Source: https://patents.google.com/patent/KR20120107536A/en
Timestamp: 2020-04-09 23:00:18
Document Index: 377717100

Matched Legal Cases: ['art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 72', 'art 71', 'art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 16', 'art 71', 'art 71', 'art 72']

KR20120107536A - Laser processing method and semiconductor chip - Google Patents
Laser processing method and semiconductor chip Download PDF
KR20120107536A
KR20120107536A KR1020127024408A KR20127024408A KR20120107536A KR 20120107536 A KR20120107536 A KR 20120107536A KR 1020127024408 A KR1020127024408 A KR 1020127024408A KR 20127024408 A KR20127024408 A KR 20127024408A KR 20120107536 A KR20120107536 A KR 20120107536A
KR1020127024408A
KR101336402B1 (en
겐시 후쿠미츠
2004-03-30 Priority to JP2004100931 priority Critical
2004-03-30 Priority to JPJP-P-2004-100931 priority
2005-03-25 Application filed by 하마마츠 포토닉스 가부시키가이샤 filed Critical 하마마츠 포토닉스 가부시키가이샤
2005-03-25 Priority to PCT/JP2005/005552 priority patent/WO2005098915A1/en
2012-10-02 Publication of KR20120107536A publication Critical patent/KR20120107536A/en
2013-12-04 Publication of KR101336402B1 publication Critical patent/KR101336402B1/en
Provided is a laser processing method that enables high precision cutting of the substrate and the laminated portion even when the substrate on which the laminated portion including the plurality of functional elements is formed is thick.
In this laser processing method, the rear surface 21 is used as a laser beam incidence surface, and the modified regions 71, 72, and 73 are irradiated with the substrate 4 by irradiating the laser beam L with the light converging point P inside the substrate 4. Form inside of. At this time, the quality modified region 71 is formed at a position where the distance between the surface 3 of the substrate 4 and the surface side end portion of the quality modified region 71 becomes 5 µm to 15 µm. When the quality modified region 71 is formed at such a position, the laminated portion 16 (herein, the interlayer insulating films 17a and 17b) formed on the surface 3 of the substrate 4 is also cut along with the substrate 4. It can cut with good precision along a predetermined line.
LASER PROCESSING METHOD AND SEMICONDUCTOR CHIP}
The present invention relates to a laser processing method used for cutting a substrate on which a laminated portion including a plurality of functional elements is formed, and a semiconductor chip cut by use of such a laser processing method.
As a conventional technique of this kind, by irradiating a laser beam with a focusing point inside a wafer-like object to be processed, a plurality of rows of modified regions along a cutting scheduled line are formed inside the object to be cut, and the modified region is cut. There is a laser processing method that is referred to as a starting point (see Patent Document 1, for example).
The laser processing method as described above is a technique that is particularly effective when the object to be processed is thick. In connection with such a technique, there has been a demand for a technique in which a substrate on which a laminated portion including a plurality of functional elements is formed is a processing object, and even when the substrate is thick, high precision cutting of the substrate and the laminated portion is possible.
Herein, the present invention has been made in view of such a point, and a laser processing method that enables high-precision cutting of the substrate and the lamination part even when the substrate on which the lamination part including the plurality of functional elements is formed is thick, and such a laser processing method An object of the present invention is to provide a semiconductor chip that has been cut by use of.
In order to achieve the above object, the laser processing method according to the present invention cuts along a cutting schedule line of a substrate by irradiating a laser beam with a focusing point inside a substrate on which a laminate including a plurality of functional elements is formed on a surface thereof. A laser processing method for forming a modified region serving as a starting point in a substrate, and forming a first modified region along a cutting schedule line at a position where the distance between the surface and the surface-side end portion is between 5 μm and 15 μm. And forming at least one row of second reformed regions along the cutting scheduled line at a position between the first reformed region and the back surface.
Moreover, the laser processing method which concerns on this invention is a modification which becomes a starting point of cutting along the cutting | disconnection scheduled line of a board | substrate by irradiating a laser beam with the condensing point in the inside of the board | substrate with which the laminated part containing several functional elements was formed in the surface. It is a laser processing method which forms an area | region inside a board | substrate, and cut | disconnects in the position where the distance of a surface and a surface side edge part becomes [(thickness of a board | substrate) x 0.1] micrometer-[20+ (thickness of a board | substrate) x 0.1] micrometer. Forming a first modified region along the predetermined line, and forming at least one row of the second modified region along the scheduled cutting line at a position between the first modified region and the back surface of the substrate. Characterized in that.
In this laser processing method, for example, when an expandable film such as an extension tape is attached to the back surface of the substrate and expanded, cracking along the cutting schedule line occurs based on the first modified region and the second modified region. Therefore, even when the substrate is thick, the substrate can be cut with good accuracy along the cutting schedule line. At this time, the distance between the surface of the substrate and the front end of the first modified region is 5 µm to 15 µm, or the distance between the surface of the substrate and the rear end of the first modified region is [( When the first modified region is formed at a position of (thickness of the substrate) x 0.1] m to [20 + (thickness of the substrate) x 0.1] m, the laminated portion formed on the surface of the substrate can also be cut with good precision along the cutting scheduled line. Can be. Therefore, such a laser processing method enables high precision cutting of a board | substrate and a laminated part, even when the board | substrate with a laminated part containing a some functional element is thick.
Here, the functional element means, for example, a semiconductor operation layer formed by crystal growth, a light receiving element such as a photodiode, a light emitting element such as a laser diode, a circuit element formed as a circuit, or the like. In addition, the distance means the distance along the thickness direction of a board | substrate unless it has a special objection (it is the same below). Further, the first modified region and the second modified region are formed by irradiating a laser beam with a focusing point inside the substrate, thereby causing multiphoton absorption or equivalent light absorption within the substrate.
Moreover, in the former laser processing method, it is preferable to form a 1st modified region in the position where the distance of the surface of a board | substrate and the surface side edge part of a 1st modified region becomes 5 micrometers-10 micrometers. In the latter laser processing method, the distance between the surface of the substrate and the rear end portion of the first modified region is from [5 + (thickness of substrate) x 0.1] m to [20 + (thickness of substrate) x 0.1] m It is preferable to form a 1st modified area | region at a position, and a 1st modified area | region is made into the position where the distance becomes from [5+ (substrate thickness) x 0.1] micrometer-[10+ (substrate thickness) x 0.1] micrometer. It is more preferable to form. Thereby, the surface side edge part and the laminated part of a board | substrate can be cut | disconnected with more favorable precision along a cutting plan line.
In the above laser processing method, the substrate is a semiconductor substrate, and the first modified region and the second modified region may include a melt processing region. If the substrate is a semiconductor substrate, a modified region including a molten processed region may be formed as the first modified region and the second modified region.
Moreover, in the said laser processing method, it is preferable that the 1st modified area | region and the 2nd modified area | region are made into a laser beam incidence surface, and are formed one by one in order from the back surface. Thereby, when forming each modified region, since no modified region exists between the back surface (laser light incident surface) of a board | substrate and the condensing point of a laser beam, scattering absorption etc. of a laser beam by an already formed modified region may arise. none. Therefore, it is possible to form each modified region with good precision.
Moreover, in the said laser processing method, it is preferable that the energy of the laser beam at the time of forming a 1st modified area | region is 2 microJ-50 microJ. This is because when the first modified region is formed under such conditions, cleavage based on the first modified region tends to occur with good accuracy along the cutting scheduled line at the time of cutting the substrate and the laminate. When the energy of the laser beam is less than 2 µJ, the cleavage based on the first modified region at the time of cutting the substrate and the laminated portion is easily released from the cutting scheduled line and reaches the laminated portion. On the other hand, when the energy of a laser beam exceeds 50 microJ, damages, such as melt | fusion, will arise easily in a laminated part.
Moreover, in the said laser processing method, it is preferable that the energy of the laser beam at the time of forming a 2nd modified area | region is 1 microJ-50 microJ. This is because when the second modified region is formed under such conditions, cleavage from the second modified region as a starting point tends to occur with good accuracy along the cutting scheduled line when the substrate and the laminate are cut. In addition, when the energy of the laser beam is less than 1 µJ, it is difficult to generate a split based on the second modified region at the time of cutting the substrate and the laminate. On the other hand, when the energy of a laser beam exceeds 50 microJ, the cleavage which started from the 2nd modified area | region at the time of cutting | disconnection of a board | substrate and a laminated part will be easy to escape | deviate from a cutting plan line.
Moreover, in the said laser processing method, when forming a 2nd modified area | region, it is preferable that the distance from the back surface of the position which matches the light converging point of a laser beam is 50 micrometers-[(thickness of board | substrate) x 0.9] micrometer. This is because when the second modified region is formed under such conditions, it is possible to easily cut the substrate and the laminated portion even when the substrate is thick.
Moreover, in the said laser processing method, when forming a 2nd modified area | region, it is preferable that the distance from the back surface of the position which matches the light converging point of a laser beam is 20 micrometers-110 micrometers. This is because when the second modified region is formed under such conditions, the cleavage based on the second modified region tends to reliably reach the back surface of the substrate. When the distance from the back surface is less than 20 µm, damages such as melting and the like easily occur on the back surface of the substrate. On the other hand, when the distance from the back surface exceeds 110 µm, it is difficult to reach the back surface of the substrate when the second modified region is started.
Moreover, in the said laser processing method, you may further include the process of cutting | disconnecting a board | substrate and a laminated part along a cutting plan line. For the reason mentioned above, even when the board | substrate with a laminated part containing several functional elements is thick, a board | substrate and a laminated part can be cut | disconnected with favorable precision along a cutting plan line.
