TWI334374B - - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the surface of a honing cloth used in a CMP apparatus (chemical mechanical honing machine; chemica 1 mechanica 1 ρ ο 1 ishing machine) for honing semiconductor wafers. A diamond trimmer that has been trimmed. [Prior Art] The φ semiconductor wafer is manufactured by cutting a crystal ingot into a cylindrical shape and cutting it at a specific thickness. The semiconductor wafer cut into a disk shape is transferred to a processing step of an STD 'ILD, W, Cu process, or the like. In these steps, the semiconductor wafer is chemically and mechanically honed by a CMP apparatus. In the CMP apparatus, a semiconductor wafer is etched using a liquid or the like to which an alkaline liquid or an acidic liquid or a neutral chelating agent is added to perform chemical honing. Next, mechanical honing was carried out using cerium microparticles (free granules). This honing accuracy • has a large impact on the quality of semiconductor wafers. - The CMP device pushes the semiconductor wafer sandwiched by the chuck mechanism onto the honing cloth to perform honing. The honing cloth is stretched on a disc-shaped honing plate. The honing plate is rotated by a rotating mechanism on the lower side. The chuck mechanism is fixed to the lower end of the main shaft that rises and falls above the honing plate. The spindle system and the honing plate rotate in the opposite direction. The semiconductor wafer system sandwiched by the chuck mechanism is pressed against the honing cloth while being rotated by the spindle. In the honing treatment, a slurry containing cerium particles or the like mixed in a lye or the like is dropped on the honing cloth. When the honing cloth is used for a long time in the CMP apparatus, the flat surface of the honing surface -4- 1334374 degrees is lowered and clogging occurs. At the same time, the honing accuracy or honing efficiency of semiconductor wafers is reduced. Thus, a dresser that trims the surface state of the honing cloth is used. The dresser is formed into a disc shape that can be pushed against the honing cloth for rotation. A robotic arm that supports the dresser moves the dresser over the honing cloth. By this action, the dresser can uniformly contact the entire surface of the honing cloth. The trimming machine grinds the surface of the honing cloth to create a new surface while optimizing the surface roughness. The dresser is required to have an efficient dresser function and durability φ. These techniques are described in the following documents (see Patent Documents 1 to 4). [Patent Document 1] Japanese Laid-Open Patent Publication No. 2001-341061 (Patent Document 3) Japanese Laid-Open Patent Publication No. 2003-230061 (Patent Document 4) Japanese Patent Laid-Open No. 2003-94332 [Brief Description of the Invention] [Problems to be Solved by the Invention] The above-described conventional dresser has insufficient disadvantages in that the honing function of the honing cloth is further stabilized and required, and the life is short. It is an object of the present invention to provide a diamond dresser that is highly practical and has a long life. [Means for Solving the Problem] The present invention solves the above problems in accordance with the configuration of the second embodiment. (Configuration 1) -5 - 1334374 A diamond dresser which is a trimmer for trimming the surface state of a polishing cloth used in a CMP apparatus for honing a semiconductor wafer, characterized in that: a disc-shaped finisher substrate: and a plurality of concentric ribbon-shaped diamond-grain bonded portions disposed on the trimmer substrate and separated by an annular groove; and bonded to the adhesive layer via the adhesive layer The diamond granules on the surface of the diamond 黏 黏 , , , , , , , , , 且 且 且 且 , , , , , , φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ φ The adjustment is performed in such a manner as to form a substantially flat surface. Since there are a plurality of concentric ribbon-shaped diamond-grain bonded portions, each of which is bonded to different types of diamond crucibles, the surface roughness can be optimized while suppressing the abrasion of the honing cloth. (Construction 2) A diamond dresser, such as the diamond dresser of the first aspect, characterized in that an annular groove is formed on the surface of the dresser substrate, and a plurality of diamond 砥 grain bonding portions formed by concentric φ strips are formed. . - The trimmer can be formed into a solid construction in one piece.