JP2014222773A - Laser dicing device and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a laser dicing device and a method which allow processing without touching a front surface of a wafer.SOLUTION: A wafer W is mounted on a dicing frame F with a transparent dicing tape T adhered to a rear surface thereof. The wafer W mounted on the dicing frame F is held on a transparent wafer table 20 by being sucked at the rear surface thereof. Laser light passes through the transparent wafer table 20 and the transparent dicing tape T and is incident on the rear surface of the wafer W. The wafer W is thereby held without touching a front surface of the wafer W, and the laser light can be incident on the rear surface of the wafer W. Consequently, laser dicing can be carried out without destroying elements, and the like, formed on the front surface of the wafer W.

Description

  The present invention relates to a laser dicing apparatus and method.

  A dicing method (laser dicing) using a laser is known as a method of dividing a wafer having a circuit pattern or the like formed on the surface into individual chips. Laser dicing is a method in which a laser beam is incident on a wafer along a street (division planned line) to form a modified layer by multiphoton absorption inside the wafer. The laser-diced wafer is then divided into individual chips starting from the modified layer by applying external stress to the wafer. This laser dicing has the advantage that it can be divided with little chipping.

  In laser dicing, a laser beam is generally incident from the front surface side (surface side on which a circuit pattern or the like is formed) of a wafer to form a modified layer inside the wafer.

  However, the method in which the laser beam is incident from the front side has a problem that in the case of a wafer in which a metal film is formed near the street, the laser beam is reflected by the metal film and cannot be used.

  In order to solve such a problem, Patent Document 1 proposes that a modified layer is formed inside a wafer by making a laser beam incident from the back surface of the wafer through a dicing tape. Further, Patent Document 2 proposes that a wafer is sandwiched and supported by a pair of transparent glass plates so that laser light can be incident from both front and back sides of the wafer.

JP 2007-123404 A JP 2005-109045 A

  By the way, in laser dicing, a wafer is held by a table and laser light is incident. However, in Patent Document 1, the front side of the wafer is sucked and held by a table so that the laser light can be incident on the back surface of the wafer. It is configured to do.

  However, if the surface side of the wafer is sucked and held by the table in this way, for example, in the case of a wafer having a fine structure element such as a MEMS element (Micro Electro Mechanical System), the element is destroyed by the suction. There is a drawback. Such a problem also occurs in the laser dicing apparatus of Patent Document 2 in which a wafer is sandwiched between transparent glass plates.

  On the other hand, it is also conceivable to support only the peripheral edge of the wafer with an annular table, but if only the peripheral edge is supported in this way, the wafer will be bent and a modified layer cannot be formed in a predetermined region. There are drawbacks.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a laser dicing apparatus and method capable of processing without touching the surface of a wafer.

  Means for solving the problems are as follows.

  In the first embodiment of the laser dicing apparatus, the laser beam emitted from the laser irradiation means is incident on one surface of the wafer along the street, so that the modified layer is formed inside the wafer along the street. In the laser dicing device to be formed, the laser beam is formed with a uniform thickness so that the laser beam can be transmitted, and one surface is a wafer adsorption surface, and the one surface of the wafer is sucked, thereby A wafer table provided with a plate-like wafer holder that holds the entire surface of the one side in close contact with the wafer suction surface, and the laser irradiation means is applied to the wafer through the wafer holder of the wafer table. It is a laser dicing apparatus of the aspect which injects the laser beam radiate | emitted from.

  According to this aspect, the wafer holding part of the wafer table that holds the wafer is formed so as to transmit laser light. One side of the wafer is sucked and held on the wafer suction surface of the wafer holding unit. The wafer suction surface is formed substantially flat, and the wafer is held in close contact with the flat wafer suction surface. Thereby, the wafer can be held without bending. Laser light is incident on the wafer through the wafer table, and a modified layer is formed inside the wafer. Thereby, the wafer can be diced without touching any one surface. Thereby, even if a fine element or the like is formed on one surface, the dicing process can be performed without destroying the element or the like. Furthermore, by making the laser beam incident through the wafer holding unit, it is possible to prevent the laser beam transmitted through the wafer from being burned or the melt from being attached to the wafer table. In addition, this makes it possible to always keep the wafer suction surface flat and to hold the wafer stably for a long period of time. Furthermore, since the wafer holding portion is formed with a uniform thickness and can fix the wafer completely on a flat surface, the distance from the laser irradiation means to the laser irradiation surface (one side surface) of the wafer is made constant. be able to. Thereby, work distance can be made constant. Since the work distance can be made constant in this way, it is possible to greatly reduce the conventional labor of having to perform autofocus along the waviness of the wafer surface. Thereby, the wafer can be processed efficiently, and the throughput can be improved.

  According to a second aspect of the laser dicing apparatus, in the laser dicing apparatus according to the first aspect, the wafer is formed in an annular shape by attaching a dicing tape capable of transmitting the laser light to the one surface. The wafer table is mounted on the inner side of the plate-shaped dicing frame, and the wafer table is formed to have a uniform thickness so that the laser beam can be transmitted. An aspect having a wafer holding part that holds and holds almost the entire surface of the one side of the wafer in close contact with the wafer attracting face by sucking the side face, and a frame holding part that holds the dicing frame This is a laser dicing apparatus.

  According to this aspect, the wafer is mounted on the dicing frame and processed. At this time, the wafer is mounted on the dicing frame via a dicing tape (for example, a transparent tape) that can transmit laser light. At the time of processing, the frame portion is also held together with the wafer and processed. Thereby, handling, such as conveyance of a wafer, can be made easy.

  A third aspect of the laser dicing apparatus is an aspect of the laser dicing apparatus according to the first or second aspect, further comprising a refractive liquid supply means for pouring a refractive liquid into a gap between the wafer and the wafer adsorption surface. This is a laser dicing apparatus.

  According to this aspect, the refractive liquid is poured into the gap between the wafer and the wafer suction surface. When a gap is formed between the wafer and the wafer suction surface, such as when the wafer surface is roughened by grinding marks or when there is roughness on the wafer suction surface, the laser light is scattered and the wafer is scattered. The amount of effective laser light entering the interior becomes very small, and the deteriorated layer cannot be formed efficiently. In addition, due to scattering, laser burn may occur in other parts that should not be irradiated with the laser. However, by interposing a refractive liquid between the wafer and the wafer suction surface, scattering due to the influence of the micro-roughness formed on the wafer and the wafer suction surface can be largely eliminated, and the laser beam into the wafer can be prevented. The transmittance can be increased. In addition, the refractive liquid may become a ball due to surface tension when it is placed on a solid, but by interposing it between the solids as in this embodiment, the interfacial tension is more effectively reduced. Can be used.

  A fourth aspect of the laser dicing apparatus is a laser dicing apparatus in which the wafer suction surface is roughened with a predetermined roughness so that the refractive liquid can easily flow in the third laser dicing apparatus.

  According to this aspect, the wafer suction surface of the wafer holding unit is roughened with a predetermined roughness. Thereby, it is possible to make the refractive liquid easily enter.

  According to a fifth aspect of the laser dicing apparatus, in the laser dicing apparatus according to any one of the first to fourth aspects, the wafer holding unit has a plurality of wafer suction holes formed in a peripheral portion of the wafer suction surface. In the laser dicing apparatus, the wafer is held by sucking the peripheral edge of the wafer through the wafer suction hole.

  According to this aspect, the wafer is sucked at the peripheral portion and held by the wafer holding portion of the wafer table. In general, since no element or the like is formed on the peripheral edge of the wafer, the influence on processing can be eliminated by sucking and holding this region.

  According to a sixth aspect of the laser dicing apparatus, in the laser dicing apparatus according to any one of the first to fourth aspects, the wafer holding portion has a plurality of wafer suction holes formed in a peripheral portion of the wafer suction surface. At the same time, the laser dicing apparatus is configured to hold the wafer by forming a plurality of wafer suction holes in the central portion and sucking the central portion and the peripheral portion of the wafer through the wafer suction holes.

  According to this aspect, the wafer is sucked at the peripheral part and the central part and held by the wafer holding part of the wafer table. By sucking the central portion as well, the wafer can be more closely attached to the wafer table.

  A first aspect of the cleaving apparatus is a cleaving apparatus that cleaves a wafer that has been laser-diced by the laser dicing apparatus according to the second aspect, and includes a frame holding unit that holds the dicing frame, and the wafer. A cleaving apparatus according to an aspect, comprising: a deformable plate-shaped wafer holding unit that holds and holds a surface on one side; and a pressing unit that presses and contacts a pad with the wafer holding unit to bend and deform.

  According to this aspect, the wafer is sucked and held by the bendable and deformable wafer holding means, and is cut along the street by bending the wafer holding means. By bending in the state of being sucked and held, the wafer can be efficiently cleaved without causing any remaining cracks.

  According to a second aspect of the cleaving apparatus, in the cleaving apparatus according to the first aspect, the wafer has a plate-shaped cleaving frame formed in an annular shape by attaching a cleaving tape from above the dicing tape. The frame holding means is a cleaving device that holds the cleaving frame.

  According to this aspect, the wafer is attached to the cleaving tape and cleaved. Thereby, even if the dicing tape does not have stretchability or spreadability, the cleaving process can be performed. Thereby, the freedom degree of selection of the tape for dicing can be raised.

  According to a third aspect of the cleaving apparatus, in the cleaving apparatus according to the second aspect, the wafer holding means holds the one surface of the wafer by vacuum suction, and the cleaving tape has air permeability. A cleaving apparatus having an aspect of being attached to the one surface of the wafer while being vacuum-sucked on the wafer holding means.

  According to this aspect, the cleaving tape has air permeability and is attached to the wafer while being vacuum-sucked. Thereby, the cleaving tape can be affixed to the wafer efficiently. For example, the air permeability can be imparted by forming minute holes.

  According to a fourth aspect of the cleaving apparatus, in the cleaving apparatus according to the second or third aspect, the dicing tape is formed to be embrittled by changing physical characteristics. It is a cleaving apparatus of the aspect further provided with the tape embrittlement means for dicing which changes a mechanical characteristic and embrittles.

  According to this aspect, the dicing tape is formed so as to be brittle (can be cured) by changing physical properties, and is embrittled after the cleaving tape is applied. Thereby, the dicing tape can be cleaved together with the wafer at the time of cleaving. Thereby, the wafer can be cleaved efficiently. As this type of tape, a tape that becomes brittle when irradiated with ultraviolet rays, a tape that becomes brittle when heated, a tape that becomes brittle when cooled, and the like can be used.

  According to a fifth aspect of the cleaving apparatus, in the cleaving apparatus according to any one of the first to fourth aspects, the pressing means is formed to be rotatable around an axis while the pad is formed in a bowl shape. It is the cleaving apparatus of an aspect.

  According to this aspect, the pad for deflecting the wafer holding means is formed in a bowl shape and is formed to be rotatable around the axis. Normally, streets (division lines) are formed in two orthogonal directions (X direction and Y direction). For this reason, the pad is brought into contact with the wafer W in two times in the X direction and the Y direction, and the wafer W is cut. As a result, the wafer can be efficiently cleaved without causing any remaining cracks.

  In the first aspect of the laser dicing method, the laser beam emitted from the laser irradiation means is incident on one surface of the wafer along the street, so that the modified layer is formed inside the wafer along the street. In the laser dicing method to be formed, the laser beam is formed with a uniform thickness so that the laser beam can be transmitted, and one surface is a wafer adsorption surface, and the one surface of the wafer is sucked, thereby The wafer is held by a wafer table having a plate-like wafer holding unit that holds the entire surface of the one side in close contact with the wafer adsorption surface, and passes through the wafer holding unit of the wafer table to the wafer. It is a laser dicing method of the aspect which injects the laser beam radiate | emitted from the said laser irradiation means.

  According to this aspect, the wafer holding part of the wafer table that holds the wafer is formed so as to transmit laser light. One side of the wafer is sucked and held on the wafer suction surface of the wafer holding unit. The wafer suction surface is formed substantially flat, and the wafer is held in close contact with the flat wafer suction surface. Thereby, the wafer can be held without bending. Laser light is incident on the wafer through the wafer table, and a modified layer is formed inside the wafer. Thereby, the wafer can be diced without touching any one surface. Thereby, even if a fine element or the like is formed on one surface, the dicing process can be performed without destroying the element or the like. Furthermore, by making the laser beam incident through the wafer holding unit, it is possible to prevent the laser beam transmitted through the wafer from being burned or the melt from being attached to the wafer table. In addition, this makes it possible to always keep the wafer suction surface flat and to hold the wafer stably for a long period of time. Furthermore, since the wafer holding portion is formed with a uniform thickness and can fix the wafer completely on a flat surface, the distance from the laser irradiation means to the laser irradiation surface (one side surface) of the wafer is made constant. be able to. Thereby, work distance can be made constant. Since the work distance can be made constant in this way, it is possible to greatly reduce the conventional labor of having to perform autofocus along the waviness of the wafer surface. Thereby, the wafer can be processed efficiently, and the throughput can be improved.