In addition, the semiconductor chip according to the present invention has a semiconductor chip including a substrate and a laminated portion formed on the surface of the substrate, including the functional elements, wherein the distance between the surface and the surface-side edge portion is 5 µm to 15 on the side surface of the substrate. A first modified region along the back surface of the substrate is formed at a position that is 占 퐉, and at least one row of second modified regions along the back surface is formed at a position between the first modified region and the back surface on the side of the substrate. It is characterized by that.
Moreover, the semiconductor chip which concerns on this invention WHEREIN: The semiconductor chip which has a board | substrate and the laminated part formed in the surface of a board | substrate including a functional element, WHEREIN: The distance of a surface and a back surface side end part is [ Of the first modified region along the back surface of the substrate, and at the side of the substrate, the first modified region and the first modified region At least one row of second reformed regions along the rear surface is formed at a position between the rear surface and the rear surface.
Since this semiconductor chip can be said to be cut | disconnected by the use of the said laser processing method, the side surface of the board | substrate with which the 1st modified area | region and the 2nd modified area | region was formed, and the side surface of a laminated part are high precision with unevenness suppressed. It is a cut surface of the figure.
Moreover, in the said semiconductor chip, a board | substrate is a semiconductor substrate and a 1st modified region and a 2nd modified region may contain a melt processing area. If the substrate is a semiconductor substrate, a modified region including a molten processed region may be formed as the first modified region and the second modified region.
Moreover, in the said semiconductor chip, the distance of the back surface side edge part of an opposing 1st modified area | region and the surface side edge part of a 2nd modified area | region is 0 micrometer-[(thickness of board | substrate)-(thickness of board | substrate) x 0.6] micrometer) Is preferably. If the first modified region and the second modified region are formed under such conditions, there is a tendency that, at the time of cutting the substrate and the laminate, the cleavage starting from each modified region is generated with good precision along the cutting scheduled line. It is because the side surface of the board | substrate of a semiconductor chip turns into a high precision cutting surface. Moreover, when the distance between the back surface side edge part of the opposing 1st modified area | region and the surface side edge part of a 2nd modified area | region exceeds [(thickness of a board | substrate)-(thickness of a board | substrate) x 0.6] micrometer), a board | substrate and a laminated part At the time of cutting | disconnection, it becomes difficult for the side surface of the board | substrate of a semiconductor chip to become a high precision cutting surface between a 1st modified region and a 2nd modified region.
The present invention enables high precision cutting of the substrate and the laminated portion, even when the substrate on which the laminated portion including the plurality of functional elements is formed is thick.
BRIEF DESCRIPTION OF THE DRAWINGS The top view of the process target object during laser processing by the laser processing method which concerns on this embodiment.
3 is a plan view of the object to be processed after laser processing according to the laser processing method according to the present embodiment.
FIG. 5 is a cross-sectional view taken along the line VV of the object to be processed shown in FIG. 3. FIG.
6 is a plan view of a processing object cut by the laser processing method according to the present embodiment.
7 is a graph showing the relationship between the electric field intensity and the magnitude of the crack spot in the laser processing method according to the present embodiment.
8 is a cross-sectional view of the object to be processed in the first step of the laser machining method according to the present embodiment.
9 is a cross-sectional view of the object to be processed in a second step of the laser machining method according to the present embodiment.
10 is a cross-sectional view of the object to be processed in a third step of the laser machining method according to the present embodiment.
11 is a cross-sectional view of the object to be processed in a fourth step of the laser machining method according to the present embodiment.
12 is a view showing photographs of a cross section in a portion of a silicon wafer cut by the laser processing method according to the present embodiment.
Fig. 13 is a graph showing the relationship between the wavelength of laser light and the transmittance inside the silicon substrate in the laser processing method of the present embodiment.
14 is a plan view of the object to be processed in the laser processing method of the present embodiment.
15 is a partial cross-sectional view taken along a line XV-XV of the object to be processed shown in FIG. 14.
FIG. 16 is a view for explaining the laser processing method of the present embodiment, (a) is a state in which a protective tape is applied to a processing object, and (b) is a view showing a state in which laser light is irradiated to a processing object.
Fig. 17 is a view for explaining the laser processing method of the present embodiment, (a) is a view showing a state in which an extension tape is applied to a workpiece, and (b) is a state in which ultraviolet rays are irradiated to a protective tape.
18 is a view for explaining the laser processing method of the present embodiment, (a) is a state in which the protective tape is peeled from the object to be processed, and (b) is a view in which the expansion tape is expanded.
19 is a partial cross-sectional view taken along a line XIX-XIX of the object to be processed shown in FIG. 16B.
20 is a diagram showing photographs of cut surfaces of substrates cut by use of the laser processing method of the present embodiment.
Fig. 21 is a diagram showing a photograph of the back surface of the substrate when the distance from the back surface of the position where the focus point of the laser light is aligned is 40 μm and the energy of the laser light is 20 μJ when forming the HC modified region.
Fig. 22 is a diagram showing a photograph of the back surface of the substrate when the distance from the back surface of the position where the focus point of the laser light is aligned is 15 µm and the energy of the laser beam is 10 µJ when the HC modified region is formed.
Fig. 23 is a table showing a relationship between the conditions for forming a quality modified region and the skirt width.
Fig. 24 is a diagram showing a photograph of a cut surface of a substrate in the case where the distance from the surface of the position where the focus point of the laser light is aligned is 3 µm and the energy of the laser beam is 15 µJ when forming the quality modification region.
25 is a diagram showing photographs of cut surfaces of substrates cut by use of the laser processing method of the present embodiment.
Fig. 26 is a plan view when the object to be processed is cut into a semiconductor chip, and (a) shows the case where the various modified conditions for the split reformed region are not satisfied in the formation of the split reformed region. The figure which shows the case where various formation conditions with respect to a division | segmentation modified area are satisfied.
Fig. 27 shows a photograph of a cut surface of a substrate on which a single row of quality modified regions, two rows of segmented modified regions, and a single row of HC modified regions are formed.
Fig. 28 shows a photograph of a cut surface of a substrate on which a single row of quality modified regions, two rows of segmented modified regions, and two rows of HC modified regions are formed.
Fig. 29 shows a photograph of a cut surface of a substrate on which a row of quality modified regions, a zone of 19 modified regions, and a column of HC modified regions are formed;
EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of this invention is described in detail with reference to drawings. In the laser processing method of the present embodiment, a phenomenon called multiphoton absorption is used to form a modified region inside the object to be processed. First, a laser processing method for forming a modified region by multiphoton absorption will be described.
When the absorption of energy than the band gap E G h υ of the photons of the material less is optically clear. Therefore, the condition under which absorption occurs in the material is h v > E G. However, even if it is optically transparent, absorption of the material occurs under conditions where nh υ > E G (n = 2, 3, 4, ...) when the intensity of the laser light is made very large. This phenomenon is called multiphoton absorption. In the case of a pulse wave, the intensity of the laser light is determined by the peak power density (W / cm 2) of the condensing point of the laser light. For example, multiphoton absorption occurs under the condition that the peak power density is 1 × 10 8 (W / cm 2) or more. . The peak power density is determined by (energy per pulse of laser light at the converging point) ÷ (beam spot cross-sectional area x pulse width of laser light). In the case of the continuous wave, the intensity of the laser beam is determined by the electric field intensity (W / cm 2) of the light converging point of the laser beam.
The principle of the laser processing method which concerns on this embodiment using such multiphoton absorption is demonstrated with reference to FIGS. As shown in FIG. 1, the cutting plan line 5 for cutting the process object 1 exists in the surface 3 of the process object 1 of a wafer shape (flat shape). The cutting plan line 5 is an imaginary line extending in a straight line shape. In the laser processing method which concerns on this embodiment, as shown in FIG. 2, the laser beam L is irradiated and the modified area | region 7 is formed in alignment with the condensing point P inside the process target object 1 on the conditions which multiphoton absorption arises. . In addition, the condensing point P is the position where the laser beam L condenses. In addition, the cutting plan line 5 is not limited to a straight line, but may be curved, and is not limited to an imaginary line, and may be a line actually attracted to the object 1 to be processed.
Then, the laser beam L is moved along the cutting schedule line 5 (ie, in the direction of the arrow A in FIG. 1) to move the light collection point P along the cutting schedule line 5. Thereby, as shown in FIGS. 3-5, the modified area | region 7 is formed in the inside of the process target object 1 along the cutting plan line 5, and this modified area | region 7 is a starting point area | region of a cutting | disconnection ( 8). Here, the cutting starting point region 8 means a region which becomes the starting point of cutting (disruption) when the object 1 is to be cut. This cutting origin region 8 may be formed by forming the reformed region 7 continuously, or may be formed by forming the reformed region 7 intermittently.
The laser processing method according to the present embodiment does not form the modified region 7 by generating heat of the processing target object 1 by absorbing the laser beam L. The laser beam L is transmitted through the object 1 to generate multiphoton absorption inside the object 1 to form the modified region 7. Therefore, since the laser beam L is hardly absorbed by the surface 3 of the object 1, the surface 3 of the object 1 does not melt.
When the starting point region 8 for cutting is formed inside the object 1, splitting tends to occur with the starting point region 8 as the starting point. As shown in FIG. 1) can be cut. Therefore, it becomes possible to cut | disconnect the process object 1 with high precision, without causing unnecessary division to the surface 3 of the process object 1.