构成' (Configuration 3) A diamond dresser, such as the diamond dresser of the first embodiment, characterized in that the diamond enamel bonding portions are each formed by a ring block and are embedded in the dresser substrate. The recess is fixed by bolt fixing or adhesive. The diamond enamel bonding portion composed of the annular block can be freely and easily replaced with -6 - 1334374, and the maintainability is good. (Construction 4). A diamond dresser, such as a diamond dresser constituting I or 2, characterized in that: on the finisher substrate, a strip portion which is separated from each other by an annular groove is provided The strip portion and the center round portion of the inner circumference, and the diamond granules of the particle size of JIS size #400 to #80 are adhered to the strip portion on the outer circumference, and the belt of the outer circumference is adhered to the belt portion at the inner circumference of φ. Diamond granules of smaller particle size. Diamond granules with a larger diameter on the outer circumference can be used to quickly make a new surface on the honing cloth, and the diamond granules having a smaller particle diameter in the inner circumference can be finely finished. (Configuration 5) A diamond dresser, such as a diamond dresser constituting 1 or 2, characterized in that: on the finisher substrate, there are provided a strip portion which is separated from each other by an annular groove and The strip portion and the center round portion of the inner circumference are bonded to the belt/shaped portion of the outer circumference with diamond granules of a particle size of JIS size #400 to #80, and the belt at the inner circumference is bonded to the belt at the outer circumference. Diamond granules with a larger particle size of the larger size can be made from a diamond granule with a smaller outer diameter, and the diamond granules with a larger inner diameter can be coarsely finished. Therefore, the surface roughness can be adjusted to a sufficient thickness while minimizing the abrasion of the honing cloth. 1334374 (Configuration 6) A diamond dresser, such as the diamond dresser of the 1 or 2, characterized in that: on the dresser substrate, a strip portion and an inner portion separated from each other by an annular groove are provided The strip portion and the center round portion of the circumference, and blocky diamond particles are adhered to the outer band portion, and sharp diamond particles are adhered to the inner band portion*. . The sharpness of the edge of the φ block diamond is lower than that of the sharp diamond. Moreover, the former is less prone to mechanical damage than the latter and is also likely to fall off. Therefore, first grind the surface of the honing cloth with a block of diamond granules, and then finish it with sharp diamond granules. According to this, the durability of the dresser is improved. (Structure 7) A diamond dresser, such as a diamond dresser constituting 6, characterized in that: a block of diamond granules is adhered to the outer band portion of the outer circumference. Sharp-shaped diamond granules, and diamond granules having a smaller particle size than the inner circumferential band are adhered to the outer band. 'The sharp-shaped diamond granules are formed into a large particle size to improve durability. (Structure 8) A diamond dresser, such as the diamond dresser of the sixth embodiment, characterized in that: the block-shaped diamond granules are adhered to the outer band portion, and the inner portion of the belt 1334374 is bonded to the inner portion. The diamond granules are in the form of diamond granules having a smaller particle size than the inner circumferential band portion in the outer band portion. Finely finished diamond fines with a smaller inner diameter can be used. A diamond dresser, such as a diamond dresser constituting 1 or 2, characterized in that: on the dresser substrate, a strip portion and an inner circumference strip which are separated from each other by an annular groove are provided When the radius of the dresser substrate is set to 1 ,, the width of the outer peripheral strip-shaped portion is 2 or more and 30 or less, and the width of the inner peripheral strip-shaped portion is 2 or more and 50 or less, and the center circle When the radius of the center portion is 20 or more, the size is selected. If the radius of the center circle portion is less than 20, the circumferential velocity of the center portion is slow, so that sufficient trimming cannot be performed. The width of the outer peripheral strip portion and the width of the inner peripheral strip portion may be selected in accordance with the division of the inner peripheral strip portion into a new surface by the strip portion on the outer circumference and finishing by the inner strip portion. . (Structure 10) A diamond dresser, such as the diamond dresser of the ninth aspect, characterized in that the dimension of the inner peripheral strip portion in the radial direction is longer than the outer peripheral strip shape. In order to fully exert the finishing completion function of the honing cloth, it is preferable that the width of the inner circumferential band portion is wider. (Composition Π) -9- 1334374 A diamond dresser, such as a diamond dresser constituting 1 to 9, characterized in that a bevel is present on the outermost periphery of the outer band, and a diamond is also adhered to the bevel. grain. When the dresser substrate is pushed against the honing cloth, the bevel will first come into contact with the honing cloth. Therefore, the honing efficiency is improved because the diamond granules are adhered there. (Structure 12) A diamond dresser, such as the diamond dresser of the