  According to a second aspect of the laser dicing method, in the laser dicing method according to the first aspect, the wafer is formed in an annular shape by attaching a dicing tape capable of transmitting the laser light to the one surface. The wafer table is mounted on the inner side of the plate-shaped dicing frame, and the wafer table is formed to have a uniform thickness so that the laser beam can be transmitted. A wafer holding part that holds the wafer by adhering almost the entire surface of the one side of the wafer in close contact with the wafer suction surface, and a frame holding part that holds the dicing frame. The wafer holding unit holds the wafer, and the frame holding unit holds the dicing frame. The mounted the wafer use frame held by the wafer table, through the wafer holder of the wafer table, a laser dicing method aspect of incident laser light emitted from said laser irradiating means to the wafer.

  According to this aspect, the wafer is mounted on the dicing frame and processed. At this time, the wafer is mounted on the dicing frame via a dicing tape (for example, a transparent tape) that can transmit laser light. At the time of processing, the frame portion is also held together with the wafer and processed. Thereby, handling, such as conveyance of a wafer, can be made easy.

  According to a third aspect of the laser dicing method, in the laser dicing method according to the first or second aspect, the laser dicing according to the aspect of holding the wafer by pouring a refractive liquid into a gap between the wafer and the wafer adsorption surface. Is the method.

  According to this aspect, the refractive liquid is poured into the gap between the wafer and the wafer suction surface. When a gap is formed between the wafer and the wafer suction surface, such as when the wafer surface is roughened by grinding marks or when there is roughness on the wafer suction surface, the laser light is scattered and the wafer is scattered. The amount of effective laser light entering the interior becomes very small, and the deteriorated layer cannot be formed efficiently. In addition, due to scattering, laser burn may occur in other parts that should not be irradiated with the laser. However, by interposing a refractive liquid between the wafer and the wafer suction surface, scattering due to the influence of the micro-roughness formed on the wafer and the wafer suction surface can be largely eliminated, and the laser beam into the wafer can be prevented. The transmittance can be increased. In addition, the refractive liquid may become a ball due to surface tension when it is placed on a solid, but by interposing it between the solids as in this embodiment, the interfacial tension is more effectively reduced. Can be used.

  A fourth aspect of the laser dicing method is a laser dicing method of the third laser dicing method, in which the wafer suction surface is roughened with a predetermined roughness so that the refractive liquid can easily flow.

  According to this aspect, the wafer suction surface of the wafer holding unit is roughened with a predetermined roughness. Thereby, it is possible to make the refractive liquid easily enter.

  According to a fifth aspect of the laser dicing method, in the laser dicing method according to any one of the first to fourth aspects, the wafer holding unit has a plurality of wafer suction holes formed in a peripheral portion of the wafer suction surface. In this laser dicing method, the wafer is held by sucking the peripheral edge of the wafer through the wafer suction hole.

  According to this aspect, the wafer is sucked at the peripheral portion and held by the wafer holding portion of the wafer table. In general, since no element or the like is formed on the peripheral edge of the wafer, the influence on processing can be eliminated by sucking and holding this region.

  According to a sixth aspect of the laser dicing method, in the laser dicing method according to any one of the first to fourth aspects, the wafer holding portion has a plurality of wafer suction holes formed in a peripheral portion of the wafer suction surface. In addition, a laser dicing method of a mode in which a plurality of wafer suction holes are formed in the central portion, and the wafer is held by sucking the central portion and the peripheral portion of the wafer through the wafer suction holes.

  According to this aspect, the wafer is sucked at the peripheral part and the central part and held by the wafer holding part of the wafer table. By sucking the central portion as well, the wafer can be more closely attached to the wafer table.

  A first aspect of the cleaving method is a cleaving method for cleaving a wafer that has been laser-diced by the laser dicing method of the second aspect, wherein the one of the wafers is deformed and deformed by a plate-shaped wafer holding means. This is a cleaving method of a mode in which the wafer is cleaved by sucking and holding the side surface, pressing the pad against the wafer holding means, and bending and deforming the wafer holding means.

  According to this aspect, the wafer is sucked and held by the bendable and deformable wafer holding means, and is cut along the street by bending the wafer holding means. By bending in the state of being sucked and held, the wafer can be efficiently cleaved without causing any remaining cracks.

  A first aspect of the cleaving apparatus is a cleaving apparatus that cleaves a wafer that has been laser-diced by the laser dicing apparatus according to the second aspect, and includes a frame holding unit that holds the dicing frame, and the wafer. A cleaving apparatus according to an aspect, comprising: a deformable plate-shaped wafer holding unit that holds and holds a surface on one side; and a pressing unit that presses and contacts a pad with the wafer holding unit to bend and deform.

  A second aspect of the cleaving method is a cleaving method according to the aspect of cleaving the wafer after applying a cleaving tape to the one side surface of the wafer in the first cleaving method.

  According to this aspect, the wafer is attached to the cleaving tape and cleaved. Thereby, even if the dicing tape does not have stretchability or spreadability, the cleaving process can be performed. Thereby, the freedom degree of selection of the tape for dicing can be raised.

  A third aspect of the cleaving method is the cleaving method according to the aspect of the cleaving method of the second aspect, wherein the cleaving tape has air permeability and is attached to the wafer while being vacuumed.

  According to this aspect, the cleaving tape has air permeability and is attached to the wafer while being vacuum-sucked. Thereby, the cleaving tape can be affixed to the wafer efficiently. For example, the air permeability can be imparted by forming minute holes.

  According to a fourth aspect of the cleaving method, in the cleaving method according to the second or third aspect, the dicing tape is formed so as to be embrittled by changing physical characteristics. This is a cleaving method in which the wafer is cleaved after the characteristics are changed to make it brittle.

  According to this aspect, the dicing tape is formed so as to be brittle (can be cured) by changing physical properties, and is embrittled after the cleaving tape is applied. Thereby, the dicing tape can be cleaved together with the wafer at the time of cleaving. Thereby, the wafer can be cleaved efficiently. As this type of tape, a tape that becomes brittle when irradiated with ultraviolet rays, a tape that becomes brittle when heated, a tape that becomes brittle when cooled, and the like can be used.

  According to a fifth aspect of the cleaving method, in the cleaving method according to any one of the first to fourth aspects, the pad is formed in a bowl shape, and the pad is rotated 90 degrees around the axis to divide into two times. The cleaving method is a mode in which the wafer is pressed and brought into contact with the one surface of the wafer.

  According to this aspect, the pad for deflecting the wafer holding means is formed in a bowl shape and is formed to be rotatable around the axis. Normally, streets (division lines) are formed in two orthogonal directions (X direction and Y direction). For this reason, the pad is brought into contact with the wafer W in two times in the X direction and the Y direction, and the wafer W is cut. As a result, the wafer can be efficiently cleaved without causing any remaining cracks.

  According to a first aspect of the wafer processing method, a laser beam emitted from a laser irradiation unit is incident on a street mounted on a dicing frame via a dicing tape, thereby entering the street. A dicing step for forming a modified layer in the wafer along the dicing tape, the dicing tape capable of transmitting the laser light being attached to one surface of the wafer, and the wafer being dicing frame. The one side of the wafer is formed by sucking the one side surface of the wafer so that the one side surface is a wafer suction surface. A wafer holding unit that holds the entire surface of the wafer in close contact with the wafer suction surface, and the dicing frame. The wafer mounted on the dicing frame is held by a wafer table having a frame holding portion for holding a frame, and the laser emitted from the laser irradiation means to the wafer through the wafer holding portion of the wafer table. A laser dicing process in which light is incident to form a modified layer inside the wafer; and a cleaving process in which the wafer that has been subjected to the laser dicing process is bent into individual chips on the tape. It is the wafer processing method of the aspect which has.

  According to this aspect, when the laser dicing process is performed, the wafer holding portion of the wafer table that holds the wafer is formed so as to transmit the laser light. One side of the wafer is sucked and held on the wafer suction surface of the wafer holding unit. The wafer suction surface is formed substantially flat, and the wafer is held in close contact with the flat wafer suction surface. Thereby, the wafer can be held without bending. Laser light is incident on the wafer through the wafer table, and a modified layer is formed inside the wafer. Thereby, the wafer can be diced without touching any one surface. Thereby, even if a fine element or the like is formed on one surface, the dicing process can be performed without destroying the element or the like. Furthermore, by making the laser beam incident through the wafer holding unit, it is possible to prevent the laser beam transmitted through the wafer from being burned or the melt from being attached to the wafer table. In addition, this makes it possible to always keep the wafer suction surface flat and to hold the wafer stably for a long period of time. Furthermore, since the wafer holding portion is formed with a uniform thickness and can fix the wafer completely on a flat surface, the distance from the laser irradiation means to the laser irradiation surface (one side surface) of the wafer is made constant. be able to. Thereby, work distance can be made constant. Since the work distance can be made constant in this way, it is possible to greatly reduce the conventional labor of having to perform autofocus along the waviness of the wafer surface. Thereby, the wafer can be processed efficiently, and the throughput can be improved. The laser-diced wafer is cut into individual chips by bending.

  According to a second aspect of the wafer processing method, in the wafer processing method according to the first aspect, a cleaving tape attaching step of attaching a cleaving tape to the laser-diced wafer is further provided before the cleaving step. It is the wafer processing method of the aspect containing.

  According to this aspect, the wafer is cleaved by being attached to the cleaving tape. Thereby, even if the dicing tape does not have stretchability or spreadability, the cleaving process can be performed. Thereby, the freedom degree of selection of the tape for dicing can be raised.

  According to a third aspect of the wafer processing method, in the wafer processing method according to the second aspect, the cleaving tape has air permeability and is attached to the one side surface of the wafer while being vacuum-sucked. This is a wafer processing method.

  According to this aspect, the cleaving tape has air permeability and is attached to the wafer while being vacuum-sucked. Thereby, the cleaving tape can be affixed to the wafer efficiently. For example, the air permeability can be imparted by forming minute holes.

  According to a fourth aspect of the wafer processing method, in the wafer processing method according to the second or third aspect, the dicing tape is formed so as to be embrittled by changing physical characteristics. The wafer processing method according to an aspect further includes a dicing tape embrittlement step in which the physical properties of the dicing tape are changed and embrittled with respect to the wafer to which the cleaving tape has been previously attached.

  According to this aspect, the dicing tape is formed so as to be brittle (can be cured) by changing physical properties, and is embrittled after the cleaving tape is applied. Thereby, the dicing tape can be cleaved together with the wafer at the time of cleaving. Thereby, the wafer can be cleaved efficiently. As this type of tape, a tape that becomes brittle when irradiated with ultraviolet rays, a tape that becomes brittle when heated, a tape that becomes brittle when cooled, and the like can be used.

  According to a fifth aspect of the wafer processing method, in the wafer processing method according to any one of the first to fourth aspects, in the laser dicing step, a refraction liquid is poured into a gap between the wafer and the wafer adsorption surface. In the wafer processing method, the wafer is held by the wafer holder.

  According to this aspect, the refractive liquid is poured into the gap between the wafer and the wafer suction surface. When a gap is formed between the wafer and the wafer suction surface, such as when the wafer surface is roughened by grinding marks or when there is roughness on the wafer suction surface, the laser light is scattered and the wafer is scattered. The amount of effective laser light entering the interior becomes very small, and the deteriorated layer cannot be formed efficiently. In addition, due to scattering, laser burn may occur in other parts that should not be irradiated with the laser. However, by interposing a refractive liquid between the wafer and the wafer suction surface, scattering due to the influence of the micro-roughness formed on the wafer and the wafer suction surface can be largely eliminated, and the laser beam into the wafer can be prevented. The transmittance can be increased. In addition, the refractive liquid may become a ball due to surface tension when it is placed on a solid, but by interposing it between the solids as in this embodiment, the interfacial tension is more effectively reduced. Can be used.

  According to a sixth aspect of the wafer processing method, in the wafer processing method according to any one of the first to fifth aspects, in the cleaving step, the dicing frame is held, and a plate-shaped wafer holding that can be flexibly deformed is held. By means of a wafer processing method in which the wafer is cleaved by adsorbing and holding the one side surface of the wafer by means, pressing the pad against the wafer holding means, and bending and deforming the wafer holding means is there.