The following two methods are considered to cut | disconnect the process object 1 which made this cutting origin region 8 the starting point. One is that artificial force is applied to the object to be processed 1 after formation of the starting point region 8, and the processing object 1 is cleaved by cutting the starting point region 8 as a starting point. to be. This is, for example, cutting when the thickness of the object 1 is large. The application of an artificial force is, for example, by applying a bending stress or shear stress to the workpiece 1 or by applying a temperature difference to the workpiece 1 according to the cutting origin region 8 of the workpiece 1. Will generate. The other is to form the starting point region 8 for cutting, so that the starting point region 8 is naturally broken toward the cross-sectional direction (thickness direction) of the object 1 as a starting point, and as a result, the object 1 is cut. to be. This becomes possible, for example, when the starting point region 8 is formed by a single row of modified regions 7 when the thickness of the object 1 is small, and the thickness when the thickness of the object 1 is large. It becomes possible that the cutting origin region 8 is formed by the modified region 7 formed in multiple rows in the direction. In addition, even in this case of naturally cleaving, the cleavage does not occur over the surface 3 of the portion corresponding to the portion where the cleavage origin region 8 is not formed at the position to be cut, and thus the cleavage origin region 8 Only the part corresponding to the site | part which formed () can be cut | disconnected, and cutting can be controlled well. In recent years, since the thickness of the processing object 1, such as a silicon wafer, tends to become thin, such a cutting method with such controllability is very effective.
However, in the laser processing method which concerns on this embodiment, as a modified area | region formed by multiphoton absorption, there may be the following (1)-(3).
(1) in the case of a crack region in which the modified region includes one or a plurality of cracks
The laser beam is focused on the inside of the object to be processed (for example, a piezoelectric material made of glass or LiTaO 3 ), and the laser beam is provided under a condition that the electric field intensity at the light collecting point is 1 × 10 8 (W / cm 2) or more and the pulse width is 1 dB or less. Irradiate light. The magnitude of the pulse width is a condition in which a crack region can be formed only inside the object to be processed without causing unnecessary damage to the surface of the object while causing multiphoton absorption. As a result, a phenomenon called optical damage due to multiphoton absorption occurs inside the object to be processed. This optical damage causes thermal damage inside the object to be processed, whereby a crack region is formed inside the object. As an upper limit of electric field intensity, it is 1 * 10 <12> (W / cm <2>), for example. The pulse width is preferably 1 ns to 200 ns, for example. In addition, the formation of the crack region by multiphoton absorption is described, for example, in pages 23 to 28 of the 45th Laser Thermal Processing Society Proceedings (December 1998). Marking ”.
The inventors obtained the relationship between the electric field strength and the size of cracks by experiment. The experimental conditions are as follows.
(A) Object to be processed: Pyrex (registered trademark) glass (700 µm thick)
Laser light spot cross section: 3.14 * 10 -8cm2
Repetition frequency: 100kHz
Polarization characteristic ： Linear polarization
Transmittance to laser light wavelength: 60 percent
(D) The moving speed of the mounting table on which the object is placed: 100 mm / s
In addition, the laser light quality of TEM 00 means that the light collecting property is high and the light can be collected up to the wavelength of the laser light.
7 is a graph showing the results of the experiment. The abscissa is the peak power density, and since the laser light is pulsed laser light, the electric field intensity is represented by the peak power density. The vertical axis | shaft has shown the magnitude | size of the crack part (crack spot) formed in the inside of a to-be-processed object by 1 pulse of laser beam. Crack spots gather to form a crack area. The size of the crack spot is the size of the portion of the shape of the crack spot that is the maximum length. The data represented by the black portion in the graph is a case where the magnification of the condensing lens C is 100 times and the numerical aperture NA is 0.80. On the other hand, the data represented by the white portion in the graph is a case where the magnification of the condensing lens C is 50 times and the numerical aperture NA is 0.55. It turns out that a crack spot generate | occur | produces in the inside of a to-be-processed object from the peak power density about 10 11 (W / cm <2>), and a crack spot also becomes large as peak power density becomes large.
Next, the mechanism of cutting of the object by crack area formation is demonstrated with reference to FIGS. As shown in FIG. 8, the laser beam L is irradiated by making the light collection point P fit inside the process object 1 on the conditions which multiphoton absorption generate | occur | produces, and the crack area | region 9 is formed inside along a cutting | disconnection scheduled line. The crack area 9 is an area including one or a plurality of cracks. The crack region 9 thus formed becomes a starting point region for cutting. As shown in FIG. 9, the crack grows further from the crack region 9 as a starting point (i.e., the starting point region from the cutting origin), and as shown in FIG. 10, the crack is formed on the surface 3 of the object 1 to be processed. And the back surface 21 are reached, and as shown in FIG. 11, the process object 1 is cut | disconnected by splitting | disconnecting the process object 1. The cracks reaching the front surface 3 and the rear surface 21 of the object 1 may grow naturally, or may grow by applying a force to the object 1.
Focus the light collection point inside the object to be processed (for example, a semiconductor material such as silicon), and emit the laser light under the condition that the electric field intensity at the light collection point is 1 × 10 8 (W / cm 2) or more and the pulse width is 1 dB or less. Investigate. As a result, the inside of the object to be processed is locally heated by multiphoton absorption. By this heating, a molten processed region is formed inside the object to be processed. The melt processing region is a region that is once remelted after melting, a region that is reliably melted, or a region that is restocked from the molten state, and may be referred to as a phase-changed region or a region in which the crystal structure is changed. have. Moreover, it can also be said that it is the area | region which changed one structure into another structure in a single crystal structure, an amorphous structure, and a polycrystal structure from a melt processing area | region. That is, for example, a region changed from a single crystal structure to an amorphous structure, a region changed from a single crystal structure to a polycrystalline structure, and a region changed from a single crystal structure to a structure including an amorphous structure and a polycrystalline structure. When the object to be processed is a silicon single crystal structure, the molten processed region is, for example, an amorphous silicon structure. As an upper limit of electric field intensity, it is 1 * 10 <12> (W / cm <2>), for example. The pulse width is preferably 1 ns to 200 ns, for example.
(A) Processing object: Silicon wafer (350 micrometers in thickness, outer diameter 4 inches)
(D) The moving speed of the mounting table on which the object to be processed is placed: 100 mm / s
It will be described that the molten processed region 13 is formed by multiphoton absorption. 13 is a graph showing the relationship between the wavelength of laser light and the transmittance inside the silicon substrate. However, the reflection component of each of the front side and the back side of the silicon substrate was removed, and only the internal transmittance was shown. The said relationship was shown about the thickness t of a silicon substrate of 50 micrometers, 100 micrometers, 200 micrometers, 500 micrometers, and 1000 micrometers, respectively.
For example, in 1064 nm which is a wavelength of Nd: YAG laser, when the thickness of a silicon substrate is 500 micrometers or less, it turns out that a laser beam permeates 80% or more inside a silicon substrate. Since the thickness of the silicon wafer 11 shown in FIG. 12 is 350 micrometers, the molten process area | region 13 by multiphoton absorption is formed in the vicinity of the center of the silicon wafer 11, ie, the part which is 175 micrometers from the surface. Since the transmittance in this case is 90% or more with reference to a silicon wafer having a thickness of 200 µm, laser light is hardly absorbed inside the silicon wafer 11, and most of them transmit. This is because laser light is absorbed in the silicon wafer 11, and the molten processed region 13 is not formed inside the silicon wafer 11 (that is, the molten processed region is formed by normal heating by the laser light). This means that the molten processed region 13 is formed by multiphoton absorption. Formation of the molten processed region by multiphoton absorption is described in, for example, "Processing characteristics of silicon by picosecond pulse lasers" on pages 72 to 73 of the 66th Collection of Welding Society National Conference Outline (April 2000). Evaluation ”.
In addition, the silicon wafer generates a breakage toward the cross-sectional direction starting from the cutting origin region formed by the melt processing region, and the breakage results in the breakage reaching the front and back surfaces of the silicon wafer. This cleavage that reaches the front and back surfaces of the silicon wafer may grow naturally, or may grow due to the application of force to the silicon wafer. In the case where the cleavage naturally grows on the front surface and the back surface of the silicon wafer from the cut start region, the melt treatment region forms the cut start region and the melt treatment region forms the cut origin region when the melt treatment region forming the cut start region is molten. In the case of re-stocking from this molten state, there exists a case where the division grows. In either case, the molten processed region is formed only inside the silicon wafer, and the molten processed region is formed only inside the cut surface after cutting, as shown in FIG. In this way, when the starting point region for cutting is formed inside the object to be processed by the molten processing region, unnecessary splitting that deviates from the starting point region line for cutting is unlikely to occur, so that the cutting control becomes easy.
(3) When the modified region is the refractive index change region
The condensing point is aligned inside the object to be processed (for example, glass), and the laser beam is irradiated on the condition that the electric field intensity at the condensing point is 1 × 10 8 (W / cm 2) or more and the pulse width is 1 ns or less. When the pulse width is made extremely short and the multiphoton absorption is caused inside the workpiece, the energy due to the multiphoton absorption does not change into thermal energy, and the permanent structure changes such as ion valence change, crystallization or polarization orientation inside the workpiece. Is caused to form a refractive index change region. As an upper limit of electric field intensity, it is 1 * 10 <12> (W / cm <2>), for example. The pulse width is preferably, for example, 1 ns or less, and more preferably 1 ps or less. Formation of the refractive index change region by multiphoton absorption is described, for example, in the glass interior by femtosecond laser irradiation on pages 105 to 111 of the 42nd Laser Thermal Processing Proceedings (Nov. 1997). Wild-night structure formation ".
In the above, the cases of (1) to (3) have been described as modified regions formed by multiphoton absorption. However, in consideration of the crystal structure of the wafer-like processing object, its cleavage properties, and the like, the starting point region for cutting is as follows. When formed together, it becomes possible to cut the object to be processed with a smaller force, and with good precision, using the cutting origin region as a starting point.