composition 11, characterized in that the diamond enamel having a larger particle diameter than the other faces is adhered to the inclined surface. Since this part exerts the most mechanical stress, the diamond granules have high bonding strength and large particle diameter. (Structure 13) A diamond dresser, such as a diamond dresser constituting 1 to 9, characterized in that: a diamond is adhered to the upper surface and the side surface of each strip portion separated by an annular groove砥 granules. / According to this, the diamond particles can be firmly fixed to the edge of the groove. In addition, the substrate surface can be used widely and effectively. (Configuration 14) A diamond dresser which is a dresser for honing cloth in a CMP apparatus for honing a semiconductor wafer, comprising: a disc-shaped finisher substrate; and an integral expansion of the trimmer substrate The surface of the ring is formed into a ring-shaped short arc-shaped diamond 黏 grain bonding portion formed around the outer -10- 1334374; and the inner side of the short-arc-shaped plurality of diamond 砥 grain bonding portions is short. An arc-shaped plurality of diamond 黏 黏 ; ;; and a _ 经由 经由 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 该 , , , , , , , And the surface of the dresser after the diamond granules are bonded to each other. [Embodiment] Hereinafter, a diamond embodiment of the present invention will be described in detail using the drawings. Fig. 1 is a plan view showing the main part of the diamond dresser of the first embodiment. A cross-sectional view of the main part of the diamond dresser of Example 2. A cross-sectional view of the main part of the diamond dresser of the 43rd. Figure 5 is a cross-sectional view of the main part of the diamond dresser. Fig. 6 is a plan view showing an arrangement example of the φ diamond 黏 particle bonding portion. Fig. 7 is a perspective view showing an example of a CMP honing device of the whole device. Fig. 8 is an explanatory view showing the effect of the above-mentioned diamond dresser. The CMP honing device shown in Fig. 7 (chemical mechanical system uses honing cloth (Clining cl〇th) C, honing half ϋ. Diamond dresser 1 is used to trim the honing cloth C. The semiconductor crystal grinding process has ILD, STI, Cu process. CMP honing process requires different honing conditions. As shown in Figure 7(a), the CMP honing device is bonded to a plurality of diamonds by forming a vortex layer in the ring. Types of diamonds form the same flat

The actual picture of the dresser. Fig. 2, Fig. 3, Fig. 3, embodiment of Example 4, use of diamond repair, Fig. 9 is a real honing machine), kite wafer W, circle W is placed in each system by rotation axis A -11 - 1334374 The honing plate B disposed at the upper end of the rotating shaft A is rotationally driven. The honing plate B is provided with a honing cloth C» above the honing plate B. A main shaft D that is freely movable in the opposite direction to the rotating shaft A is disposed. The chuck mechanism E' disposed at the lower end of the spindle D sandwiches the semiconductor wafer W. The semiconductor wafer W and the honing plate B are rotated while dropping a slurry of ruthenium or the like mixed with ruthenium or the like on the upper surface of the honing cloth c. Accordingly, the semiconductor wafer W is subjected to CMP honing processing. When the honing cloth C continues to perform CMP honing for a long time, the flatness of the honing surface is lowered. Moreover, blockages can occur. This causes the honing accuracy or the honing efficiency of the semiconductor wafer W to be lowered. Therefore, a mechanical arm F that protrudes from the side of the honing plate B toward the upper side of the honing cloth C and that can advance and retreat is provided. A rotating shaft is provided at the front end of the robot arm F, and the dresser 1 is fixed to the lower end of the rotating shaft. Next, the dresser 1 is rotated while being advanced and retracted from at least the outer circumference of the honing plate B to the vicinity of the center. Accordingly, the trimmer 1 is used to trim the condition of the honing cloth C. As shown in Fig. 7(b), the dresser 1 is pressed against the honing cloth C in a slightly inclined state to move in the direction of the arrow 10. Initially, the outer peripheral edge portion of the front side is in contact with the honing cloth as viewed from the traveling direction of the dresser 1 (the direction of the arrow 10). Then, the outer peripheral portion of the dresser 1 is in contact with the honing cloth. The outer peripheral portion of the dresser 1 contributes to the process of generating a new face of the honing cloth. Then, the inner peripheral portion of the dresser 1 is in contact with the honing cloth. Here, the finishing completion processing is performed. Viewed from the direction of travel of the dresser 1, the rear portion facilitates finishing. -12- 1334374 [Embodiment 1] As shown in the plan view of Fig. 1 and the longitudinal sectional view of Fig. 2, the dresser substrate 2 has a disk shape in which annular groove 3 is formed at two places. This is formed of a metal