  According to this aspect, the wafer is sucked and held by the bendable and deformable wafer holding means, and is cut along the street by bending the wafer holding means. By bending in the state of being sucked and held, the wafer can be efficiently cleaved without causing any remaining cracks.

  According to the present invention, processing can be performed without touching the surface of the wafer.

Schematic configuration diagram showing an embodiment of a laser dicing apparatus A perspective view showing a wafer mounted on a dicing frame 3-3 sectional view of FIG. Explanatory drawing explaining the suction position of a wafer Schematic configuration diagram of laser irradiation equipment Schematic configuration diagram showing a second embodiment of the laser dicing apparatus 7-7 sectional view of FIG. Schematic configuration diagram showing another embodiment of a laser dicing apparatus 9-9 sectional view of FIG. Schematic configuration diagram showing another embodiment of a laser dicing apparatus 11-11 sectional view of FIG. Schematic configuration diagram showing another embodiment of a laser dicing apparatus Schematic configuration diagram showing another embodiment of a laser dicing apparatus Plan view of a wafer table with the function of pouring refractive liquid between the wafer and the wafer table 15-15 sectional view of FIG. Process chart showing outline of cleaving process by cleaving device Schematic configuration diagram of a cleaving device that cleaves wafers while vacuum suction Process chart showing outline of cleaving process by cleaving device The figure which shows the outline of the expansion process by a cleaving apparatus Schematic configuration diagram showing another embodiment of the cleaving device The figure which shows the state of a press pad Process diagram outlining a series of processes during laser dicing Process chart of the outline of a series of processing at the time of division

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

<< First Embodiment of Laser Dicing Apparatus >>
<Constitution>
FIG. 1 is a schematic configuration diagram illustrating a first embodiment of a laser dicing apparatus.

  As shown in the figure, the laser dicing apparatus 10 according to the present embodiment mainly applies laser light to the wafer table 20 that holds the wafer W, and the laser reflection preventing plate 50 and the wafer W held on the wafer table 20. And a laser irradiation device 60.

  First, the wafer W to be processed by the laser dicing apparatus 10 of the present embodiment will be described.

  A wafer W to be processed by the laser dicing apparatus 10 according to the present embodiment is a wafer W having a MEMS element formed on the surface thereof, and is processed while mounted on the dicing frame F.

  FIG. 2 is a perspective view showing the wafer mounted on a dicing frame.

  As shown in the figure, the wafer W is mounted on a dicing frame F via a dicing tape T.

  The dicing frame F is formed in a frame shape, and a dicing tape T is attached inside the dicing frame F. The back surface of the wafer W is attached to the dicing tape T and mounted on the dicing frame F.

  Here, the dicing tape T attached to the dicing frame F is formed of a material having ductility, and is formed of a material capable of transmitting laser light emitted from the laser irradiation device 60. In this example, it is made of a transparent material having ductility. Further, it is more preferable to have air permeability.

  The wafer W mounted on the dicing frame F is stocked, for example, in a cassette or the like, and is supplied to the wafer table 20 by a transfer device (not shown) (for example, a robot arm). At this time, the wafer W is transferred to the wafer table 20 with the surface (back surface) to which the dicing tape T is adhered facing the suction surface of the wafer table 20, and the surface to which the dicing tape T is adhered is transferred. It is sucked and held on the wafer table 20.

  As shown in FIG. 1, the wafer table 20 mainly includes a table plate 22 and a table plate holding frame 24 that holds the table plate 22.

  The table plate 22 is formed in a disk shape corresponding to the wafer W to be processed (in a disk shape having a larger diameter than the wafer W to be processed so that the entire surface of the wafer W to be processed can be supported). The upper and lower surfaces are both formed flat. That is, it is formed with a uniform thickness. The table plate 22 is formed of a material that can transmit laser light emitted from the laser irradiation device 60. As an example, in the present embodiment, it is made of transparent quartz glass. The table plate 22 is formed with a necessary and sufficient thickness so that the wafer W to be processed can be held without bending.

  The table plate 22 has a wafer suction surface 22A for holding the wafer W on the lower surface side. As shown in FIG. 3, a plurality of wafer suction holes 26 are formed on the wafer suction surface 22A at a constant pitch on a concentric circle. The wafer suction hole 26 is formed corresponding to the wafer W to be processed, and is formed at a position for sucking the peripheral edge of the wafer W to be processed. That is, as shown in FIG. 4, normally, the peripheral portion of the wafer (the region on the outer periphery side of the circle indicated by the broken line in FIG. 4) is a blank region, and no element or the like is formed in this blank region. The wafer suction holes 26 are arranged so as to suck the wafer in this blank area.

  Each wafer suction hole 26 is formed perpendicular to the table plate 22 and communicates with an annular flow path 28 formed inside the table plate 22. The annular flow path 28 is formed corresponding to the arrangement locus of the wafer suction holes 26 and is formed in an annular shape parallel to the wafer suction surface 22A. That is, the wafer suction holes 26 are formed on the annular flow path 28 at a constant pitch.

  A connection channel 30 is communicated with a part of the annular channel 28. The connection channel 30 is formed in parallel with the wafer suction surface 22 </ b> A and communicates with a connection channel communication port 32 formed on the outer peripheral surface of the table plate 22. By sucking air from the connection flow path communication port 32, air is sucked from each wafer suction hole 26.

  The table plate holding frame 24 is formed in an annular shape. The table plate 22 is held on the inner periphery of the table plate holding frame 24.

  The table plate holding frame 24 is rotated around the θ axis by a rotation driving mechanism (not shown), and is moved up and down (Z direction) by an elevator driving mechanism (not shown). Moreover, while moving in the front-rear direction (Y direction) on the horizontal plane by a front-rear drive mechanism (not shown), it moves in the left-right direction (X direction) on the horizontal plane by a left-right drive mechanism (not shown). Furthermore, the front and back (up and down) is reversed by a front and back reversing mechanism (not shown) (for example, the front and back are reversed by rotating around the X axis).

  The table plate 22 rotates around the θ axis as the table plate holding frame 24 rotates. Further, the table plate holding frame 24 moves up and down as it moves up and down. Further, the table plate holding frame 24 moves back and forth when moving in the front-rear direction, and moves left and right when moved in the left-right direction. Further, when the table plate holding frame 24 is turned upside down, the front and back (up and down) are turned upside down.

  The table plate holding frame 24 is formed with a communication channel 34 that communicates with the connection channel communication port 32 of the connection channel 30 formed on the table plate 22. The communication channel 34 is formed horizontally and communicates with a connection port 36 formed in the outer peripheral surface portion of the table plate holding frame 24.

  A suction pipe 38 having flexibility is connected to the connection port 36. A vacuum pump 40 is connected to the suction pipe 38. By driving the vacuum pump 40, air is sucked from the wafer suction holes 26 and the wafer W is sucked and held on the wafer suction surface of the table plate 22.

  The laser antireflection plate 50 is installed below the wafer table 20. The laser antireflection plate 50 is formed in a flat plate shape having an upper surface subjected to antireflection processing (for example, black processing) of laser light, and is horizontally placed at a position away from the wafer suction surface 22A of the wafer table 20 by a predetermined distance. Installed. That is, a predetermined space is formed between the wafer suction surface 22 </ b> A of the wafer table 20 and the laser antireflection plate 50.

  The laser light emitted from the laser irradiation device 60 and transmitted through the wafer W enters the laser antireflection plate 50. Thereby, unnecessary reflection can be prevented and occurrence of reflection burn can be prevented.

  The laser irradiation device 60 is installed above the wafer table 20 and emits laser light vertically toward the wafer table 20.

  FIG. 5 is a schematic configuration diagram of a laser irradiation apparatus. As shown in the figure, the laser irradiation device 60 mainly includes a laser oscillation device 62, a collimator lens 64, a condenser lens 66, and an actuator 68.

  The laser oscillator 62 oscillates laser light in accordance with the processing conditions of the wafer W. The laser light oscillated from the laser oscillation device 62 is collimated by the collimator lens 64 and then condensed at the focal point P by the condenser lens 66.

  When the focal point P is set inside the wafer W and laser light is incident on the wafer W, a modified region is formed inside the wafer W. When the wafer W is moved horizontally in this state, the modified region is continuously formed along the movement locus of the focal point P, and the modified layer L is formed. At the time of processing, this modified layer is formed along the street S.

  The actuator 68 slightly moves the condenser lens 66 in the optical axis direction (Z-axis direction). That is, the condenser lens 66 is held by a lens frame (not shown) and is supported so as to be movable in the optical axis direction. The condenser lens 66 is driven by the actuator 68 and moves minutely in the optical axis direction.

  By driving the actuator 68 and moving the condenser lens 66 in the optical axis direction, the position of the focal point P of the laser light is displaced in the Z direction. Thereby, the position (position in the Z direction) where the modified layer L is formed can be adjusted. Further, a plurality of modified layers L can be formed inside the wafer W by changing the position of the focal point P in the Z direction and making the wafer W enter the wafer W a plurality of times.

  The laser dicing apparatus 10 of the present embodiment is configured as described above.

  The operation of the laser dicing apparatus 10 is controlled by a control device (not shown). The control device executes a predetermined control program, controls the operation of each unit, and executes the processing of the wafer W.

<Action>
Next, a dicing method using the laser dicing apparatus 10 will be described.

  As described above, the wafer W is processed while mounted on the dicing frame F. The wafer W is mounted on a dicing frame F by attaching the back surface (the surface on which no MEMS element is formed) to the dicing tape T.

  The wafer W mounted on the dicing frame F is transferred to the lower part of the wafer table 20 by a transfer device (not shown) (for example, a robot arm). At this time, the wafer W is transported to the lower position of the wafer table 20 with the surface on which the dicing tape T is adhered facing upward, and the surface being in a non-contact state.

  The wafer W transferred to the lower position of the wafer table 20 is delivered from the transfer device to the wafer table 20. The delivery is performed by sucking and holding the back surface of the wafer W by the wafer suction surface 22A of the wafer table 20. Specifically, this is performed as follows.

  First, the wafer W is positioned. That is, the wafer W is positioned so that the center of the wafer W coincides with the center of the wafer table 20. Thereafter, the wafer suction surface 22A of the wafer table 20 is brought into contact with the back surface of the wafer W, and the vacuum pump 40 is driven. As a result, the peripheral edge of the back surface of the wafer W is sucked into the wafer suction hole 26, and the wafer W is sucked and held on the wafer table 20.

  The wafer W sucked and held in this way on the wafer table 20 is held in close contact with the wafer suction surface 22A of the wafer table 20 formed flat via the dicing tape T. Thereby, the wafer W can be held horizontally without being bent. Moreover, since the back surface of the wafer W is sucked and held via the dicing tape T, the front surface can be held in a non-contact manner.

  The transfer device that has delivered the wafer W retracts from the lower portion of the wafer table 20. Thereafter, a predetermined alignment process is performed, and dicing is started.

  Dicing is performed by causing the laser beam emitted from the laser irradiation device 60 to enter the wafer W along the street (division planned line) S.

  A control device (not shown) drives the actuator 68 to adjust the position of the condenser lens 66 so that the focal point P is set at a predetermined position inside the wafer W. Then, the wafer table 20 is moved so that the emitted laser light enters the wafer W along the street S.

  By the way, in the laser dicing apparatus 10 of the present embodiment, the wafer W to be processed is sucked and held on the lower surface of the wafer table 20. On the other hand, the laser light is incident on the upper surface of the wafer table 20.

  However, since the wafer table 20 is formed so as to transmit laser light, it can enter the wafer W even when the laser light is incident on the upper surface.

  In addition, the wafer W has the surface (back surface) to which the dicing tape T is attached adsorbed and held on the wafer table 20, but the dicing tape T is also formed so as to transmit laser light. Can be incident.

  Thus, in the laser dicing apparatus 10 according to the present embodiment, the laser light is incident on the wafer W through the wafer table 20 and the dicing tape T.

  Since the wafer W is in close contact with the wafer suction surface 22A of the wafer table 20 and is held without being bent, the laser light can be accurately incident on a predetermined position. Thereby, the altered layer can be formed accurately along the street S.

  Moreover, since the wafer W is hold | maintained at the wafer table 20 without touching the surface, it can process without destroying the MEMS element formed in the surface.

  In addition, if the surface of the wafer W is held by suction, the wafer suction surface may be burnt by the laser light transmitted through the wafer W, or the melt may adhere, and the smoothness of the wafer suction surface cannot be maintained. By adsorbing and holding the wafer W without touching the surface, it is possible to prevent such a problem from occurring. Thereby, even if it processes continuously, the wafer W can always be adsorbed and held flat.

  Further, since the laser light is incident on the back surface of the wafer W, the deteriorated layer can be accurately and reliably formed at a predetermined position without being affected by the elements formed on the front surface.