That is, in the case of a substrate made of a single crystal semiconductor having a diamond structure such as silicon, it is preferable to form a starting point region for cutting in the direction along the (111) plane (first cleaved surface) or 110 (plane) (second cleaved surface). Moreover, in the case of the board | substrate which consists of group III-V compound semiconductors of a galvanic structure, such as GaAs, it is preferable to form a cutting origin region in the direction along the (110) plane. Further, in the case of a substrate having a hexagonal crystal structure such as sapphire (Al 2 O 3 ), the (0001) plane (C plane) is the main plane (1120) plane (A plane) or (1100) plane (M plane) It is preferable to form the starting point region for cutting in the direction along ().
Further, an orientation flat is placed on the substrate along the direction orthogonal to the direction in which the above-mentioned cutting origin region should be formed (for example, the direction along the (111) plane in a single crystal silicon substrate) or the direction in which the cutting origin region should be formed. If formed, the cutting origin region along the direction in which the cutting origin region should be formed can be easily and accurately formed on the substrate by using the orientation flat as a reference.
Next, preferable embodiment of this invention is described. 14 is a plan view of the object to be processed in the laser processing method of the present embodiment, and FIG. 15 is a partial cross-sectional view along the XV-XV line of the object to be processed shown in FIG. 14.
As shown in FIG. 14 and FIG. 15, the object to be processed 1 is a laminate formed on the surface 3 of the substrate 4 including a substrate 4 having a thickness of 290 μm made of silicon and a plurality of functional elements 15. The part 16 is provided. The functional element 15 includes an interlayer insulating film 17a stacked on the surface 3 of the substrate 4, a wiring layer 19a disposed on the interlayer insulating film 17a, and an interlayer insulating film 17 so as to cover the wiring layer 19a. The interlayer insulating film 17b laminated on 17a and the wiring layer 19b disposed on the interlayer insulating film 17b are provided. The wiring layer 19a and the board | substrate 4 are electrically connected by the conductive plug 20a which penetrates the interlayer insulation film 17a, and the wiring layer 19b and the wiring layer 19a penetrate the conductive plug which penetrates the interlayer insulation film 17b. It is electrically connected by 20b.
In addition, although the functional elements 15 are formed in a matrix form in a direction parallel to and perpendicular to the orientation flat 6 of the substrate 4, the interlayer insulating films 17a and 17b are formed on the surface of the substrate 4. 3) It is formed between the functional elements 15 and 15 which adjoin each other so that the whole may be covered.
The object to be processed 1 configured as described above is cut for each functional element 15 as follows. First, as shown to FIG. 16A, the protective tape 22 is stuck to the to-be-processed object 1 so that the laminated part 16 may be covered. Subsequently, as shown in FIG. 16B, the object 1 is fixed on a mounting table (not shown) of the laser processing apparatus with the rear surface 21 of the substrate 4 facing upward. At this time, since the protection tape 22 can avoid that the laminated part 16 directly contacts a mounting table, each functional element 15 can be protected.
Then, the cutting schedule line 5 is set in a lattice shape so as to pass between the functional elements 15 and 15 that are adjacent to each other (see the broken line in FIG. 14), and the rear surface 21 is a laser beam incident surface, and the substrate While focusing the converging point P inside (4) and irradiating the laser beam L on the conditions which generate | occur | produce multi-photon absorption, the condensing point P is scanned along the cutting plan line 5 by the movement of a mounting base.
Although the scanning of the collection point P along this cutting schedule line 5 is performed 6 times with respect to one cutting schedule line 5, by changing the distance from the back surface 21 of the position which matches the collection point P each time, , In order from the surface 3 side, one row of quality reformed region 71, three rows of divided reformed region (first reformed region) 72, and two rows of HC (half cut) modified region (second modified region) The columns 73 are formed one by one inside the substrate 4 along the cut line 5 (the formation conditions of the modified regions 71, 72, and 73 will be described later). In addition, since the board | substrate 4 is a semiconductor substrate which consists of silicon, each modified area | region 71, 72, 73 is a fusion process area | region.
Thus, by forming each modified region 71, 72, 73 one by one in a sequence far from the back surface 21 of the substrate 4, the laser beam incident when the respective modified regions 71, 72, 73 are formed. Since no modified region exists between the back surface 21, which is a surface, and the light-converging point P of the laser beam L, scattering absorption and the like of the laser light L by the modified region already formed do not occur. Therefore, each modified region 71, 72, 73 can be formed in the inside of the board | substrate 4 along the cutting plan line 5 with good precision. Moreover, by making the back surface 21 of the board | substrate 4 into a laser beam incident surface, even if there exists a member (for example, TEG) which reflects the laser beam L on the cutting plan line 5 of the laminated part 16. Each of the modified regions 71, 72, and 73 can be reliably formed inside the substrate 4 along the cutting schedule line 5.
Here, in the formation of the quality modified region 71, as shown in FIG. 19, the distance between the surface 3 of the substrate 4 and the surface side end portion 71a of the quality modified region 71 is 5 μm to 15 μm. Or the distance between the surface 3 of the substrate 4 and the back end 71b of the quality modification region 71 is [(thickness of the substrate 4) × 0.1] μm to [20+ (substrate ( 1 row of quality-modified regions 71 are formed at a position of (thickness) 4) x 0.1] m. In the formation of the divided reformed regions 72, three rows of divided reformed regions 72 are formed so as to continue in the thickness direction of the substrate 4. In the formation of the HC reformed region 73, as shown in FIG. 16B, the HC reformed region 73 is formed in two rows, so that the cleavage 24 along the cutting scheduled line 5 is removed from the HC reformed region 73. On the back surface 21 of the substrate 4. In addition, depending on the formation conditions, the cleavage 24 may occur between the divided reformed region 72 and the HC reformed region 73 which are adjacent to each other.
After each of the modified regions 71, 72, 73 is formed, the expansion tape 23 is attached to the back surface 21 of the substrate 4 of the object 1 as shown in FIG. 17A. Subsequently, as shown in FIG. 17B, ultraviolet-ray is irradiated to the protective tape 22, the adhesive force is reduced, and as shown in FIG. 18A, the protective tape 22 is carried out from the laminated part 16 of the to-be-processed object 1 ))
After the protective tape 22 is peeled off, as shown in FIG. 18B, the expansion tape 23 is expanded, and the substrate 4 and the laminated portion ( 16) is cut along the cutting schedule line 5, and the semiconductor chips 25 obtained by cutting are separated from each other.
As described above, in the laser processing method, the substrate (the quality modification region 71, the division modification region 72, and the HC modification region 73 serving as the starting point of the cutting (dividing) is formed along the cutting schedule line 5. It is formed in the inside of 4). Therefore, the laser processing method of the substrate 4 and the laminated portion 16 even when the thickness of the substrate 4 on which the laminated portion 16 including the plurality of functional elements 15 is formed is thick, such as 290 μm. High precision cutting is possible.
Specifically, in the above laser processing method, two rows of HC-modified regions 73 are formed at positions between the divided reformed region 72 and the rear surface 21 closest to the rear surface 21 of the substrate 4. The cleavage 24 along the cutting schedule line 5 is caused from the HC modified region 73 to the back surface 21 of the substrate 4. Thus, when the expansion tape 23 is attached to the back surface 21 of the substrate 4 and expanded, the laminated portion (from the substrate 4 is formed through the divided reformed regions 72 formed in three rows so as to continue in the thickness direction. The division proceeds smoothly to 16, and as a result, the substrate 4 and the laminated portion 16 can be cut along the cutting schedule line 5 with good precision.
In addition, as long as division can be made to advance smoothly from the board | substrate 4 to the laminated part 16, the division | segmentation modification area | region 72 is not limited to three rows. In general, the thinner the substrate 4, the lower the number of columns of the splitting reforming region 72, and the thicker the substrate 4, the higher the number of columns of the splitting reforming region 72. In addition, as long as the division can be smoothly progressed from the substrate 4 to the laminated portion 16, the divided reformed regions 72 may be separated from each other. In addition, as long as the cleavage 24 can be reliably produced from the HC reformed region 73 to the back surface 21 of the substrate 4, the HC reformed region 73 may be one row.
In the above laser processing method, the distance between the surface 3 of the substrate 4 and the surface side end portion 71a of the quality modification region 71 is 5 µm to 15 µm, or the substrate 4 The distance between the surface 3 and the back side end portion 71b of the quality modification region 71 is from [(thickness of the substrate 4) × 0.1] μm to [20+ (thickness of the substrate 4) × 0.1] μm. The quality modification area | region 71 is formed in the position to become. When the quality modification region 71 is formed at such a position, the laminated portions 16 (herein, the interlayer insulating films 17a and 17b) formed on the surface 3 of the substrate 4 are also good along the cut line 5. Can cut with precision.
In the semiconductor chip 25 cut | disconnected by the above laser processing method, as shown in FIG. 18B, the cutting surface (side surface) 4a of the board | substrate 4 in which each modified area | region 71, 72, 73 was formed. The cut surface (side surface) 16a of the laminated part 16 becomes a high precision cut surface in which the unevenness | corrugation was suppressed.
20 is a diagram showing a photograph of the cut surface 4a of the substrate 4 cut by use of the laser processing method. As described above, the substrate 4 is made of silicon, and its thickness is 300 m. The conditions for forming each modified region 71, 72, 73 are shown in Table 1 below. In addition, in Table 1, a condensing point position means the distance from the back surface 21 of the position which matches the condensing point P of the laser beam L, and energy is a thing at the time of forming each modified area | region 71, 72, 73. It means the energy of the laser light L. Moreover, the pulse width of the laser beam L at the time of forming each modified region 71, 72, 73 is 180 ns, and the laser beam L of 1 pulse is irradiated when the laser beam L is irradiated along the cutting | disconnection plan line 5. The interval (hereinafter referred to as the interval between laser light irradiation positions) of the positions (positions where the condensing points P are combined) is 4 m.