such as stainless steel or an aluminum ceramic. Also, it can be made of hard plastic. A plurality of diamond enamel bonding portions 4 are formed on the surface of the finisher substrate 2, and are formed concentrically via the annular grooves 3. In the example of the figure, φ has an annular groove 3 at two places. According to this configuration, a circular diamond enamel bonding portion 4A located at the center side, a band-shaped diamond enamel bonding portion 4B on the outer side, and an outermost band-shaped diamond enamel bonding portion 4C are formed. Further, in the embodiment of Fig. 1, annular groove 3 is formed at two places. However, it can be one place or three places. When one is formed, the diamond 黏 grain bond becomes two. When three places are formed, the diamond granules are bonded to four. Further, as will be described later, the diamond portion may not be bonded to the circular portion of the center portion. Push the diamond dresser to the honing cloth to start φ. When the Φ is trimmed, the pushing force will slightly bend the whole. That is, the diamond repairer will be elastically deformed by the pushing force. A circular plate having an annular groove is more elastically deformed by a pressing force than a completely non-grooved circular plate. The two annular grooves are the junctions of the particle size changes of the diamond granules. Here the disc can be bent. Accordingly, the effect of the inner peripheral portion determining the thickness of the finished surface of the honing cloth can be improved. A variety of diamonds, 6A, 6B, and 6C are artificial diamonds. The diamond granules 6A, 6B, and 6C of each of the diamond granule adhering portions 4A, 4B, and 4C are, for example, different in particle size. Also, for example, the particle size is the same, but the respective hard -13 - 1334374 degrees are different. Further, for example, the particle shape on one side has a circular portion, and the particles on the other side have an acute angle portion. As described above, each makes the species different. The shape in which the shape of the particle has a circular portion is referred to as a blocky one, and the one in which the particle has an acute angle portion is referred to as a sharp shape. For the same granularity, from block to sharp, you can select, for example, the catalogue of DIAMOND INNOVATIONS, INC. On the upper surface of the diamond enamel bonding portion 4 and the upper side of the side, diamond granules 6-8, 63, and 6 are adhered via the adhesive layer 5 (: as shown in Fig. 2, etc., at the outermost periphery A bevel is formed on the outer peripheral edge portion of the diamond enamel bonding portion 4. The diamond enamel particles 6C are also adhered to the upper side of the slanted surface via the adhesive layer 5. In this embodiment, even the diamond granules 6A, 6B of different types are different. 6C is adhered to the upper surface of each diamond 黏 grain bonding portion 4A' 4B, 4C, and the surface of the bonded diamond dresser 1 can also be adjusted to be in the same plane shape. Therefore, in this example, the height of the surface of the substrate 2 It can be adjusted. In fact, the difference in soundness is within 0.5mm or so. Therefore, the surface of the diamond dresser 1 should be formed as a substantially flat surface. If the difference in outer diameter of each diamond magnetic particle is If it is not more than 0.5 mm, it is not necessary to adjust the height of the substrate. Further, the annular groove is not necessarily formed by cutting on the substrate. Each of the different types of diamond particles 6A, 6B, and 6C are adhered at a certain interval. When it is connected in a ring shape, it can automatically form a groove between them. This is also called a ring. Grooves. The following 'describes the meaning of bonding different types of diamonds. (Example 1) -14- 1334374 First, the first example is the bonding of massive diamond particles to the outer band. In the inner circumference of the strip, there is a sharp-shaped diamond enamel. Since the circular portion at the center side has a slower rotation speed and a smaller honing effect, the diamond granules may not be bonded. In the second example, The diamond granules of the particle size of JIS size #400 or more and #80 or less are bonded to the outer band of the outer circumference, and the diamond granules having a particle size larger than the particle size of the outer peripheral band are bonded to the inner band portion. At 400 o'clock, the honing effect is too small. If it is below #80, φ is thicker than the surface roughness after finishing, so the range is suitable. In addition, the JIS specification #4 00~#80 granularity The average particle size is from about 45 // m to about 250 # m. Ideally, the average particle size is 20% difference. If the average particle size is less than 20%, all of the same type of diamond particles are used. In comparison, the difference in effect does not appear adequately. Focus on the drill fixed to the face of the dresser In the case of the particle size of the granules, the larger the particle size, the coarser the surface roughness