  When the laser beam is incident on the wafer W along the street S and the processing is completed, the wafer W is transferred from the wafer table 20 to the transfer device, and is transferred to the next process by the transfer device.

  As described above, according to the laser dicing apparatus 10 of the present embodiment, the wafer W is held without touching the front surface, and the laser beam is incident on the back surface and processed. As a result, even a wafer having an easily damaged element (for example, a MEMS element) on the surface can be processed without damaging the element. Further, even a wafer having a metal film formed near the street can be processed.

  Further, since the entire surface of the wafer W is adsorbed and held on the wafer adsorption surface 22A of the wafer table 20, the wafer W can be fixed without bending (it can be fixed in a completely flat state). Thereby, the distance (work distance) from the laser irradiation apparatus 60 to the wafer W can be made constant. Since the work distance can be made constant, it is not necessary for the laser irradiation apparatus 60 to perform autofocusing along the waviness of the wafer W, and the processing efficiency during processing can be improved (throughput is improved). Can be made.)

<< Second Embodiment of Laser Dicing Apparatus >>
<Constitution>
FIG. 6 is a schematic configuration diagram showing a second embodiment of the laser dicing apparatus.

  As shown in the figure, the laser dicing apparatus 110 according to the present embodiment mainly applies laser light to the wafer table 120 that holds the wafer W, and the laser reflection preventing plate 150 and the wafer W held on the wafer table 120. And a laser irradiation device 160 to be configured.

  The wafer W to be processed by the laser dicing apparatus 110 of the present embodiment is also a wafer W having a MEMS element formed on the surface, similar to the laser dicing apparatus 10 of the first embodiment described above. Processing is performed with the frame F mounted (see FIG. 2).

  As shown in FIG. 6, the wafer table 120 mainly includes a table plate 122 and a table plate holding frame 124 that holds the table plate 122, and holds the dicing frame F together with the wafer W by suction.

  The table plate 122 sucks and holds the wafer W mounted on the dicing frame F. The table plate 122 sucks and holds the wafer W portion of the wafer W mounted on the dicing frame F and sucks the portion of the dicing frame F of the wafer W mounted on the dicing frame F. It is comprised with the flame | frame holding | maintenance part 122F to hold | maintain.

  The wafer holding unit 122W that sucks and holds the portion of the wafer W is formed in a disk shape corresponding to the wafer W to be processed (from the wafer W to be processed so that the entire surface of the wafer W to be processed can be supported). Are formed in a large-diameter disk shape), and the upper and lower surfaces thereof are both formed flat. The wafer holder 122W is formed of a material that can transmit laser light emitted from the laser irradiation device 160. As an example, in the present embodiment, it is made of transparent quartz glass. The table plate 122 is formed with a necessary and sufficient thickness so that the wafer W to be processed can be held without bending.

  The wafer holding part 122W is a wafer suction surface 122WA for holding the wafer W on the lower surface side. On the wafer suction surface 122WA, as shown in FIG. 7, a plurality of wafer suction holes 126W are formed on a concentric circle at a constant pitch. This wafer suction hole 126W is formed corresponding to the wafer W to be processed, and is formed at a position for sucking the peripheral edge (the blank area (see FIG. 4)) of the wafer W to be processed.

  Each wafer suction hole 126W is formed perpendicular to the wafer holding part 122W and communicates with a wafer suction annular flow path 128W formed inside the wafer holding part 122W. The wafer suction annular flow path 128 </ b> W is formed corresponding to the arrangement locus of the wafer suction holes 126 </ b> W, and is formed in an annular shape parallel to the wafer suction surface 122 </ b> WA. That is, the wafer suction holes 126W are formed at a constant pitch on the wafer suction annular flow path 128W.

  A wafer holding portion connection flow path 130W is communicated with a part of the wafer suction annular flow path 128W. Wafer holding part connection flow path 130W is formed in parallel with wafer suction surface 122WA and communicates with wafer holding part connection flow path communication port 132W formed on the outer peripheral surface of wafer holding part 122W. By sucking air from the wafer holding part connection channel communication port 132W, air is sucked from each wafer suction hole 126W.

  The frame holding part 122F that sucks and holds the portion of the dicing frame F is formed in an annular shape corresponding to the dicing frame F, and both upper and lower surfaces thereof are formed flat. The frame holding part 122F is formed of a rigid body, is disposed so as to surround the outer periphery of the wafer holding part 122W, and is integrated with the wafer holding part 122W.

  The frame holding portion 122F has one surface (the same surface as the wafer suction surface 122WA) as the frame suction surface 122FA. As shown in FIG. 7, a plurality of frame suction holes 126F are formed on the frame suction surface 122FA at a constant pitch on a concentric circle.

  Each frame suction hole 126F is formed perpendicular to the frame holding portion 122F and communicates with a frame suction annular channel 128F formed inside the frame holding portion 122F. The frame suction annular flow path 128F is formed corresponding to the arrangement locus of the frame suction holes 126F, and is formed in an annular shape parallel to the frame suction surface 122FA. That is, the frame suction holes 126F are formed at a constant pitch on the frame suction annular flow path 128F.

  A frame holding portion connection flow path 130F communicates with a part of the frame adsorption annular flow path 128F. The frame holding part connection flow path 130F is formed in parallel with the frame suction surface 122FA, and communicates with the frame holding part inner peripheral side connection flow path communication port 132FA formed on the inner peripheral surface of the frame holding part 122F. The frame holding part outer peripheral side connection flow path communication port 132FB is formed on the outer peripheral surface of the holding part 122F. The frame holding portion inner peripheral side connection flow path communication port 132FA is communicated with a wafer holding portion connection flow path communication port 132W formed on the outer peripheral surface of the wafer holding portion 122W. By sucking air from the frame holding portion outer peripheral side connection flow path communication port 132FB, air in the frame suction annular flow path 128F is sucked, and air in the wafer suction annular flow path 128W is sucked. Thereby, air is sucked from each frame suction hole 126F of the frame holding part 122F, and air is sucked from each wafer suction hole 126W of the wafer holding part 122W.

  The table plate holding frame 124 is formed in an annular shape. The table plate 122 is held on the inner periphery of the table plate holding frame 124.

  The table plate holding frame 124 is rotated about the θ axis by a rotation drive mechanism (not shown) and is moved up and down (Z direction) by an elevation drive mechanism (not shown). Moreover, while moving in the front-rear direction (Y direction) on the horizontal plane by a front-rear drive mechanism (not shown), it moves in the left-right direction (X direction) on the horizontal plane by a left-right drive mechanism (not shown). Furthermore, the front and back (up and down) is reversed by a front and back reversing mechanism (not shown) (for example, the front and back are reversed by rotating around the X axis).

  The table plate 122 rotates around the θ axis as the table plate holding frame 124 rotates. Further, the table plate holding frame 124 moves up and down as it moves up and down. Further, the table plate holding frame 124 moves back and forth by moving in the front-rear direction, and moves left and right by moving in the left-right direction. Further, when the table plate holding frame 124 is reversed, the front and back (up and down) are reversed.

  The table plate holding frame 124 is formed with a communication channel 134 communicating with the frame holding unit outer peripheral side connection channel communication port 132FB formed on the outer peripheral surface of the frame holding unit 122F of the table plate 122. The communication channel 134 is formed horizontally and communicates with a connection port 136 formed on the outer peripheral surface portion of the table plate holding frame 124.

  A flexible suction tube 138 is connected to the connection port 136. A vacuum pump 140 is connected to the suction pipe 138. By driving the vacuum pump 140, air is sucked from each wafer suction hole 126W of the wafer holding part 122W, and air is sucked from each frame suction hole 126F of the frame holding part 122F. As a result, the wafer W is sucked and held on the wafer suction surface 122WA of the table plate 122, and the dicing frame F is sucked and held on the frame suction surface 122FA of the table plate 122.

  The laser antireflection plate 150 is installed below the wafer table 120. The laser antireflection plate 150 is formed in a flat plate shape having a laser beam antireflection treatment (for example, black processing) on the upper surface thereof, and is horizontally placed at a position away from the wafer suction surface 122WA of the wafer table 120 by a predetermined distance. Installed. That is, a predetermined space is formed between the wafer suction surface 122WA of the wafer table 120 and the laser antireflection plate 150.

  Laser light emitted from the laser irradiation device 160 and transmitted through the wafer W enters the laser antireflection plate 150. Thereby, unnecessary reflection can be prevented and occurrence of reflection burn can be prevented.

  The laser irradiation device 160 is installed above the wafer table 120 and emits laser light vertically toward the wafer table 120. The configuration of the laser irradiation device 160 is the same as that of the laser irradiation device 60 of the first embodiment described above. Therefore, the description is omitted.

  When the focal point P is set inside the wafer W and laser light is incident on the wafer W from the laser irradiation device 160, a modified region is formed inside the wafer W. When the wafer W is moved horizontally in this state, the modified region is continuously formed along the movement locus of the focal point P, and the modified layer L is formed. At the time of processing, this modified layer is formed along the street S.

  The laser dicing apparatus 110 of the present embodiment is configured as described above.

  The operation of the laser dicing apparatus 110 is controlled by a control device (not shown). The control device executes a predetermined control program, controls the operation of each unit, and executes the processing of the wafer W.

<Action>
Next, a dicing method using the laser dicing apparatus 110 of the present embodiment will be described.

  As described above, the wafer W is processed while mounted on the dicing frame F. The wafer W is mounted on a dicing frame F by attaching the back surface (the surface on which no MEMS element is formed) to the dicing tape T.

  The wafer W mounted on the dicing frame F is transferred to the lower part of the wafer table 120 by a transfer device (not shown) (for example, a robot arm). At this time, the wafer W is transported to the lower position of the wafer table 120 with the surface to which the dicing tape T is attached facing upward and the surface being in a non-contact state.

  The wafer W transferred to the lower position of the wafer table 120 is transferred from the transfer device to the wafer table 120. The delivery is performed by sucking and holding the back surface of the wafer W by the wafer suction surface 122WA of the wafer table 120 and holding the dicing frame F by the frame suction surface 122FA of the wafer table 120. Specifically, this is performed as follows.

  First, the wafer W is positioned. That is, the wafer W is positioned so that the center of the wafer W coincides with the center of the wafer table 120. Thereafter, the wafer suction surface 122WA and the frame suction surface 122FA of the wafer table 120 are brought into contact with the back surface of the wafer W and the back surface of the dicing frame F, and the vacuum pump 140 is driven. As a result, the peripheral edge of the back surface of the wafer W is sucked into the wafer suction hole 126W, the wafer W is sucked and held in the wafer table 120, and the back surface of the dicing frame F is sucked into the frame suction hole 126F. F is sucked and held on the wafer table 120.

  The wafer W sucked and held in this manner on the wafer table 120 is held in close contact with the wafer suction surface 122WA of the flatly formed wafer table 120 via the dicing tape T. Further, the dicing frame F is held in close contact with the frame suction surface 122FA via the dicing tape T. Thereby, the wafer W can be held horizontally without being bent. Moreover, since the back surface of the wafer W is sucked and held via the dicing tape T, the front surface can be held in a non-contact manner.

  The transfer device that has delivered the wafer W retracts from the lower portion of the wafer table 120. Thereafter, a predetermined alignment process is performed, and dicing is started.

  Dicing is performed by causing the laser light emitted from the laser irradiation device 160 to enter the wafer W along the street (division planned line) S.

  A control device (not shown) adjusts the position of the condenser lens by driving the actuator so that the focal point P is set at a predetermined position inside the wafer W. Then, the wafer table 120 is moved so that the emitted laser light is incident on the wafer W along the street S.

  By the way, in the laser dicing apparatus 110 of the present embodiment, the wafer W to be processed is attracted and held on the lower surface of the wafer table 120. In contrast, the laser light is incident on the upper surface of the wafer table 120.

  However, since the wafer table 120 is formed so as to transmit laser light, it can be incident on the wafer W even when the laser light is incident on the upper surface.

  Further, the wafer W has the surface (rear surface) to which the dicing tape T is stuck attached to the wafer table 120, but the dicing tape T is also formed so as to transmit laser light. Can be incident.

  As described above, in the laser dicing apparatus 110 according to the present embodiment, the laser light is incident on the wafer W through the wafer table 120 and the dicing tape T.

  Since the wafer W is in close contact with the wafer suction surface 122WA of the wafer table 120 and is held without being bent, the laser beam can be accurately incident on a predetermined position. Thereby, the altered layer can be formed accurately along the street S.

  In addition, since the wafer W is held on the wafer table 120 without touching the surface, it can be processed without destroying the MEMS element formed on the surface.