Condensing point position (㎛) Energy (μJ) Quality Reforming Zone (71) 267 15 Divided reforming area 72 (surface 3 side) 196 20 Segmentation Modification Zone (72) 160 20 Divided reforming area 72 (back side 21 side) 125 20 HC modified region 73 (surface 3 side) 71 10 HC modified region 73 (back side 21 side) 39 10
At this time, the width of the quality modified region 71 in the thickness direction of the substrate 4 is about 20 µm, the width of each divided reformed region 72 is about 37 µm, and the width of each HC modified region 73 is It was about 20 micrometers. Further, the distance between the surface 3 and the surface side end portion 71a of the quality reformed region 71 is about 7 μm, and the surface of the back side end portion 71b and the segmented reformed region 72 facing the quality reformed region 71. The distance from the side end part 72a was about 59 micrometers, and the distance between the back side end 72b of the opposing dividing-modification region 72 and the surface side end 73a of the HC modification region 73 was about 24 micrometers. In addition, each divisional modification region 72 was formed so as to continue in the thickness direction of the substrate 4.
However, the width of the quality reformed region 71 means the distance between the front end 21a and the back end 71b of the quality reformed region 71 (see FIG. 19). Moreover, the surface side edge part 71a of the quality-modification area | region 71 is the "in the thickness direction of the board | substrate 4 in the edge part of the surface 3 side side of the quality-modification area | region 71 formed along the cutting plan line 5. Means an average position of &quot;, &quot; the rear surface side end portion 71b of the quality reformed region 71 is the &quot; substrate 4 &quot; of the end portion on the rear surface 21 side of the quality reformed region 71 formed along the cutting schedule line 5; Means an average position in the thickness direction. This work is the same for the split reforming region 72 and the HC reforming region 73.
Next, the formation conditions and the like of each of the modified regions 71, 72, and 73 described above will be described. In addition, the following formation conditions are especially effective when the thickness of the board | substrate 4 is 150 micrometers-800 micrometers.
(1) About energy of laser light L when forming HC modified region 73
The energy of the laser light L when forming the HC modified region 73 is preferably 1 μJ to 20 μJ, as can be clearly seen from the data in Table 2 below. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 1 microJ-10 microJ, and when the same transmittance | permeability is 15% or less, it is preferable that it is 2 microJ-20 microJ. Moreover, the transmittance | permeability falls remarkably when the thickness of the board | substrate 4 is thick and the density | concentration of an impurity is high.
This is because when the HC modified region 73 is formed under such conditions, the cleavage 24 starting from the HC modified region 73 tends to reliably reach the back surface 21 of the substrate 4. In addition, when the energy of the laser beam L becomes less than 1 µJ, the cleavage 24 starting from the HC modified region 73 becomes difficult to reach the back surface 21 of the substrate 4. On the other hand, when the energy of the laser beam L exceeds 20 µJ, damage 30 such as melting tends to occur on the back surface 21 of the substrate 4, as shown in FIG. FIG. 21 shows the substrate in the case where the distance from the back surface 21 at the position where the condensing point P of the laser beam L is set to 40 µm and the energy of the laser beam L is 25 µJ when the HC modified region 73 is formed ( It is a figure which shows the photograph of the back surface 21 of 4).
Energy (μJ) 0.5 1.0 2.0 2.5 5.0 10 15 20 25 30% or more transmittance △ ○ ○ ○ ○ ○ × × × Transmittance 15% or less × △ ○ ○ ○ ○ ○ ○ ×
"Δ" on the low energy side: in the case where the part where the cleavage 24 reaches the rear surface 21 of the substrate 4 and the part which does not reach the mixture are mixed
"X" on the low energy side: when the cleavage 24 hardly reaches the back surface 21 of the substrate 4
"X" on the high energy side: when damage such as melting occurs on the back surface 21 of the substrate 4
In addition, the data of Table 2 is when the HC modification area | region 73 is formed in 1 or more rows in the range of 20 micrometers-110 micrometers in the back surface 21 of the board | substrate 4. As shown in FIG.
(2) Regarding the energy of the laser light L when forming the segment modification region 72
The energy of the laser light L when forming the divided reformed region 72 is the energy of the laser light L when forming the HC modified region 73, as can be clearly seen from the data in Table 3 below. When it is set to 1, it is preferable that it is 1.6-3.0. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 1.6-3.0, and when the same transmittance | permeability is 15% or less, it is preferable that it is 2.3-3.0.
When the divided reformed region 72 is formed under such a condition, at the time of cutting the substrate 4 and the laminated portion 16, the cleavage based on the divided reformed region 72 is along the cut schedule line 5. This is because it tends to occur with good accuracy. In addition, when the energy of the laser beam L is less than 1.6, it is difficult to generate the splitting starting from the segment modification region 72 at the time of cutting the substrate 4 and the laminated portion 16. On the other hand, when the energy of the laser beam L exceeds 3.0, the breakage starting from the cleavage modifying region 72 at the time of cutting the substrate 4 and the laminated portion 16 tends to deviate from the scheduled cutting line 5. .
Energy costs 1.0 1.1 1.3 1.4 1.5 1.6 1.7 1.8 30% or more transmittance × × × × △ ○ ○ ○ Transmittance 15% or less × × × × × × × × Energy costs 1.9 2.0 2.1 2.2 2.3 3.0 3.1 3.2 30% or more transmittance ○ ○ ○ ○ ○ ○ △ × Transmittance 15% or less × × △ △ ○ ○ △ ×
"△" on the low energy side: where good quality and bad parts are mixed
Low energy "×": When excessive stress is not applied, splitting does not occur and splitting quality is bad
"△" on the high-energy side: where good and bad parts are mixed
"×" on the high energy side: When cutting quality is poor, such as defects on the cutting surface
In addition, the energy of the laser light L when forming the split modification region 72 is preferably 2 μJ to 50 μJ, as can be clearly seen from the data in Table 4 below. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 2 microJ-20 microJ (more preferably 2 microJ-15 microJ), and when the same transmittance | permeability is 15% or less, 3 microJ- It is preferable that it is 50 microJ (more preferably 3 microJ-45 microJ). When the transmittance | permeability is 15% or less, although the preferable range of the energy of the laser beam L becomes wider, this is because larger energy is needed in order to form a modified area | region, such as a low transmittance | permeability.
When the divided reformed region 72 is formed under such a condition, at the time of cutting the substrate 4 and the laminated portion 16, the cleavage based on the divided reformed region 72 is along the cut schedule line 5. This is because it tends to occur with good accuracy. In addition, when the energy of the laser beam L is less than 2 µJ, it is difficult to generate a cleavage based on the segment modification region 72 at the time of cutting the substrate 4 and the laminated portion 16. On the other hand, when the energy of the laser beam L exceeds 50 µJ, the cleavage starting from the cleavage modification region 72 at the time of cutting the substrate 4 and the lamination portion 16 tends to deviate from the cutting schedule line 5. .
Energy (μJ) 1.0 2.0 3.0 5.0 10 15 20 25 30 35 40 45 50 55 30% or more transmittance × ○ ○ ○ ○ ○ △ × × × × × × × Transmittance 15% or less × △ ○ ○ ○ ○ ○ ○ ○ ○ ○ ○ △ ×
(3) Regarding the energy of the laser light L when forming the quality modification region 71
The energy of the laser light L when the quality modified region 71 is formed is, as can be clearly seen from the data in Table 5 below, the energy of the laser light L when the HC modified region 73 is formed. When making it 1, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 1.4-1. 1.9, and when the same transmittance | permeability is 15% or less, it is preferable that it is 2.3-3.0.
When the quality modified region 71 is formed under such conditions, the cleavage based on the quality modified region 71 starts along the cut schedule line 5 at the time of cutting the substrate 4 and the laminated portion 16. This is because there is a tendency to reach the laminated portion 16 with good accuracy. In addition, when the energy of the laser beam L falls below the above conditions, in the cutting of the substrate 4 and the lamination section 16, the cleavage starting from the quality modification region 71 is separated from the scheduled cutting line 5 and laminated. It becomes easy to reach the part 16. On the other hand, when the energy of the laser beam L exceeds the above condition, damage such as melting or the like is likely to occur in the laminate 16.
Energy costs 1.0 1.1 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 3.0 3.1 3.2 30% or more transmittance × × △ ○ ○ ○ ○ ○ ○ △ × × × × × × Transmittance 15% or less × × × × × × × × × × △ △ ○ ○ △ ×
Low energy "×": When excessive stress is not applied, breakage does not occur and cutting quality is bad
"Δ" on the high-energy side: partial damage to the laminate 16 such as melting
"X" on the high energy side: when the laminate 16 is damaged such as melting
In addition, the energy of the laser light L when forming the quality modification region 71 is preferably 2 μJ to 50 μJ, as can be clearly seen from the data in Table 6 below. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 2 microJ-20 microJ (more preferably 2 microJ-15 microJ), and when the same transmittance | permeability is 15% or less, 3 microJ- It is preferable that it is 50 microJ (more preferably 3 microJ-45 microJ).
When the quality modified region 71 is formed under such conditions, the cleavage based on the quality modified region 71 starts along the cut schedule line 5 at the time of cutting the substrate 4 and the laminated portion 16. This is because there is a tendency to reach the laminated portion 16 with good accuracy. In addition, when the energy of the laser beam L becomes less than 2 µJ, in the cutting of the substrate 4 and the lamination section 16, the cleavage starting from the quality modification region 71 is laminated off the cutting scheduled line 5. It becomes easy to reach the part 16. On the other hand, when the energy of the laser beam L exceeds 50 µJ, damages such as melting and the like to the laminated portion 16 easily occur.