of the honing cloth after the finishing is completed. The larger the particle size of the granules, the faster the honing cloth is cut. The larger the diameter, the thicker the surface roughness of the honing cloth after the finishing is completed. However, the pre-* condition is that the diamond granules are manufactured under substantially the same conditions. Focus on the surface of the diamond granules In the state, the sharper the surface, the sharper the sharper, the more profitable. For example, the diamond granules with more impurities have more irregular irregularities on the surface and higher surface sharpness. Even the same particle size is delayed. Granules, compared with those with a lower surface sharpness, have a higher surface sharpness and a faster cutting of the honing cloth. The surface sharpness is higher, and the surface roughness of the honing cloth after finishing is finished. Will become thicker. In addition, if the hardness of the diamond granules 6 is hard, the honing ability will become higher; for the softer ones, the honing ability will be lower -15 - 1334374. When trimming the surface of the honing cloth, first, the thickened surface is cut to create a new surface, and then the finishing is completed for the desired thickness. Conventionally, a diamond disk disk having a uniform homogeneity is fixed on the entire surface. However, when the roughened surface is finished with only the large-diameter diamond granules, the excessive wear of the honing cloth is extremely fast when a new surface is produced. That is to say, the honing cloth is excessively ground before the finishing is completed. Therefore, first use the outer block diamond to grind the surface to grind the cloth, and then use the inner sharp diamond to grind the grain, or to use the outer diamond to make the grain smaller. , the new surface is made, and then the diamond is finished with the larger diameter of the inner circumference. Accordingly, the durability of the dresser is improved. In the case where the wear of the honing cloth is minimized, the surface roughness at the time of completion is adjusted to a sufficient thickness. The diamond granules adhered to the outer band of the dresser substrate 2 contact the polishing cloth at a high speed and at a high pressure. Further, the vibration of the outer circumference of the finisher substrate 2 in the direction perpendicular to the surface of the honing cloth is more intense than the vicinity of the inner circumference. Diamond granules are easily damaged by mechanical damage and are easy to fall off. However, the mechanical strength of the particle size diamond or block diamond is stronger than that of the stone or the sharp diamond. Moreover, when rubbing, the mechanical resistance is also relatively small. Therefore, durability is high. The strength of the base can also be averaged, and the overall durability is excellent. For example, in the ILD process of the CMP honing device, it is necessary to perform a certain amount of surface granules to the abrasive cloth to complete the processing of the coarse 硏. Honing the cloth, either of them will be finished and tied to the nearby, therefore, the smaller the larger the honing board. Faster -16- 1334374 honing speed of semiconductor wafer w. When the surface roughness of the honing cloth c is made coarse, the honing speed of the semiconductor wafer W becomes faster. Due to the large mechanical diameter of the diamond granules or the sharp diamond granules, the mechanical load is large, so it is easy to fall off and the abrasion is also very strong. Therefore, it causes a scratch on the semiconductor wafer W after the processing of the CMP honing device. Then, as described above, diamond granules or block-shaped diamond granules having a small particle diameter are disposed in the strip portion on the outer periphery of the substrate. For example, MB G6 80 (manufactured by φ Diamond Innovation Co., Ltd., average particle size X = 160 #m) is used as a block-shaped diamond. Further, MBG620 (ibid., average particle diameter X = 160 / / m) was used as a sharp diamond crucible. According to the above configuration, as compared with the case where the entire surface of the substrate is made of MBG620 (manufactured by Diamond Innovation Co., Ltd.), the scratch of the semiconductor wafer W is less overwhelming. In the inner peripheral belt portion, when the sharp diamond granule MBG620 is used, the surface roughness of the honing cloth C after finishing is the same. • In addition, the outer band must be adjusted for overgrinding when making a new surface on the honing cloth. Therefore, the width of the inner band portion in the radial direction may be selected such that the size of the strip portion is larger than the outer band shape. More specifically, when the radius of the dresser substrate is set to 100, the width of the outer peripheral strip-shaped portion is 2 or more and 30 or less, the width of the inner peripheral strip-shaped portion is 2 or more and 50 or less, and the radius of the central round portion is 20 The above method is preferred to select the size. When the width of the outer