forming step, a separation groove that does not reach the back surface of the wafer at a depth corresponding to the thickness of the device chip is formed along the division line. Wafer processing method.   2. The wafer according to claim 1, wherein the separation groove forming step forms a separation groove having a depth corresponding to the thickness of the device chip along the planned division line by irradiating the laser beam condensing point on the predetermined division line. Processing method.   In the separation groove forming step, the condensing points of the laser beam are positioned on both sides of the division line, the functional layer is cut, and two shallow grooves shallower than the depth corresponding to the thickness of the device chip are formed along the division line. A shallow groove forming step to be formed, and a separation groove forming step in which a cutting blade is positioned at the center of the two shallow grooves and a separation groove having a depth corresponding to the thickness of the device chip is formed along the division line. The method for processing a wafer according to claim 1.