(4) Formation Position of the Divided Reforming Region 72
It is preferable that the distance between the positions where the light-converging point P of the laser beam L is aligned when forming each of the divided reformed regions 72 adjacent to each other is 24 µm to 70 µm. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 30 micrometers-70 micrometers, and when the same transmittance | permeability is 15% or less, it is preferable that it is 24 micrometers-50 micrometers. . When the divided reformed regions 72 are formed under such conditions, the divided reformed regions 72 and 72 adjacent to each other tend to continue in the thickness direction of the substrate 4, and as a result, the substrate 4 This is because even when thick, the substrate 4 and the laminated portion 16 can be easily cut.
In addition, when forming the segmented modified region 72, the distance from the back surface 21 at the position where the converging point P of the laser beam L is aligned is 50 µm to [(thickness of the substrate 4) x 0.9 (preferably 0.7). ] Micrometer is preferable. This is because when the divided reformed region 72 is formed under such a condition, the substrate 4 and the laminated portion 16 can be easily cut even when the substrate 4 is thick.
In addition, in the case where the divided reformed region 72 and the HC modified region 73 which are adjacent to each other are formed, the position where the condensed modified region 72 is aligned with the converging point P of the laser beam L is the HC modified region 73. ) Is preferably within the range of 30 µm to 100 µm on the surface 3 side of the substrate 4 from the position where the focusing point P of the laser beam L is aligned. At this time, the distance between the rear surface side end portion of the opposing segment reforming region 72 and the surface side end portion of the HC reforming region 73 is 15 µm to 60 µm (preferably 15 µm to 35 µm), This is because the cleavage 24 easily occurs between the divided reformed region 72 and the HC reformed region 73.
(5) Formation Position of HC Modified Region 73
It is preferable that the distance from the back surface 21 of the position which matches the light converging point P of the laser beam L when forming HC modification area 73 is 20 micrometers-110 micrometers. This is because when the HC modified region 73 is formed under such conditions, the cleavage 24 starting from the HC modified region 73 tends to reliably reach the back surface 21 of the substrate 4. Moreover, when the distance from the back surface 21 is less than 20 micrometers, as shown in FIG. 22, the damage 30, such as melt | fusion, will arise easily on the back surface 21 of the board | substrate 4. As shown in FIG. Fig. 22 shows the substrate in the case where the distance from the back surface 21 at the position where the condensing point P of the laser beam L is aligned is 15 µm and the energy of the laser beam L is 10 µJ when the HC modified region 73 is formed ( It is a figure which shows the photograph of the back surface 21 of 4). On the other hand, when the distance from the back surface 21 exceeds 110 micrometers, the cleavage 24 starting from the HC modified region 73 will become difficult to reach the back surface 21 of the board | substrate 4. At this time, the distance between the rear surface 21 of the substrate 4 and the rear surface side end portion of the HC modified region 73 is set to 10 µm to 100 µm.
(6) About the distance between the back side end part of the opposing dividing-modification area | region 72 and the surface side end part of HC-modification area | region 73
It is preferable that it is 15 micrometers-60 micrometers, and, as for the distance between the back surface side edge part of the opposing divisional modification region 72 and the surface side edge part of HC modification region 73, it is more preferable that they are 15 micrometers-35 micrometers. When the divided reformed region 72 and the HC modified region 73 are formed under such conditions, the cleavage based on the modified regions 72 and 73 at the time of cutting the substrate 4 and the laminated portion 26 is performed. It is because it exists in the tendency to generate | occur | produce with favorable precision along this cutting plan line 5, and the cut surface 4a of the board | substrate 4 of the semiconductor chip 25 turns into a high precision cut surface. In addition, when the distance is less than 15 μm, the cleavage based on each of the modified regions 72 and 73 at the time of cutting the substrate 4 and the laminated portion 16 tends to deviate from the cutting schedule line 5. As a result, the cut surface 4a of the substrate 4 of the semiconductor chip 25 becomes difficult to be a cut surface with high precision. On the other hand, when the distance exceeds 60 µm, the interaction between the segment reforming region 72 and the HC reforming region 73 becomes small at the time of cutting the substrate 4 and the laminated portion 16, and the semiconductor chip 25 The cut surface 4a of the board | substrate 4 of () becomes difficult to become a high precision cut surface.
(7) With respect to the distance between the back side end portion of the opposing quality modification region 71 and the surface side end portion of the dividing modification region 72.
The distance between the back surface side end portion of the opposed quality reformed region 71 and the surface side end portion of the divided reformed region 72 is 0 μm to [(thickness of the substrate 4) − (thickness of the substrate 4) × 0.6] It is preferable that it is micrometer. If the quality reformed region 71 and the segmented reformed region 72 are formed under such conditions, cleavage based on the reformed regions 71 and 72 at the time of cutting the substrate 4 and the laminate 16 is performed. It tends to occur with good precision along this cutting | disconnection scheduled line 5, and the cutting surface 4a of the board | substrate 4 of the semiconductor chip 25 and the cutting surface 16a of the laminated part 16 are made into the high precision cutting surface. Because it becomes. If the distance exceeds [(thickness of the substrate 4) − (thickness of the substrate 4) × 0.6] μm, the quality modification region 71 at the time of cutting the substrate 4 and the laminated portion 16. ), And the cut surface 4a of the board | substrate 4 of the semiconductor chip 25 becomes difficult to become a high precision cut surface between the part and the division | modification modified region 72. FIG. In addition, setting the distance to 0 µm is a case where the substrate 4 is completely cut off only by irradiation of the laser light L. FIG.
(8) Formation Position of the Quality Reformed Area 71
At the position where the distance between the surface 3 of the board | substrate 4 and the surface side edge part of the quality-modified area | region 71 becomes 5 micrometers-15 micrometers, or the surface 3 of the board | substrate 4 and the quality-modified area | region 71 In which the quality modified region 71 is formed at a position where the distance from the rear surface side end portion of the &quot;) becomes [(thickness of the substrate 4) × 0.1] m to [20+ (thickness of the substrate 4) × 0.1] m. It is preferable. If the quality modification area | region 71 is formed on such conditions, as shown in FIG. 23, the skirt width S can be suppressed to 3 micrometers or less, and the laminated part 16 formed in the surface 3 of the board | substrate 4 is carried out. This is because it is possible to cut with good precision along the cutting schedule line 5.
In addition, when the quality modified area 71 is formed in the position where the distance between the surface 3 of the board | substrate 4 and the surface side edge part of the quality modified area 71 will be 5 micrometers-10 micrometers, it will show in FIG. Similarly, skirt width S can be suppressed to 1 micrometer or less, and the edge part and the laminated part 16 of the surface 3 side of the board | substrate 4 can be cut | disconnected with more precision along the cutting schedule line 5. Done. Moreover, about the distance between the surface 3 of the board | substrate 4 and the back side edge part of the quality-modification area | region 71, the said distance is [5+ (thickness of the board | substrate 4) * 0.1] micrometer-[20+ (substrate ( It is preferable to form the quality modification area | region 71 in the position which becomes thickness of 4) x 0.1] micrometer, and the said distance is [5+ (thickness of the board | substrate 4) x 0.1] micrometer-[10+ (substrate (4) It is more preferable to form the quality modifying region 71 at a position of (thickness) x 0.1] mu m. If the quality modification region 71 is formed under such conditions, it is possible to cut the end portion and the laminated portion 16 on the surface 3 side of the substrate 4 along the cutting schedule line 5 with better accuracy. Because.
In addition, in FIG. 23, the condensing point position means the distance from the back surface 21 of the position which matches the condensing point P of the laser beam L, and energy means the laser beam L at the time of forming the quality-modification area | region 71. In FIG. It means energy. In addition, a back surface side end position means the distance from the back surface 21 of the back surface side edge part of the quality-modification area | region 71, and a width means the distance of the surface side edge part of the quality-modification area | region 71 and a back surface side end part. In addition, the surface side end position means the distance from the surface 3 of the surface side edge part of the quality-modification area | region 71. As shown in FIG.
Moreover, when the distance between the surface 3 of the board | substrate 4 and the surface side edge part of the quality-modification area | region 71 is less than 5 micrometers, as shown in FIG. 24, it melts on the surface 3 of the board | substrate 4 Damage 30 of the back tends to occur. FIG. 24 shows the substrate in the case where the distance from the surface 3 at the position where the condensing point P of the laser beam L is aligned is 3 µm and the energy of the laser beam L is 15 µJ when the quality modification region 71 is formed ( The figure which showed the photograph of the cut surface of 4).
(9) About width of each modified area 71, 72, 73
It is preferable that the width of the HC modified region 73 in the thickness direction of the substrate 4 (the sum of the widths in the case of forming a plurality of rows of the HC modified regions 73) is 110 μm or less. When the HC modified region 73 is formed under such conditions, the cleavage 24 from the HC modified region 73 to the back surface 21 of the substrate 4 is formed with good precision along the cut line 5. Because there is a tendency. In addition, when the width of the HC modified region 73 exceeds 110 µm, the cleavage 24 from the HC modified region 73 to the back surface 21 of the substrate 4 tends to escape from the cut schedule line 5.
Moreover, it is preferable that the sum total of the width | variety of the segmentation modification area | region 72 in the thickness direction of the board | substrate 4 is 40 micrometers-[(thickness of the board | substrate 4) x 0.9] micrometer. When the divided reformed region 72 is formed under such a condition, at the time of cutting the substrate 4 and the laminated portion 16, the cleavage based on the divided reformed region 72 is along the cut schedule line 5. This is because it tends to occur with good accuracy, and the cut surface 4a of the substrate 4 of the semiconductor chip 25 becomes a cut surface of high precision. Moreover, when the sum total of the width | variety of the segmentation reforming area | region 72 is less than 40 micrometers, it becomes difficult to generate | occur | produce the division | segmentation based on the segmentation reforming area | region 72 at the time of the cutting | disconnection of the board | substrate 4 and the laminated part 16, It is difficult for the cutting surface 4a of the board | substrate 4 of the semiconductor chip 25 to be a high precision cutting surface. On the other hand, when the sum total of the width | variety of the segmentation reforming area | region 72 exceeds [(thickness of the board | substrate 4) x 0.9] micrometer, when it cut | disconnects the board | substrate 4 and the laminated part 16, the segmentation reforming area | region 72 The cleavage starting from this point tends to deviate from the cutting schedule line 5, and it becomes difficult for the cut surface 4a of the board | substrate 4 of the semiconductor chip 25 to become a high precision cut surface.