peripheral band portion is 2 or less, the arrangement of the outer peripheral band portion becomes meaningless. If the width of the outer peripheral strip exceeds 30, the effective width of the inner peripheral strip portion becomes too narrow. If the width of the inner band of the -17-1334374 is less than 2, the inner band portion is set to be wider than 50 when the width of the inner band is more than 50. The radius of the center circle is determined by the outer and inner circumferences and is automatically set. (Example 2) Further, the scratch of W in the STI process of the CMP honing device is further reduced. Moreover, it is desirable to have a life. In the prior art, it is considered to use a smaller particle size instead of the MBG620. However, only use, there will be a shortcoming of slow speed. Then, a small particle diameter X = 90 / zm) was used for the band portion on the outer circumference, and the particles (X = 160 #m) were formed in the band portion on the inner circumference. As a result, the outside of the dresser will increase and the scratches will decrease. Further, by the inner circumference of the diamond granules, the honing speed of the semiconductor wafer W caused by the surface roughness of the honing cloth C can be increased as a whole, and the life of the dresser can be improved. (Example 3) On the other hand, Cu etching in a CMP honing device becomes a problem. It is known that if the honing cloth is thin, the depression and corrosion are less. However, it does not make sense to use it. A trimmer with a longer semiconductor wafer life is desired if a valid outer band-shaped strip is left. The MBG680 is used as a diamond granule for the dresser of the MBG680. (The average size of the large-diameter mechanical band of the large-diameter diamond 砥-belt is thicker, so the 硏 is also faster. Moreover, When the life becomes about twice as effective, the surface roughness of the depression and the rot C is, for example, a finer diamond 砥-18-1334374 (for example, the average particle diameter X=l〇/zm), although the depression and corrosion are less. However, there is a problem that the life of the diamond dresser becomes extremely short. Therefore, in this example, a large-diameter diamond granule (for example, an average particle diameter of X=40/zm) is used in the outer band portion. The strips of the circumference are made of diamond particles of small particle size (for example, the average particle diameter X = 1 0 em ). In order to make this; the height of the particles is approximately the same, the bonding is preferred. Compared to the case of using finer diamond granules (for example, average particle size X = φ \ 〇 β m), the depressions and corrosion can be reduced to approximately the same extent. Furthermore, the life of the diamond dresser can be reduced to approximately two times. In addition, practically, the drill of the JIS specification #400 to #80 is bonded to the strip portion on the outer circumference. In the case of the granules, the diamond granules having a particle size smaller than the outer-circumferential band at the inner circumference are preferable. The reason is the same as in the case of Example 1. When the thickness exceeds #400, the honing effect is too small. In addition, when it is less than #80, the surface roughness after finishing is too thick, so the range is suitable." It is preferable that the average particle diameter is 20% or more. If the difference in particle size is less than 20%, the difference in the effect of the same type of diamond granules will not be sufficient. For example, in the center side; the round shape of the diamond 黏 grain bonding part, use # 200 diamond granules 6. The diamond granules 4 in the inner band of the band are made of #12 〇 diamond 砥 granules. In the ring-shaped diamond 黏 grain bonding part 4 of the outer band, use # 80 diamond granules 6. According to this, the function of the desired purpose can be obtained. Further, as shown in Fig. 2 and the like, the upper surface of each diamond granule bonding portion 4 and the upper side surface thereof are bonded. The layer 5 is bonded with diamond enamel particles 6A, 6B, 6C» at the outer peripheral edge portion of the diamond granule bonding portion 4 located at the outermost periphery -19- 1334374 There is a bevel. Diamond bead 6C is also adhered to the upper side of the bevel via the adhesive layer 5. As shown in the description of Fig. 7(b), the outer periphery and the outer periphery of the diamond dresser 1 become acute angles. The surface of the honing cloth C is honed. Further, the edge of the outer edge of the strip portion and the edge of the outer periphery of the round diamond splicing portion can be honed. That is, it can be utilized with good efficiency. The honing is performed on the entire surface of the substrate 2. φ [Example 2] As shown in Fig. 3, the diamond enamel adhering portions 4D and 4E' 4F are each formed of a ring-shaped block, and are formed on the dresser substrate 2. The recessed portions 3D, 3E, 3F » diamond enamel adhesion portions 4D, 4E, 4F are embedded in the recess portions 3D, 3E, 3F. Both are fixed by bolting or adhesive. As described above, the diamond enamel adhering portions 4D, 4E, and 4F composed of the annular blocks can be freely and easily replaced, and therefore have excellent maintainability. φ [Example 3]