  In addition, if the surface of the wafer W is held by suction, the wafer suction surface may be burnt by the laser light transmitted through the wafer W, or the melt may adhere, and the smoothness of the wafer suction surface cannot be maintained. By adsorbing and holding the wafer W without touching the surface, it is possible to prevent such a problem from occurring. Thereby, even if it processes continuously, the wafer W can always be adsorbed and held flat.

  Further, since the laser light is incident on the back surface of the wafer W, the deteriorated layer can be accurately and reliably formed at a predetermined position without being affected by the elements formed on the front surface.

  When the laser beam is incident on the wafer W along the street S and the processing is completed, the wafer W is transferred from the wafer table 120 to the transfer device, and is transferred to the next process by the transfer device.

  As described above, also in the laser dicing apparatus 110 of the present embodiment, the wafer W is held without touching the front surface, and the laser beam is incident on the back surface and processed. As a result, even a wafer having an easily damaged element (for example, a MEMS element) on the surface can be processed without damaging the element. Further, even a wafer having a metal film formed near the street can be processed.

  Further, since the entire surface of the wafer W is adsorbed and held on the wafer adsorption surface 22A of the wafer table 20, the wafer W can be fixed without bending (it can be fixed in a completely flat state). Thereby, the distance (work distance) from the laser irradiation apparatus 60 to the wafer W can be made constant. Since the work distance can be made constant, it is not necessary for the laser irradiation apparatus 60 to perform autofocusing along the waviness of the wafer W, and the processing efficiency during processing can be improved (throughput is improved). Can be made.)

<< Other Embodiments of Laser Dicing Apparatus >>
<Other Embodiment 1>
In the laser dicing apparatus 10 of the first embodiment, the wafer suction hole 26 is formed only in the peripheral portion of the table plate 22 and only the peripheral portion of the wafer W is sucked and held. As shown, the wafer suction hole 42 may be formed in the central portion of the table plate 22 and the central portion of the wafer W may be sucked and held. Thereby, the wafer W can be more closely attached to the wafer suction surface 22A.

  In the example shown in the figure, wafer suction holes 42 are formed at three locations in the center of the lower surface of the table plate 22. Each wafer suction hole 42 is formed perpendicular to the wafer suction surface 22 </ b> A and communicates with a disk-shaped central space 44 formed in the table plate 22. The central space 44 communicates with the annular flow path 28 via a central communication flow path 46 that is horizontally formed inside the table plate 22. Therefore, by driving the vacuum pump 40, it is possible to suction from the wafer suction hole 42 in the center simultaneously with the wafer suction hole 26 in the peripheral portion.

  If a suction hole or the like is formed at a position where the laser beam is incident, the position of the focal point P may be shifted at that position. Therefore, the suction hole or the like is disposed away from the position where the laser beam is incident. It is preferable. Therefore, when arranging the suction holes in the central portion, it is preferable to install the minimum necessary number.

  In addition, when a suction hole or the like is disposed at a position where the laser light is incident, it is preferable to adjust the position of the focal point P at that position. That is, since the positions of the suction holes and the like are known, the control device adjusts the position of the focal point P as necessary, and irradiates the laser beam.

  The same applies to the laser dicing apparatus 110 of the second embodiment. As shown in FIGS. 10 and 11, a wafer suction hole 142 is also formed in the central portion of the wafer holding portion 122W, and the central portion of the wafer W is also formed. It is also possible to adopt a configuration for holding by suction.

  In the above embodiment, when the peripheral edge of the wafer W is sucked and held, a plurality of wafer suction holes 42 (142) having a predetermined diameter are formed on the concentric circles at a constant pitch, and the wafer suction holes 42 (142) are formed. Although the peripheral edge of the wafer W is sucked and held by vacuum suction, an annular groove (wafer suction groove) is formed on the peripheral edge of the wafer suction surface 22A (122WA), and vacuum suction is performed from the wafer suction groove. By doing so, it can also be set as the structure which adsorbs and hold | maintains the peripheral part of the wafer W (refer FIG. 14).

  Similarly, in the case of holding the dicing frame F by suction (second embodiment of the laser dicing apparatus), an annular groove (frame suction groove) is formed on the frame suction surface 122FA of the frame holding portion 122F. It is also possible to adopt a configuration in which a portion of the dicing frame is sucked and held by vacuum suction from the suction groove (see FIG. 14).

<Other embodiment 2>
In the laser dicing apparatus 10 according to the first embodiment, the wafer W is sucked and held on the lower surface of the horizontally installed wafer table 20, but the wafer is placed on the upper surface of the wafer table 20 as shown in FIG. The suction surface 22 </ b> A may be formed, and the wafer W may be placed on the upper surface of the wafer table 20 and held by suction. In this case, as shown in the figure, the laser irradiation device 60 is installed at a position below the wafer table 20 and emits laser light from below to above. As described above, the wafer suction surface 22A is formed on the upper surface of the wafer table 20, and the wafer W is placed on the upper surface of the wafer table 20 to be sucked and held. Also, the wafer W can be securely adhered to the wafer suction surface 22A, and the wafer W can be held flat.

  The same applies to the laser dicing apparatus 110 of the second embodiment. As shown in FIG. 13, a wafer suction surface 122WA and a frame suction surface 122FA are formed on the upper surface of the wafer table 120, and the wafer W is formed on the upper surface of the wafer table 120. The wafer W and the dicing frame F can be sucked and held. In this case, as shown in the figure, the laser irradiation device 160 is installed at a position below the wafer table 120 and emits laser light from below to above.

<Other embodiment 3>
In the above-described embodiment, the wafer W mounted on the dicing frame F is sucked and held by the wafer table 20 and laser dicing is performed. However, the wafer W is not mounted on the dicing frame F, but directly on the wafer table 20. The laser dicing can also be performed by holding. Further, it is possible to adopt a configuration in which laser dicing is performed by attaching only a tape (dicing tape) capable of transmitting laser light to the back surface without mounting on the dicing frame F.

<Other embodiment 4>
In the above-described embodiment, the back surface of the wafer W is sucked (vacuum suction), and the wafer W is brought into close contact with the wafer suction surface 22A (122WA) of the wafer table 20 (120). In this case, a gap is formed between the wafer W after air suction and the wafer table 20 (120) (between the wafer suction surface 22A (122WA) and the dicing tape T) due to mutual surface roughness. If so, the laser light may be scattered by the gap. Similarly, when the wafer is directly sucked and held by the wafer table 20 (120) without sticking the dicing tape, the surface roughness between the wafer attracting surface 22A (122WA) and the attracted surface of the wafer W is the same. When a gap associated with is formed, the laser light may be scattered by the gap.

  Such scattering of laser light based on a minute gap between the wafer and the wafer table can be suppressed by pouring a refractive liquid between the wafer and the wafer table.

  FIG. 14 is a plan view of a wafer table having a function of pouring a refracting liquid between the wafer and the wafer table, and FIG. 15 is a sectional view taken along line 15-15 of FIG.

  As shown in the figure, the wafer table 220 has a refractive liquid supply groove 250 formed on the wafer suction surface 222WA, and the refractive liquid is supplied to the refractive liquid supply groove 250 so that the wafer table 220 is spaced between the wafer W and the wafer table 220. A refraction liquid is supplied to.

  The wafer table 220 is mainly composed of a table plate 222 and a table plate holding frame 224 that holds the table plate 222, and holds the dicing frame F together with the wafer W by suction.

  The table plate 222 sucks and holds the wafer W mounted on the dicing frame F. The table plate 222 sucks and holds a portion of the wafer W of the wafer W mounted on the dicing frame F, and a portion of the dicing frame F of the wafer W mounted on the dicing frame F. It is comprised with the flame | frame holding | maintenance part 222F to hold | maintain.

  The wafer holding unit 222W that sucks and holds the portion of the wafer W is formed in a disk shape corresponding to the wafer W to be processed (from the wafer W to be processed so that the entire surface of the wafer W to be processed can be supported). Are formed in a large-diameter disk shape), and the upper and lower surfaces thereof are both formed flat. The wafer holder 222W is formed of a material that can transmit laser light emitted from the laser irradiation apparatus. As an example, in the present embodiment, it is made of transparent quartz glass. The table plate 222 is formed with a necessary and sufficient thickness so that the wafer W to be processed can be held without bending.

  The wafer holding portion 222W is a wafer suction surface 222WA for holding the wafer W on the lower surface side. On the wafer suction surface 222WA, an annular wafer suction groove 226W is formed at the periphery. The wafer suction groove 226W is formed corresponding to the diameter of the wafer W to be processed, and is formed at a position in contact with the peripheral portion (the blank area (see FIG. 4)) of the wafer W to be processed.

  The wafer suction groove 226W is formed with a constant width and depth, and communicates with a wafer suction flow path 228W formed inside the wafer holding portion 222W.

  The wafer suction flow path 228W is formed vertically and communicates with the wafer holding part connection flow path 230W. The wafer holding part connection flow path 230W is formed in parallel with the wafer suction surface 222WA. By sucking air from the wafer holding part connection channel 230W, air is sucked from the wafer suction groove 226W.

  A refractive liquid supply groove 250 is further formed on the wafer suction surface 222WA. The refraction liquid supply groove 250 is formed inside the wafer suction groove 226W, and is formed in a spiral shape with a certain width and depth.

  A refractive liquid supply groove suction channel 252 formed inside the wafer holding part 222W is communicated with the inner peripheral end of the refractive liquid supply groove 250. The refraction liquid supply groove suction flow path 252 is formed vertically and communicates with the refraction liquid supply groove communication flow path 254. The refractive liquid supply groove communication channel 254 is formed in parallel with the wafer suction surface 222WA and communicates with a refractive liquid supply groove connection port (not shown) formed in the outer peripheral surface portion of the table plate holding frame 224.

  On the other hand, a refractive liquid supply channel 256 formed inside the wafer holding part 222W is communicated with the outer peripheral end of the refractive liquid supply groove 250. The refraction liquid supply channel 256 is formed vertically and communicates with the refraction liquid supply groove communication channel 258. The refraction liquid supply groove communication channel 258 is formed in parallel with the wafer suction surface 222WA and communicates with the refraction liquid supply port 260 formed in the outer peripheral surface portion of the table plate holding frame 224.

  The frame holding part 222F that sucks and holds the portion of the dicing frame F is formed in an annular shape corresponding to the dicing frame F, and both upper and lower surfaces thereof are formed flat. The frame holding part 222F is formed of a rigid body, is disposed so as to surround the outer periphery of the wafer holding part 222W, and is integrated with the wafer holding part 222W.

  The frame holding portion 222F has one surface (the same surface as the wafer suction surface 222WA) as the frame suction surface 222FA. As shown in FIG. 14, an annular frame suction groove 226F is formed on the frame suction surface 222FA.

  The frame suction groove 226F is formed with a certain width and depth, and communicates with a frame suction flow path 228F formed inside the frame holding portion 122F. The frame adsorption flow path 228F is formed vertically and communicates with the frame holding part connection flow path 230F. The frame holding part connection flow path 230F is formed in parallel with the frame suction surface 222FA and communicates with the wafer holding part connection flow path 230W. By sucking air from the frame holding portion connection flow path 230F, air in the frame suction flow path 228F is sucked and air in the wafer suction flow path 228W is sucked. Accordingly, air is sucked from the frame suction groove 226F of the frame holding unit 222F and air is sucked from the wafer suction groove 226W of the wafer holding unit 122W.

  The table plate holding frame 224 is formed in an annular shape. The table plate 222 is held on the inner periphery of the table plate holding frame 224.

  The table plate holding frame 224 is rotated about the θ axis by a rotation driving mechanism (not shown) and is moved up and down (Z direction) by a lifting driving mechanism (not shown). Moreover, while moving in the front-rear direction (Y direction) on the horizontal plane by a front-rear drive mechanism (not shown), it moves in the left-right direction (X direction) on the horizontal plane by a left-right drive mechanism (not shown). Furthermore, the front and back (up and down) is reversed by a front and back reversing mechanism (not shown) (for example, the front and back are reversed by rotating around the X axis).

  The table plate 222 rotates around the θ axis as the table plate holding frame 224 rotates. Further, the table plate holding frame 224 moves up and down as it moves up and down. Further, the table plate holding frame 124 moves back and forth by moving in the front-rear direction, and moves left and right by moving in the left-right direction. Further, when the table plate holding frame 224 is reversed, the front and back (up and down) are reversed.

  The table plate holding frame 224 is formed with a communication channel 234 that communicates with the frame holding unit connection channel 230F formed in the frame holding unit 222F. The communication channel 234 is formed horizontally and communicates with a wafer suction connection port 236 formed on the outer peripheral surface portion of the table plate holding frame 224.