Moreover, it is preferable that the width | variety of the quality modification area | region 71 in the thickness direction of the board | substrate 4 is [(thickness of the board | substrate 4) x 0.1] micrometer or less. When the quality modified region 71 is formed under such conditions, the cleavage based on the quality modified region 71 starts along the cut schedule line 5 at the time of cutting the substrate 4 and the laminated portion 16. This is because there is a tendency to reach the laminated portion 16 with good accuracy. If the width of the quality modified region 71 exceeds [(thickness of the substrate 4) × 0.1] μm, the quality modified region 71 is cut at the time of cutting the substrate 4 and the laminate 16. The cleavage set as the starting point deviates from the cutting schedule line 5 and easily reaches the laminated part 16.
Next, the processing result regarding FIG. 25 is demonstrated.
FIG. 25 is a diagram showing a photograph of the cut surface 4a of the substrate 4 cut by use of the laser processing method. As described above, the substrate 4 is made of silicon, and its thickness is 290 μm. The conditions for forming each modified region 71, 72, 73 are shown in Table 7 below. In addition, in Table 7, the condensing point position means the distance from the back surface 21 of the position which matches the condensing point P of the laser beam L, and an energy means when forming each modified area | region 71, 72, 73. It means the energy of the laser light L. Moreover, the pulse width of the laser beam L when forming each modified area | region 71, 72, 73 is 150 ns, and when the laser beam L is irradiated along the cutting | disconnection plan line 5, 1 pulse of laser beam L is irradiated. The interval (hereinafter referred to as the interval between laser light irradiation positions) of the positions (positions where the converging points P are combined) is 3.75 占 퐉.
Condensing point position (㎛) Energy (μJ) Quality Reforming Zone (71) 275 7 Divided reforming area 72 (surface 3 side) 228 14 Segmentation Modification Zone (72) 194 14 Divided reforming area 72 (back side 21 side) 165 14 HC modified region 73 (surface 3 side) 104 14 HC modified region 73 (back side 21 side) 57 9
At this time, the width of the quality reformed region 71 in the thickness direction of the substrate 4 is about 22 µm, the width of each divided reformed region 72 is about 33 µm, and the HC modified region (on the surface 3 side) The width of 73) was about 28 µm, and the width of the HC modified region 73 on the rear surface 21 side was about 20 µm. Moreover, the distance between the surface 3 and the surface side edge part 71a of the quality-modification area | region 71 is about 8 micrometers, and the surface of the back surface side edge part 71b and the division | segmentation reforming area | region 72 which oppose the quality-modification area | region 71 The distance from the side end part 72a was about 25 micrometers, and the distance between the back side end 72b of the opposing dividing-modification region 72 and the surface side end 73a of the HC modification region 73 was about 25 micrometers. In addition, each divisional modification region 72 was formed so as to continue in the thickness direction of the substrate 4.
By forming the modified layer as described above, it is possible to suppress that a step is generated in the cracks extending from the HC modified region 73 on the surface 3 side as compared with FIG. 20 (the step does not become a uniform surface in proportion). Can be. Then, due to the step due to the crack, the laser beam incident upon the formation of the HC modified region 73 on the rear surface 21 side causes the molten particles to be generated in the ratio end face, and this can prevent the formation of large dust.
For this reason, in the embodiment of FIG. 20, the energy of the laser beam when forming the HC modified region 73 on the front surface 3 side and the HC modified region 73 on the rear surface 21 side was made the same. In the present embodiment, the energy of the laser light when forming the HC modified region 73 on the surface 3 side is greater than the energy of the laser light when forming the HC modified region 73 on the rear surface 21 side.
In this case, the energy of the laser beam when forming the HC modified region 73 on the surface 3 side is the energy condition of the laser beam L when forming the short modified region 72 as described above. The same conditions are used. That is, it is preferable that they are 2 micrometers-50 micrometers. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 2 microJ-20 microJ (more preferably 2 microJ-15 microJ), and when the same transmittance | permeability is 15% or less, 3 microJ- It is preferable that it is 50 microJ (more preferably 3 microJ-45 microJ).
In addition, the energy of the laser beam when forming the HC modified region 73 on the surface 3 side when the energy of the HC modified region 73 on the rear surface 21 side is 1 is divided into a modified region (to be described later) ( It is set as the same condition as the energy condition of the laser beam L when forming 72) (the energy condition of the laser beam when forming the divided reformed region 72 when the energy of the HC modified region 73 is 1). .
That is, the energy of the laser beam L when forming the HC modified region 73 on the surface 3 side when the energy of the HC modified region 73 on the rear surface 21 side is 1 is 1.3 to 3.3. desirable. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 1.3-3.0, and when the same transmittance | permeability is 15% or less, it is preferable that it is 1.5-3.3.
(10) Regarding the relationship between the energy of the laser light L when the divided reformed region 72 is formed and the energy of the laser light L when the HC modified region 73 is formed.
In the case where a plurality of rows of the HC reformed regions 73 are formed, the energy of the laser light L when the split reformed regions 72 are formed, as can be clearly seen from the data in Table 8 below, the substrate 4 When the energy of the laser light L when forming the HC modified region 73 closest to the rear surface 21 of the surface is 1, the energy of the laser light when forming the divided reformed region 72 is preferably 1.3 to 3.3. Do. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 1.3-3.0, and when the same transmittance | permeability is 15% or less, it is preferable that it is 1.5-3.3.
When a plurality of rows of the HC reformed regions 73 are formed under such conditions, when the HC reformed region 73 is formed close to the rear surface 21 of the substrate 4, the HC reformed region 73 is formed. Since the resulting cleavage 24 does not reach the vicinity of the back surface 21 of the substrate 4, when the HC modified region 73 closest to the back surface 21 of the substrate 4 is formed, the cleavage 24 is formed. The inner surface of the melt can be prevented from generating dust.
Energy costs 1.0 1.1 1.3 1.4 1.5 1.6 1.7 1.8 30% or more transmittance × × ○ ○ ○ ○ ○ ○ Transmittance 15% or less × × × △ ○ ○ ○ ○ Energy costs 1.9 2.0 2.1 2.2 2.3 3.0 3.1 3.2 30% or more transmittance ○ ○ ○ ○ ○ ○ × × Transmittance 15% or less ○ ○ ○ ○ ○ ○ ○ ○ Energy costs 3.3 3.4 3.5 3.6 30% or more transmittance × × × × Transmittance 15% or less ○ △ × ×
(11) Regarding the energy of the laser light L when forming the quality modification region 71
The energy of the laser light L when forming the quality modified region 71 is clear when the HC modified region 73 is formed on the rear surface 21 side, as can be clearly seen from the data in Table 9 below. When the energy of the laser beam L is 1, the transmittance of the laser beam L in the substrate 4 is preferably 0.6 to 1.9 when the transmittance is 30% or more, and 0.6 to 3.0 when the same transmittance is 15% or less. desirable.
Energy costs 0.3 0.4 0.5 0.6 0.7 0.8 0.9 30% or more transmittance × × △ ○ ○ ○ ○ Transmittance 15% or less × × △ ○ ○ ○ ○ Energy costs 1.0 1.1 1.3 1.4 1.5 1.6 1.7 1.8 30% or more transmittance ○ ○ ○ ○ ○ ○ ○ ○ Transmittance 15% or less ○ ○ ○ ○ ○ ○ ○ ○ Energy costs 1.9 2.0 2.1 2.2 2.3 3.0 3.1 3.2 30% or more transmittance ○ △ × × × × × × Transmittance 15% or less ○ ○ ○ ○ ○ ○ △ ×
In addition, the energy of the laser beam L at the time of forming the quality modification area 71 is as the data of Table 6 mentioned above. That is, it is preferable that they are 2 micrometers-50 micrometers. In more detail, when the transmittance | permeability of the laser beam L in the board | substrate 4 is 30% or more, it is preferable that it is 2 microJ-20 microJ (more preferably 2 microJ-15 microJ), and when the same transmittance | permeability is 15% or less, 3 microJ- It is preferable that it is 50 microJ (more preferably 3 microJ-45 microJ).
(12) Formation Position of Each HC Modified Region 73 in the case of forming a plurality of rows of HC modified regions 73
In the case where a plurality of rows of the HC modified regions 73 are formed, the back surface 21 at the position where the condensing point P of the laser beam L is aligned when the HC modified region 73 closest to the back surface 21 of the substrate 4 is formed. Distance from 20 micrometers-110 micrometers, and from the back surface 21 of the position which matches the light-converging point P of the laser beam L, when forming HC modification area | region 73 which is close to the back surface 21 of the board | substrate 4, is formed. It is preferable that a distance is 140 micrometers or less.
As mentioned above, although the formation conditions of each modified region 71, 72, 73 etc. were demonstrated, the pulse width of the laser beam L at the time of forming each modified region 71, 72, 73 is preferably 500 ns or less, and 10 ns- 300 ns is more preferable (more preferably 100 ns to 300 ns). Moreover, it is preferable that the space | interval of a laser light irradiation position is 0.1 micrometer-10 micrometers. The interval of the laser light irradiation position can be appropriately set by the repetition frequency of the laser and the moving speed of the laser light.
In addition, in the formation of the divided reformed region 72, as described above, unless the various forming conditions for the modified reformed region 72 are satisfied, as shown in FIG. 26A, the object to be processed 1 is the semiconductor chip 25. The part which is not cut occurs. On the other hand, as described above, if various forming conditions for the short reforming region 72 are satisfied, as shown in FIG. 26B, the entirety of the object 1 is reliably cut into the semiconductor chip 25.
This invention is not limited to the said embodiment. For example, in the above embodiment, the multi-photon absorption is caused to occur within the substrate 4 to form the respective modified regions 71, 72, and 73. However, the light equivalent to the multi-photon absorption within the substrate 4 is formed. In some cases, absorption may be caused to form the modified regions 71, 72, and 73.
Further, in the above embodiment, the quality reformed region 71 in one row, the division reformed region 72 in three rows, and the HC reformed region 73 in two rows are arranged in the substrate 4 in order from the stacking portion 16 side. Although it was a case where it forms in the inside, each modified region 71, 72, 73 may be formed in the inside of the board | substrate 4 as follows.
For example, as shown in FIG. 27, in order from the surface 3 side of the substrate 4, one row of quality reformed regions 71, two rows of divided reformed regions 72, and one row of HC modified regions ( 73 may be formed inside the substrate 4. Here, the board | substrate 4 consists of silicon, and the thickness is 200 micrometers. The conditions for forming each modified region 71, 72, 73 are shown in Table 10 below. Moreover, the pulse width of the laser beam L when forming each modified region 71, 72, 73 is 150 ns, and the space | interval of a laser beam irradiation position is 4 micrometers.
Condensing point position (㎛) Energy (μJ) Quality Reforming Zone (71) 167 15 Divided reforming area 72 (surface 3 side) 121 20 Divided reforming area 72 (back side 21 side) 71 20 HC modified zone (73) 39 10
In addition, as shown in FIG. 28, one row of quality reformed regions 71, two rows of divided reformed regions 72, and two rows of HC modified regions 73 in order from the surface 3 side of the substrate 4. May be formed inside the substrate 4. Here, the board | substrate 4 consists of silicon, and the thickness is 300 micrometers. The conditions for forming each modified region 71, 72, 73 are shown in Table 11 below. In addition, the pulse width of the laser light L when forming each modified region 71, 72, 73 is 150 ns, and the interval of the laser light irradiation position is 4 占 퐉 as the quality modified region 71 and the segmented modified region 72. 1 µm to the surface 3 side, 4 µm to the segment reforming region 72 (the back side 21 side), 4 µm to the HC reforming region 73 (the surface 3 side), and HC reforming region 73 It is 4 micrometers to (the back side 21 side).
Condensing point position (㎛) Energy (μJ) Quality Reforming Zone (71) 256 15 Divided reforming area 72 (surface 3 side) 153 20 Divided reforming area 72 (back side 21 side) 121 20 HC modified region 73 (surface 3 side) 71 10 HC modified region 73 (back side 21 side) 39 10
As shown in FIG. 29, one row of quality modified regions 71, 19 rows of divided reformed regions 72, and two rows of HC modified regions 73 are sequentially disposed from the surface 3 side of the substrate 4. May be formed inside the substrate 4. Here, the substrate 4 is made of silicon, and its thickness is 725 m. The conditions for forming each modified region 71, 72, 73 are shown in Table 12 below. Moreover, the pulse width of the laser beam L when forming each modified region 71, 72, 73 is 150 ns, and the space | interval of a laser beam irradiation position is 4 micrometers.
Condensing point position (㎛) Energy (μJ) Quality Reforming Zone (71) 644 15 Divided reforming area 72 (surface 3 side) 641 20 Segmentation Modification Zone (72) 612 20 Segmentation Modification Zone (72) 584 20 Segmentation Modification Zone (72) 555 20 Segmentation Modification Zone (72) 527 20 Segmentation Modification Zone (72) 498 20 Segmentation Modification Zone (72) 470 20 Segmentation Modification Zone (72) 441 20 Segmentation Modification Zone (72) 413 20 Segmentation Modification Zone (72) 384 20 Segmentation Modification Zone (72) 356 20 Segmentation Modification Zone (72) 328 20 Segmentation Modification Zone (72) 299 20 Segmentation Modification Zone (72) 271 20 Segmentation Modification Zone (72) 242 20 Segmentation Modification Zone (72) 214 20 Segmentation Modification Zone (72) 185 20 Segmentation Modification Zone (72) 157 20 Divided reforming area 72 (back side 21 side) 121 20 HC modified region 73 (surface 3 side) 71 10 HC modified region 73 (back side 21 side) 39 10
In addition, in Tables 10-12, a condensing point position means the distance from the back surface 21 of the position which matches the condensing point P of the laser beam L, and energy forms each modified area | region 71, 72, 73. It means the energy of the laser light L when doing.
One… Object,
3 ... surface,
4… Board,
4a ... Cutting plane (side),
5 ... Line to be cut,
7 ... Reforming area,
8… Cutting origin area,
13 ... Melt processing zones,
15... Function element,
16 ... Lamination,
21 ... If so,
24 ... split,
25... Semiconductor chip,
71 ... Quality reforming area,
72 ... Segmented reforming region (first reforming region),
73 ... HC modified region (second modified region),
L… Laser Light,
P… Condensing point.
The laser which forms a modified region which becomes a starting point of a cutting along the cut | disconnection line of the said board | substrate by irradiating a laser beam with the condensation point in the inside of the board | substrate with which the laminated part containing several functional elements was formed in the surface inside the board | substrate. As a processing method,
Forming a first modified region along the cutting scheduled line at a position where the distance between the surface and the surface side end portion is set to 5 µm to 15 µm;
And forming at least one row of second modified regions along the cutting scheduled line at a position between the first modified region and the back surface of the substrate.
And forming a first modified region along the cutting scheduled line at a position where the distance between the surface and the surface side end portion is set to 5 µm to 15 µm.
And the first modified region is formed at a position where the distance between the surface and the surface side end portion is set to 5 µm to 10 µm.
By irradiating a laser beam with a light converging point inside a substrate formed on the surface of a laminated portion including a plurality of functional elements, a modified region serving as a starting point for cutting is formed inside the substrate along a cutting schedule line of the substrate. As a laser processing method,
The first modified region along the cutting scheduled line at a position where the distance between the front surface and the rear end portion is [(thickness of the substrate) × 0.1] μm to [20+ (thickness of the substrate) × 0.1] μm. Forming a,
The first modified region along the cutting scheduled line at a position where the distance between the front surface and the rear end portion is [(thickness of the substrate) × 0.1] μm to [20+ (thickness of the substrate) × 0.1] μm. Laser processing method comprising the step of forming a.
Forming the first modified region at a position where the distance between the front surface and the rear end portion is between [5+ (thickness of the substrate) × 0.1] μm to [20+ (thickness of the substrate) × 0.1] μm. Laser processing method characterized by the above-mentioned.
Forming the first modified region at a position where the distance between the front surface and the rear end portion is between [5 + (thickness of the substrate) × 0.1] μm to [10+ (thickness of the substrate) × 0.1] μm. Laser processing method characterized by the above-mentioned.
Wherein said substrate is a semiconductor substrate, and said first modified region and said second modified region comprise a melt processing region.
And said first modified region and said second modified region are formed by one row in order from said back surface in the order of distant from said back surface.
The energy of a laser beam at the time of forming said 1st modified area | region is 2 microJ-50 microJ, The laser processing method characterized by the above-mentioned.
The energy of a laser beam at the time of forming said 2nd modified region is 1 microJ-50 microJ, The laser processing method characterized by the above-mentioned.
The distance from the said back surface of the position which matches the light converging point of a laser beam at the time of forming a said 2nd modified area | region is 50 micrometers-[(thickness of the said board | substrate) x 0.9] micrometers, The laser processing method characterized by the above-mentioned.
The distance from the back surface of the position where the focusing point of the laser light is aligned when forming the second modified region is 20 µm to 110 µm.
And cutting the substrate and the lamination along the cutting schedule line.
A semiconductor chip comprising a substrate and a laminate formed on the surface of the substrate, including a functional element,
In the side surface of the said board | substrate, the 1st modified area | region along the back surface of the said board | substrate is formed in the position where the distance of the said surface and the surface side edge part will be 5 micrometers-15 micrometers,
The semiconductor chip according to claim 1, wherein at least one row of second modified regions along the back surface is formed at a position between the first modified region and the back surface of the substrate.
A side surface of the substrate, wherein the first modified region along the rear surface of the substrate is formed at a position where the distance between the front surface and the surface side end portion is 5 µm to 15 µm.
In the side surface of the said board | substrate, the back surface of the said board | substrate is placed in the position where the distance of the said surface and the back side edge part becomes [(thickness of the said board | substrate) x 0.1] micrometer-[20+ (thickness of the said board | substrate) x 0.1] micrometer. A first modified region is formed,
The semiconductor chip according to claim 1, wherein at least one row of second modified regions along the back surface is formed at a position between the first modified region and the back surface.
In the side surface of the said board | substrate, the back surface of the said board | substrate is placed in the position where the distance of the said surface and the back side edge part becomes [(thickness of the said board | substrate) x 0.1] micrometer-[20+ (thickness of the said board | substrate) x 0.1] micrometer. The semiconductor chip characterized by the above-mentioned 1st modification area | region formed.
Forming the first modified region at a position where the distance between the front surface and the rear end portion is between [5+ (thickness of the substrate) × 0.1] μm to [20+ (thickness of the substrate) × 0.1] μm. A semiconductor chip characterized by the above-mentioned.
The distance between the rear surface side end portion of the opposing first modified region and the surface side end portion of the second modified region is 0 μm to [(thickness of the substrate)-(thickness of the substrate) × 0.6] μm. Semiconductor chip.
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KR1020127024408A KR101336402B1 (en) 2004-03-30 2005-03-25 Laser processing method and semiconductor chip
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