  A flexible first suction tube 238 is connected to the wafer suction connection port 236 communicating with the wafer suction groove 226W and the frame suction groove 226F. On the other hand, a second suction pipe 262 is connected to a refractive liquid supply groove connection port (not shown) communicated with the inner peripheral end of the refractive liquid supply groove 250.

  Both the first suction pipe 238 and the second suction pipe 262 are connected to the separation tank 264. The first suction pipe 238 and the second suction pipe 262 are provided with valves 266 and 268, respectively (the valve 266 provided in the first suction pipe 238 is used as a wafer suction groove opening / closing valve 266, and The valve 268 provided in the suction pipe 262 is referred to as a refractive liquid supply groove opening / closing valve 268).

  When the liquid is sucked into the first suction pipe 238 and the second suction pipe 262, the separation tank 264 collects the sucked liquid (separates gas and liquid). The separation tank 264 is connected to the vacuum pump 240 via the third suction pipe 270.

  The driving of the vacuum pump 240 and the opening / closing of the wafer suction groove opening / closing valve 266 and the refractive liquid supply groove opening / closing valve 268 are controlled by a control device (not shown). By opening the wafer suction groove opening / closing valve 266 and driving the vacuum pump 240, air is sucked from the wafer suction groove 226W and the frame suction groove 226F. Further, the refractive liquid supply groove opening / closing valve 268 is opened and the vacuum pump 240 is driven, whereby air is sucked from the refractive liquid supply groove 250. At this time, when the liquid is sucked, the liquid is collected in the separation tank 264.

  A waste liquid pipe 272 is connected to the separation tank 264. A waste liquid pipe opening / closing valve 274 is installed in the waste liquid pipe 272, and the liquid recovered in the separation tank 264 is discharged from the separation tank 264 by opening the waste liquid pipe opening / closing valve 274.

  A refracting liquid supply pipe 276 having flexibility is connected to the refracting liquid supply port 260 communicated with the outer peripheral end of the refracting liquid supply groove 250.

  The refractive liquid supply pipe 276 is connected to one connection port of the three-way valve 278. An atmosphere release pipe 280 and a tank connection pipe 282 are connected to the remaining two connection ports of the three-way valve 278, respectively. The three-way valve 278 opens and closes each connection port individually. Therefore, the pipes connected to the connection ports can be arbitrarily combined and communicated.

  The other end of the atmosphere release pipe 280 is opened to the atmosphere.

  The tank connection pipe 282 is connected to the refractive liquid storage tank 284 (connected to the bottom). The refractive liquid storage tank 284 stores the refractive liquid. At the ceiling of the refracted liquid storage tank 284, there are a refracted liquid supply port 286 for putting the refracted liquid into the refracted liquid storage tank 284, and a pressure adjusting pipe 290 for adjusting the pressure in the refracted liquid storage tank 284. Connected.

  The refractive liquid supply port 286 is provided with a plug 288 so that the inside of the refractive liquid storage tank 284 can be sealed.

  The other end of the pressure adjustment pipe 290 is opened to the atmosphere, and a gauge 292 and a pressure adjustment valve 294 are installed in the middle. The pressure detected by the gauge 292 is output to a control device (not shown). The control device controls the pressure adjustment valve 294 based on the pressure detected by the gauge 292, and controls the pressure in the refractive liquid storage tank 284.

  Opening and closing of the three-way valve 278 is controlled by a control device (not shown). The refractive liquid supply groove 250 is opened to the atmosphere by controlling the three-way valve 278 so that the refractive liquid supply pipe 276 and the atmospheric release pipe 280 communicate with each other. Further, the refractive liquid supply pipe 276 and the tank connection pipe 282 are communicated, so that the refractive liquid stored in the refractive liquid storage tank 284 can be supplied to the refractive liquid supply groove 250.

  The wafer table 220 of the present embodiment is configured as described above.

<Action>
The wafer W is held by the wafer table 220 of the present embodiment as follows.

  The wafer W mounted on the dicing frame F is transferred to the lower part of the wafer table 220 by a transfer device (not shown) (for example, a robot arm). At this time, the wafer W is transported to the lower position of the wafer table 120 with the surface to which the dicing tape T is attached facing upward and the surface being in a non-contact state.

  The wafer W transferred to the lower position of the wafer table 120 is transferred from the transfer device to the wafer table 120. The delivery is performed by sucking and holding the back surface of the wafer W by the wafer suction surface 222WA of the wafer table 220 and holding the dicing frame F by the frame suction surface 222FA of the wafer table 120. Specifically, this is performed as follows.

  First, the wafer W is positioned. That is, the wafer W is positioned so that the center of the wafer W coincides with the center of the wafer table 220. Thereafter, the wafer suction surface 222WA and the frame suction surface 222FA of the wafer table 220 are brought into contact with the back surface of the wafer W and the back surface of the dicing frame F.

  Next, the wafer suction groove opening / closing valve 266 and the refractive liquid supply groove opening / closing valve 268 are opened, and the vacuum pump 240 is driven. At this time, all the three-way valves 278 are closed (all the pipes connected to the three-way valve 278 are disconnected).

  By driving the vacuum pump 240 with all the three-way valves 278 closed, the wafer suction groove 226W, the frame suction groove 226F, and the refractive liquid supply groove 250 are vacuumed. As a result, the peripheral portion of the wafer W portion of the wafer W mounted on the dicing frame F is sucked into the wafer suction groove 226W, and the dicing frame F portion is sucked into the frame suction groove 226F. Further, as described above, since the refractive liquid supply groove 250 is also sucked, the wafer W is also sucked by the portion of the refractive liquid supply groove 250.

  When the wafer suction groove 226W, the frame suction groove 226F, and the refractive liquid supply groove 250 are vacuumed, the wafer suction groove opening / closing valve 266 and the refractive liquid supply groove opening / closing valve 268 are closed, and the vacuum pump 240 is driven. Is stopped. As a result, the peripheral edge of the wafer W is sucked and held on the wafer suction face 222WA, and the dicing frame F is sucked and held on the frame suction face 222FA. In addition, the portion of the wafer W placed in the refractive liquid supply groove 250 is sucked and held by the wafer suction surface 222WA (the inside of the refractive liquid supply groove 250 is in a decompressed state).

  Next, the three-way valve 278 is driven, and the refractive liquid supply pipe 276 and the tank connection pipe 282 are communicated. As a result, the refractive liquid supply groove 250 and the refractive liquid storage tank 284 communicate with each other. At this time, the pressure in the refractive liquid storage tank 284 is controlled to a predetermined pressure (the degree of vacuum is slightly lowered (increased)). For example, the degree of vacuum is 50 [Torr] or less, or 100 [Torr] or less. As a result, the refractive liquid stored in the refractive liquid storage tank 284 is sucked toward the refracted refractive liquid supply groove 250, and the entire refractive liquid supply groove 250 is filled with the refractive liquid (refractive liquid storage tank). The inside of 284 is maintained at a slightly higher positive pressure than the refractive liquid supply groove 250, and when the refractive liquid supply groove 250 and the refractive liquid storage tank 284 communicate with each other, the refractive liquid stored in the refractive liquid storage tank 284 is decompressed. The refraction liquid supply groove 250 is sucked toward the refraction liquid supply groove 250, and the whole refraction liquid supply groove 250 is filled with the refraction liquid.

  Here, as described above, the wafer W is sucked and held on the wafer suction surface WA by vacuum suction, but between the wafer suction surface 222WA (the dicing tape T1 attached to the wafer W and the wafer suction). When there is a gap between the surface 222WA and the surface 222WA, the refractive liquid supplied to the refractive liquid supply groove 250 flows into the gap. Thereby, the gap is filled with the refractive liquid.

  When the refractive liquid supply groove 250 is filled with the refractive liquid as described above, the three-way valve 278 is driven, and the refractive liquid supply pipe 276 and the tank connection pipe 282 are disconnected (the refractive liquid supply groove 250 is Closed.)

  Thus, the suction holding of the wafer W is completed. Thereafter, a laser dicing process is performed.

  As described above, according to the wafer table 220 of the present example, when a gap is generated between the wafer W and the wafer suction surface 222WA, the refractive liquid can be poured into the gap.

  Here, when the refractive index of the refractive liquid filled in the refractive liquid supply groove 250 and the refractive index of the wafer holding part 222W are almost the same, the interface does not exist, and the laser beam is transmitted without being scattered as it is. To do. Therefore, even when the laser beam is irradiated, the wafer W can be irradiated with an extremely high transmittance.

  Further, by pouring the refractive liquid into the gap, the wafer W is also sucked by the interface tension of the liquid and held on the wafer table. At this time, the intervening liquid is also made very thin to the extent that the interfacial tension acts, so that the thickness becomes uniform and the distance between the wafer W and the laser irradiation apparatus can be kept constant.

  When the liquid is allowed to stand on the solid, it may become a ball due to surface tension, but by interposing the liquid between the solids (wafer and wafer table) as in this embodiment, Interfacial tension can be utilized more effectively. Moreover, since no gas is interposed, variations due to droplet formation due to the surface tension of the liquid can be suppressed.

  In addition, if the back surface of the wafer (surface to be attracted (surface irradiated with laser)) is roughened by grinding marks, etc., or if there is roughness on the wafer attracting surface of the wafer table, Laser light may be scattered on the back surface of the wafer, and the amount of effective laser light entering the inside of the wafer W may be very small, or other portions that should not be irradiated with laser light may cause laser burn due to scattering. However, by interposing a liquid between the wafer and the wafer table, the scattering due to the micro-roughness formed on the back surface of the wafer can be greatly reduced, and the transmittance of the laser light into the wafer can be reduced. Can be increased.

  In addition, a liquid such as water generally has a higher refractive index than a gas such as air. Here, assuming that the refractive index of the medium is n0 and the refractive index of the reflecting surface is n1, the reflectance R when light is vertically incident is represented by R = (n0−n1) 2 / (n0 + n1) 2. Is done.

  For example, in the case of a silicon wafer, if a natural oxide film is formed on the surface, the refractive index of the surface is about 1.46. Since the refractive index of air is 1, while the refractive index of water is about 1.3, the difference in refractive index is smaller when a liquid such as water is used. As a result, it is possible to significantly reduce the reflectance from the above reflectance formula, and it is possible to introduce the laser beam into the wafer W more efficiently.

  In order to facilitate the pouring of the refractive liquid, it is preferable that the surface of the wafer table (wafer adsorption surface) is intentionally roughened and clouded. As a result, the refracting liquid becomes familiar and easily enters the gap.

  As a method for roughening the surface of the wafer table, for example, when the surface is formed of quartz glass, the surface is intentionally roughed with a file having a count of about # 324- # 500, and a fine roughness of about 1 μm to 10 μm is obtained. It is good to form.

  By roughening the surface (wafer adsorption surface) in this way, it is possible to make the refractive liquid easily flow into the adsorption bonding interface after the wafer is evacuated. This also allows the refractive liquid to flow with a uniform thickness due to the interfacial tension, thereby further increasing the permeability.

  As the refracting liquid, for example, water or the like can be used, but alcohols such as ethanol and IPA may also be used. When quartz glass is used as the table plate, the refractive index is about 1.46. Further, the natural oxide film formed on the silicon substrate irradiated with the laser light also has a refractive index of about 1.46. Further, the refractive index of the polyethylene-based transparent film used as the dicing tape T is about 1.5. Therefore, if a liquid having a refractive index close to this is interposed at the interface, the laser beam can be transmitted with almost no reflection in theory.

  In the above example, the refractive liquid supply groove 250 is used to flow the refractive liquid into the gap, but the method of interposing the refractive liquid between the wafer and the wafer suction surface is limited to this. It is not a thing. In addition, for example, a refractive liquid can be interposed between the wafer and the wafer suction surface by the following method. That is, before the wafer is sucked and held by the wafer table, the refractive liquid is supplied to the sucked surface of the wafer and / or the sucking surface of the wafer table by dropping, spraying, applying, or the like. After the supply, the wafer is vacuum-sucked and held with the refractive liquid interposed between the wafer suction surface and the wafer. Thereby, a refracting liquid can be interposed between the wafer and the wafer suction surface. In this case, means (dropping means, coating means, spraying means, etc.) for supplying the refracting liquid by dropping or the like is provided on the surface to be attracted to the wafer and / or the attracting surface of the wafer table.

<< Cleaving after laser dicing >>
<First Embodiment of Cleaving Process>
The wafer W diced by the laser dicing apparatus 10 (110) is applied with external stress and divided (divided) into chips. This process is performed by a cleaving device, for example.

  FIG. 16 is a process diagram illustrating an outline of the cleaving process performed by the cleaving apparatus.

  The laser-diced wafer W is placed on the cleaving table 300 with the surface facing up, as shown in FIG. Further, the dicing frame F is fixed at a predetermined position by a frame fixing mechanism (not shown).

  When the wafer W is placed on the cleaving table 300 and the dicing frame F is fixed, as shown in FIG. 4B, the expanding W is arranged so as to surround the peripheral portion of the cleaving table 300. The ring 302 is pushed up by an elevating mechanism (not shown) and rises. As a result, the dicing tape T attached to the back side of the wafer W is radially expanded. When the dicing tape T is expanded, an external stress is applied to the wafer W, and the wafer W is cleaved and divided starting from the deteriorated layer. Since the altered layer is formed along the street S, the wafer W is cleaved along the street S. Since the street S is set between individual chips, the wafer W is divided into individual chips.

  Thus, the laser-diced wafer W is divided into individual chips by applying external stress.

<Second Embodiment of Cleaving Process>
The dicing tape used in the laser dicing apparatus 10 (110) of the above embodiment is required to have sufficient transparency with respect to laser light. On the other hand, in consideration of the cleaving process after laser dicing, the dicing tape is required to have a property of excellent stretchability. Although such a dicing tape does not exist, it is difficult to satisfy both of them when the homogeneity of refractive index is strictly considered. Especially for dicing that has high anisotropy with a uniform refractive index and no anisotropy with respect to laser light, and has no anisotropy with respect to elastic deformation when it is further cleaved. The tape is hardly found at present. In the case of a tape material, the greater the spreadability, the more the molecules are entangled in a chain, and in such a configuration, in principle, the degree of light scattering within the material is high, and refraction This is because the rate variation tends to increase.

  Even if the dicing tape is not stretchable or spreadable, the wafer can be cleaved after laser dicing by the following method as long as the dicing tape has a characteristic of transmitting laser light very well. That is, after laser dicing, the wafer is attached to a thick cleaving tape (the cleaving tape is applied from above the dicing tape), and the wafer is expanded and cleaved. Thus, the wafer after laser dicing can be divided even if the dicing tape does not have stretchability or spreadability.

  As the thick cleaving tape used here, a rubber material or the like can be used. For example, SBR (silicon butadiene rubber), NBR (nitrile butadiene rubber), or the like can be suitably used. As the thickness, a thick rubber of about 1 mm or 2 mm may be used. An adhesive material, double-sided tape, or the like is pasted on the rubber surface in advance so that the dicing tape is firmly held.

  In addition, when affixing to the cleaving tape and cleaving in this way, the dicing tape does not matter whether it is stretchable or spreadable, so it is a tape that has a property of transmitting laser light very well, that is, it is thin and refracted. Any tape with a uniform rate can be used. The tape having a uniform refractive index is, for example, a polyester-based or polyolefin-based thin tape.

  In addition, if possible, the dicing tape has the property of transmitting laser light very well, while being embrittled by irradiating with ultraviolet light, embrittled by heating, and cooled. It is more preferable to have a characteristic of embrittlement due to some change in physical characteristics, such as an embrittlement type. When dicing a wafer that has been diced using such a dicing tape, after laser dicing, the wafer is affixed to a thick cutting tape to change the physical characteristics of the dicing tape. Embrittle. For example, in the case of a dicing tape that is embrittled by irradiating with ultraviolet rays, the dicing tape is embrittled by irradiating the dicing tape with ultraviolet rays, and dicing tape that is embrittled by heating. The tape is made brittle by heating. In the case of a dicing tape that becomes brittle when cooled, the dicing tape is cooled and embrittled. In this way, after the dicing tape is embrittled, it is expanded to break the wafer. Thus, the wafer can be efficiently broken together with the dicing tape. If there is no tape of this type, it may be a thin transparent tape (about 20 μm) that can support the wafer.

  Moreover, when affixing a wafer on the cleaving tape, it is preferable to provide a small vent in advance in the cleaving tape and affix the wafer to the cleaving tape while evacuating. Thereby, a wafer can be affixed on the tape for cleaving efficiently.

<Third embodiment of cleaving process>
As described above, the wafer can be cleaved even if the dicing tape does not have stretchability or spreadability by being attached to a thick cleaving tape and expanded after laser dicing. When this cleaving process is performed, the wafer can be efficiently cleaved by bending the wafer while vacuum-sucking the back surface (tape adhering surface) of the wafer.

  FIG. 17 is a schematic configuration diagram of a cleaving apparatus that cleaves a wafer while vacuum suctioning.

  As shown in the figure, the cleaving device 310 includes a wafer chuck 312 that sucks and holds the wafer W, a frame chuck 314 that sucks and holds the frame, a pressing device 316 that presses and deflects the wafer chuck 312, and a tape. An expansion ring 318 is provided.

  The wafer chuck 312 is formed in a circular plate shape (disk shape) on which the wafer W can be placed. The wafer chuck 312 is formed so that it can be vacuum-sucked, and can be bent and deformed while holding the wafer W. It is formed. The wafer chuck 312 is made of a flexible plate (for example, about 2 mm), has a plurality of suction holes formed on the surface (the mounting surface (suction holding surface) of the wafer W), and a spiral shape inside. The groove 312A is formed. A wafer suction vacuum pump 322 is connected to the spiral groove 312A formed inside via a suction line 320. By driving the wafer suction vacuum pump 322, air is sucked from the suction holes formed on the surface, and the wafer W placed on the surface is sucked and held.

  The frame chuck 314 is formed in an annular shape and is disposed so as to surround the periphery of the wafer chuck 312. The wafer W placed on the wafer chuck 312 has a frame portion placed on the wafer suction surface (upper surface) of the frame chuck 314. A plurality of suction holes are formed at a constant pitch on the wafer suction surface. When a frame suction vacuum pump (not shown) is driven, air is sucked from the suction holes to suck and hold the mounted frame.

  The pressing device 316 is composed of, for example, a cylinder, and vertically presses the center of the lower surface of the wafer chuck 312 with a pressing pad 324 attached to the tip of the rod to bend the wafer chuck 312. The pressure pad 324 has a hemispherical tip, and moves forward and backward vertically with respect to the lower surface of the wafer chuck 312.

  The expanding ring 318 is disposed between the wafer chuck 312 and the frame chuck 314 and is disposed so as to surround the peripheral portion of the wafer chuck 312. The expanding ring 318 is pushed up by a lifting mechanism (not shown) and moves up. As the expand ring 318 is raised, the tape attached to the wafer W is expanded (stretched) radially. Thereby, the wafer W is divided | segmented.

  The wafer cleaving process by the cleaving apparatus 310 configured as described above is performed as follows.

  First, the wafer W after laser dicing is attached to a cleaving tape. Here, similarly to the dicing tape, the cleaving tape is attached to an annular frame. This frame has the same configuration as the dicing frame. In the following, in order to distinguish between the dicing tape and the cleaving tape, the dicing tape is denoted as T1, and the cleaving tape is denoted as T2. In addition, a frame (dicing frame) to which the dicing tape T1 is attached is described as F1, and a frame (cutting frame) to which the cutting tape T2 is attached is described as F2. For example, the cleaving frame F2 is stocked in a cassette or the like in a state where a cleaving tape is applied, and is supplied by a cleaving frame supply device (not shown).

  The wafer W is attached to the cleaving tape T2 as follows. First, as shown in FIG. 18A, the cleaving tape T2 is placed on the wafer chuck 312 with the sticking surface (the surface on which the adhesive layer is formed) facing up. Next, the cutting frame F <b> 2 is sucked and held by the frame chuck 314. Next, the wafer W is mounted on the cleaving tape T2 (the surface to be adhered (the surface on which the back surface of the wafer W (the surface on which the dicing tape T1 is adhered) is placed) is placed). As shown in FIG. 18B, the wafer W is attached to the cleaving tape T2.

  Here, when a tape having air permeability is used as the cleaving tape T2, the wafer W is attached while being sucked. That is, the wafer W is bonded to the cleaving tape T2 while driving the wafer suction vacuum pump 322. Thereby, the wafer W can be affixed to the cleaving tape T2 efficiently.

  The cleaving tape T2 can be provided with air permeability by, for example, forming a large number of small air holes.

  Next, the wafer suction vacuum pump 322 is driven, and the wafer W is sucked and held by the wafer chuck 312. In this state, the pressing device 316 is driven, and the pressing pad 324 is brought into contact with the center of the back surface of the wafer chuck 312 to bend the wafer chuck 312 as shown in FIG. Thereby, the wafer W can be cleaved efficiently. In other words, after the wafer W is vacuum-sucked and the surface is corrected by the wafer chuck 312, the wafer W is bent together with the wafer chuck 312, so that the wafer W can be made to follow the deflection of the wafer chuck 312. As a result, a uniform bending stress due to a constant bending displacement can be applied within the wafer surface, and the wafer can be divided without causing any remaining cracks.

  Thereafter, the adsorption of the wafer W by the wafer chuck 312 is released, and the expanding ring 318 is raised as shown in FIG. As a result, the cleaving tape T2 is extended (the dicing tape T1 is also extended), and the wafer W is divided into individual chips.

  In this example, the wafer frame portion is held by vacuum suction, but the configuration for holding the frame portion is not limited to this. In addition, for example, a configuration in which the frame portion is sandwiched and held (clamped) by a pair of clamping members may be employed.

<Other embodiments of the cleaving device>
FIG. 20 is a schematic configuration diagram showing another embodiment of the cleaving device.

  As shown in the figure, the cleaving device 310 is the above-described cleaving method in that the pressing pad 324 that presses the wafer chuck 312 is formed in a so-called saddle shape and the pressing device 316 is formed to be rotatable. Different from the device.

  The pressure pad 324 is medium-high and has a half-moon shape (so-called bowl shape) in cross section. The pressing device 316 is installed on a rotary table (not shown), and is provided to be rotatable about the center (center axis) of the pressing pad 324 as a rotation center. The rotary table rotates by being driven by a motor (not shown).

  When the motor is driven, the pressing pad 324 rotates by 90 degrees. As a result, the pressing pad 324 can take the first posture (FIG. 21A) and the second posture rotated by 90 degrees from the first posture (FIG. 21B).

  The wafer cleaving method by the cleaving apparatus 310 of this example is as follows.

  Usually, the division lines (streets) are formed in two orthogonal directions (X direction and Y direction). For this reason, in the cleaving apparatus 310 of this example, the pressing pad 324 is brought into contact with the wafer W in two times in the X direction and the Y direction, and the wafer W is cleaved.

  That is, first, the pressing pad 324 is pressed and brought into contact with the wafer W in the first posture (FIG. 21A), and then the pressing pad 324 is rotated by 90 degrees to obtain the second posture (FIG. 21B). ), The pressing pad 324 is pressed against the wafer W.

  Here, when the pressing pad 324 is brought into contact with the wafer W in the first posture (FIG. 21A), the direction of the arc of the pressing pad 324 (direction in which the cross section of the pressing surface becomes an arc) is the X direction. Set to be parallel to the planned division line. When the pressing pad 324 is brought into contact with the wafer W in the second posture (FIG. 21B), the arc direction of the pressing pad 324 is set so as to be parallel to the planned division line in the Y direction. . Thereby, the wafer W can be bent along the planned cutting line in the X direction formed on the wafer W at the first time, and the divided line along the Y direction formed on the wafer W can be bent the second time. The wafer W can be bent.

  In this way, the wafer W can be divided more efficiently by bending the wafer W twice along the division line.

  In the case of this example as well, the wafer W is bent while being sucked and held by the wafer chuck 312.

  When the wafer W is made to follow the pressing surface of the pressing pad 324 formed in a bowl shape without vacuum suction, if a part of the wafer W is cracked first, the wafer W bends sharply at the cracked part. Since the curvature of the pressing surface is absorbed by the cracked portion, the chip may not be bent partially and may follow the pressing surface while being stuck.

  However, after the wafer W is vacuum-sucked and the surface is corrected, the wafer chuck is bent together with the wafer chuck, so that each part in the wafer is copied while being sucked in accordance with the deflection of the wafer chuck 312. It is possible to apply a bending stress due to a certain bending displacement. Thereby, the wafer W can be divided | segmented, without producing a crack remainder.

  In the above embodiment, it has been described that the wafer is cleaved by expanding the thick tape for cleaving. However, as a method of cleaving, other than expanding and dividing the wafer, for example, the cleaving tape is bent. It is also possible to break the wafer by applying a bending stress to the wafer. In this case, it is also conceivable to divide the wafer with bending stress and then expand the chip to separate the chips from each other. Such means can take various methods depending on the wafer thickness and the Young's modulus of the wafer material.

《A series of processing from laser dicing to division》
Next, a flow of a series of processes from laser dicing using a laser dicing apparatus to division using a cleaving apparatus will be described with reference to FIGS.

  Here, the laser dicing apparatus 110 (FIG. 6) described in the second embodiment is used as the laser dicing apparatus, and the cutting described in the third embodiment of the cutting process described above is used as the cutting apparatus. A case where the apparatus 310 (FIG. 17) is used will be described as an example. In the case of the cleaving process, an example will be described in which the cleaving process is performed by attaching the wafer to the cleaving tape T2.

  First, as shown in FIG. 22A, the wafer W is mounted on the dicing frame F1. That is, the wafer W is attached to the dicing tape T1 attached to the dicing frame F1.

  As described above, during the cleaving process, the wafer W is attached to the cleaving tape T2, and the cleaving process is performed. Therefore, the dicing tape T1 used here is a thin transparent tape that can support the wafer W ( About 20 μm).

  Next, the wafer W mounted on the dicing frame F <b> 1 is set in the laser dicing apparatus 110. That is, the wafer W is positioned and delivered to the wafer table 120 by a transfer device (not shown), and is sucked and held on the wafer table 120.

  At this time, as shown in FIG. 22B, the wafer table 120 receives the wafer W with the wafer suction surface 122WA facing upward. After the wafer W is received by the wafer table 120, the vacuum pump 140 is driven, the wafer W is vacuum-sucked, and the dicing frame F1 is vacuum-sucked.

  If the wafer table 120 has a refractive liquid supply function, the refractive liquid is supplied to the gap between the wafer held by suction and the wafer table 120. As a result, the wafer W is held by the wafer table 120 by being sucked by the interfacial tension of the liquid.

  After attracting and holding the wafer W, the wafer table 120 is turned upside down. Thus, as shown in FIG. 22C, the wafer W is held vertically downward. In addition, this makes it possible to irradiate the back surface of the wafer W with laser light from the laser irradiation device 160 through the wafer table 120.

  After the wafer table 120 is inverted, a predetermined alignment process is performed, and dicing is started. As shown in FIG. 22D, dicing is performed by causing the laser light emitted from the laser irradiation device 160 to enter the wafer W along the street (division line). Laser light emitted from the laser irradiation device 160 is transmitted through the wafer table 120 and the dicing tape T, is incident on the wafer W, and forms a deteriorated layer. Since the wafer W is held on the wafer table 120 without being bent, the laser beam can be accurately incident on a predetermined position.

  When the laser beam is irradiated along all the streets, the dicing process ends. Thereafter, the wafer W is recovered from the wafer table 120. At this time, first, as shown in FIG. 22E, the wafer table 120 is turned upside down. As a result, the wafer W is held upward. Thereafter, the suction of the wafer W and the dicing frame F1 is released, and the wafer W is recovered from the wafer table 120 by a transfer device (not shown).

  Next, the cleaving process is executed.

  First, the laser-diced wafer W is attached to the cleaving tape T2. The cleaving tape T2 is affixed to the cleaving frame F2, and the cleaving tape T2 is affixed from above the dicing tape T1.

  Here, a thick tape having air permeability is used for the cleaving tape T2.

  The wafer W is attached to the cleaving tape T2 as follows. First, as shown in FIG. 23A, the cleaving tape T2 is placed on the wafer chuck 312 with the sticking surface (the surface on which the adhesive layer is formed) facing up. Next, the cutting frame F <b> 2 is sucked and held by the frame chuck 314. Next, the wafer W is placed on the cleaving tape T2 (the surface to be adhered (the back surface of the wafer W (the surface on which the dicing tape T1 is adhered) is placed downward)). Then, the wafer suction vacuum pump 322 is driven, whereby the wafer W is attached to the cleaving tape T2 while being sucked.

  In this way, by adhering the wafer W to the cleaving tape T2 while sucking the wafer W, the wafer W can be efficiently affixed to the cleaving tape T2.

  Next, with the wafer W being sucked and held, the pressing device 316 is driven, and the pressing pad 324 is pressed against the center of the back surface of the wafer chuck 312. Thereby, the wafer chuck 312 is bent as shown in FIG. When the wafer chuck 312 is bent, the wafer W is bent following the wafer chuck 312 and the wafer W is cut along the street. The wafer W is cleaved without causing any remaining cracks by being bent while being attracted and held by the wafer chuck 312.

  When the cleaving process of the wafer W is completed, the pressing by the pressing pad 324 is released. Thereafter, the adsorption of the wafer W by the wafer chuck 312 is released.

  When the adsorption of the wafer W is released, as shown in FIG. 23D, the expanding ring 318 is raised and the cleaving tape T2 is extended (the dicing tape T1 is also extended). As a result, the wafer W is divided into individual chips.

  The wafer is divided into chips in the series of steps described above. Thereafter, the expanding ring 318 is retracted to the original position, the suction of the frame chuck 314 is released, and the wafer W is recovered.

  As the dicing tape T1, a tape having a characteristic that becomes brittle due to some change in physical characteristics (for example, a type that becomes brittle when irradiated with ultraviolet rays, a type that becomes brittle when heated, and a cooling type) In the case of using a tape embrittled by (1), the wafer W is attached to the cleaving tape T2, the dicing tape T1 is embrittled, and then the wafer is cleaved. Thereby, the wafer can be broken together with the dicing tape, and the wafer can be cleaved more efficiently.

  When a series of processing from laser dicing to division is performed continuously (when configured as a wafer processing system that performs a series of processing from laser dicing to division), for example, a laser dicing apparatus and a cleaving apparatus are arranged in parallel. It is configured so that a wafer that has been laser-diced by a laser dicing device is automatically transported to a cleaving device (for example, a wafer after laser dicing is recovered from the laser dicing device by a transport means such as a robot arm). , Configured to be conveyed to the cleaving device.)

[Example]
<About the wafer table>
Quartz glass is preferably used as the transparent table plate constituting the wafer table. For example, ES grade quartz glass manufactured by Tosoh Corporation or ED-C grade quartz glass with reduced absorption in the infrared region is preferably used.

  Further, even if the table plate is not made of quartz glass, single crystal silicon, germanium crystal, or the like is excellent in transmittance and can be suitably used particularly when an infrared laser is used.

  The thickness of quartz glass depends on the objective lens used in the laser irradiation apparatus, but since the work distance is about 1 to 3 mm, a thickness of about 1 mm to 2 mm is sufficient for quartz glass. It is.

<About refractive liquid>
In the case where the refractive liquid is poured into the gap between the wafer and the table plate, for example, water is suitably used as the refractive liquid. In addition, alcohols such as ethanol and IPA may be used.

  When quartz glass is used as the table plate, the table plate has a refractive index of about 1.46. When the processing target is a silicon wafer, the natural oxide film formed on the surface of the wafer also has a refractive index of about 1.46. In addition, a polyethylene-based transparent film used as a dicing tape has a refractive index of about 1.5. Therefore, if a liquid having a refractive index close to this is interposed at the interface, it can be transmitted with little reflection in theory. As such a refracting liquid, those having a refractive index of about 1.5, Cargill standard refracting liquid series A, series AA, etc. manufactured by Moritex Corporation are preferably used.

<Processing conditions for laser dicing>
As processing conditions of the laser dicing embodiment, for example, the following conditions are preferably used.

Laser light source: semiconductor laser excitation Nd: YAG laser (wavelength: 1064 nm)
Laser beam spot diameter: 2 μm
Oscillation form: Q switch pulse Repetition frequency: 100 kHz
Sample stage moving speed: 1100 mm / sec Pulse interval: 1 μm
Pulse width: 150ns
Output: 6.5 μJ / pulse Condensing lens: 50 times magnification, NA: 0.55
<About dicing tape>
As for the dicing tape, it is desirable that the transmittance with respect to laser light is about 80% or more. As a material for such a tape, a polyester, polyolefin or polyurethane material can be suitably used. For example, the film thickness may be about 200 μm, but if it is 50 μm or less, the transmittance can be further improved.

  For example, when irradiating a silicon wafer, a long wavelength region of about 1064 nm to about 1300 nm is used. Therefore, in such a wavelength region, if the transmittance is at least about 70% or more, it can be suitably used. .

  As a base material for such a dicing tape, PET film “E5100-100” manufactured by Toyobo Co., Ltd., polyethylene “NUC-8122” manufactured by Nippon Unicar Co., Ltd., polycarbonate film “Panlite (registered trademark)” manufactured by Teijin Chemicals Ltd. ) "Etc. are excellent in permeability and can be preferably used.

  DESCRIPTION OF SYMBOLS 10 ... Laser dicing apparatus, 20 ... Wafer table, 22 ... Table board, 22A ... Wafer adsorption surface, 24 ... Table board holding frame, 26 ... Wafer adsorption hole, 28 ... Annular flow path, 30 ... Connection flow path, 32 ... Connection Channel communication port, 34 ... Communication channel, 36 ... Connection port, 38 ... Suction pipe, 40 ... Vacuum pump, 42 ... Wafer suction hole, 44 ... Central space, 46 ... Central communication channel, 50 ... Laser reflection preventing plate , 60 ... laser irradiation device, 62 ... laser oscillation device, 64 ... collimator lens, 66 ... condenser lens, 68 ... actuator, 110 ... laser dicing device, 120 ... wafer table, 122 ... table plate, 122F ... frame holding unit, 122FA ... Frame suction surface, 122W ... Wafer holder, 122WA ... Wafer suction surface, 124 ... Table plate holding surface 126F ... Frame suction hole, 126W ... Wafer suction hole, 128F ... Frame suction annular flow path, 128W ... Wafer suction annular flow path, 130F ... Frame holding part connection flow path, 130W ... Wafer holding part connection flow path 132W: Wafer holding part connection flow path communication port, 132FA: Frame holding part inner peripheral side connection flow path communication port, 132FB: Frame holding part outer peripheral side connection flow path communication port, 132W ... Wafer holding part connection flow path communication port, 134 ... Communication flow path, 136 ... Connection port, 138 ... Suction pipe, 140 ... Vacuum pump, 142 ... Wafer suction hole, 144 ... Central space, 146 ... Central communication flow path, 150 ... Laser reflection preventing plate, 160 ... Laser irradiation device , 220 ... wafer table, 222 ... table plate, 222F ... frame holding part, 222FA ... frame suction surface, 222W ... Wafer holding part, 222WA ... wafer adsorption surface, 224 ... table plate holding frame, 226F ... frame adsorption groove, 226W ... wafer adsorption groove, 228F ... frame adsorption channel, 228W ... wafer adsorption channel, 230F ... frame holding part Connection flow path, 230W ... wafer holding part connection flow path, 234 ... communication flow path, 236 ... wafer suction connection port, 238 ... first suction pipe, 240 ... vacuum pump, 250 ... refractive liquid supply groove, 252 ... refraction Liquid supply groove suction flow path, 254... Refraction liquid supply groove communication flow path, 256. Refraction liquid supply flow path, 258. Refraction liquid supply groove communication flow path, 260... Refraction liquid supply port, 262. Suction tube, 264 ... separation tank, 266 ... wafer suction groove opening / closing valve, 268 ... refractive liquid supply groove opening / closing valve, 270 ... third suction tube, 272 ... waste liquid tube, 274 ... Waste liquid pipe opening / closing valve, 276 ... refractive liquid supply pipe, 278 ... three-way valve, 280 ... atmospheric release pipe, 282 ... tank connection pipe, 284 ... refractive liquid storage tank, 286 ... refractive liquid supply port, 288 ... plug, 300 ... cleaving Table ... 302 ... Expanding ring, 310 ... Cleaving device, 312 ... Wafer chuck, 312A ... Groove, 314 ... Frame chuck, 316 ... Pressing device, 318 ... Expanding ring, 320 ... Suction line, 322 ... Vacuum for wafer adsorption Pump, 324 ... Pressing pad, F (F1) ... Dicing frame, T (T1) ... Dicing tape, F2 ... Cleaving tape, T2 ... Cleaving frame, L ... Modified layer, S ... Street, W ... Wafer

Claims (2)

A plate that is formed in a disk shape corresponding to the wafer to be processed, is formed with a uniform thickness by a material that can transmit laser light, and holds one surface of the wafer in close contact with one surface. When,
A laser irradiating means for making a laser beam incident on the one surface of the wafer through the plate from a position separated from the one surface of the plate as a reference, and forming a modified layer inside the wafer; ,
A laser dicing apparatus comprising: Hold one surface of the wafer in close contact with one surface of a plate that is formed in a disc shape corresponding to the wafer to be processed and is made of a material that can transmit laser light with a uniform thickness. And
A laser beam is incident on the one side surface of the wafer through the plate from a position separated from the one side surface of the plate as a reference, thereby forming a modified layer inside the wafer. Laser dicing method.

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