In the first embodiment, the particle sizes of the diamond granules 6A, 6B, and 6C adhered to the respective diamond granule bonding portions 4A, 4B, and 4C are different. Further, by adjusting the heights of the diamond grain bonding portions 4A, 4B, 4C, the difference in the size of the particles is absorbed to make the surface of the dresser 1 flat. In the third embodiment shown in Fig. 4, the thickness of the adhesive layer 5 of the adhesive is adjusted to make the surface of the dresser 1 flat. [Example 4] -20- 1334374 In Example 2, the particle sizes of the diamond granules 6D, 6E, and 6F adhered to the respective diamond granule bonding portions 4D, 4E, and 4F were set to be different. Further, the difference in the size of the particles is absorbed by adjusting the height ' of the massive diamond-grain bonded portions 4, 4E, 4F to make the surface of the dresser 1 flat. In the fourth embodiment shown in Fig. 5, the thickness of the adhesive layer 5 of the adhesive is adjusted to make the surface of the dresser 1 flat. φ [Embodiment 5] In the fifth embodiment, as shown in Fig. 6, on the surface of the disc-shaped finisher substrate 2, a plurality of short-arc-shaped diamond-grain bonded portions 4G and 4H are disposed. These diamond enamel bonding portions 4 are formed so as to be swelled integrally on the surface of the dresser substrate 2. Further, on the outer periphery of the finisher substrate 2, the diamond-grain bonded portions 4G are arranged in a ring shape. Further, on the inner side of the finisher substrate 2, the diamond enamel adhering portion 4H is provided in a spiral shape. • Here, the diamond sarcophagus adhered to the diamond granule bonding portion 4G at the outer periphery and the diamond bonded to the diamond granule bonding portion 4H located inside; the granules are different types Composition. Thereby, the same functions as those of the above embodiment can be exerted. Fig. 8 is an explanatory view showing the relationship between the surface roughness and the honing time. In the graph of Fig. 8, the vertical axis indicates the surface roughness Ra, and the horizontal axis indicates the honing time (hr). The number on the right side of the graph is the diamond of the outer peripheral strip and the inner peripheral strip. The particle size is represented by JIS. For example, SD100-SD60 means that the outer band portion is #1〇〇, and the inner band portion -21 - 1334374 is #60 diamond 砥 particles. SD100 (only on the outside) means that the ribbon is not bonded to the inner part of the band. The graph in Fig. 8 demonstrates the fact that the surface roughness after finishing of the honing cloth is determined by the particle size of the diamond granules in the inner circumferential band. Fig. 9 is an explanatory view showing a change in the honing speed of the honing cloth. The vertical axis of the graph of Fig. 9 indicates the honing speed ('m/hr), and the horizontal axis indicates the honing time (hr). The number on the right side is the same as in Figure 8. The graph in Fig. 9 demonstrates the case where the honing speed of the honing cloth is also determined by the particle size of the diamond granules in the inner φ band. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view showing a diamond dresser of the first embodiment. Fig. 2 is a cross-sectional view showing the main part of the diamond dresser of the first embodiment. Fig. 3 is a cross-sectional view showing the main part of the diamond dresser of the second embodiment. Fig. 4 is a cross-sectional view showing the main part of the diamond dresser of the third embodiment. Fig. 5 is a cross-sectional view showing the main part of the diamond dresser of the fourth embodiment. Fig. 6 is a plan view showing an arrangement example of the diamond-grain bonding portion of the fifth embodiment. Fig. 7 is a perspective view showing an example of a CMP honing device using a diamond dresser. Fig. 8 is an explanatory view showing the relationship between the surface roughness and the honing time. Fig. 9 is an explanatory view showing a change in the honing speed of the honing cloth. [Main component symbol description] W: Semiconductor wafer-22- 1334374 c : Honing cloth 1: Diamond dresser 2: Dresser substrate 3: Annular groove 4: Diamond 黏 grain bonding portion 5: Bonding layer 6 : Diamond granules

Claims (1)

1334374 9 X. Patent Application No. 096 127776 Patent Application Chinese Patent Application Revision Amendment September 16, 1999 曰 Amendment 1. - A diamond dresser that will be used to honing semiconductor wafers in a CMP device A dresser for trimming the surface of the polishing cloth to be used, comprising: a disc-shaped dresser substrate; and being disposed on the trimmer substrate and having a ring shape a plurality of concentric ribbon-shaped diamond-grain bonded portions separated by a groove; and diamond magnetic particles adhered to the surface of the diamond-grain bonded portion via the adhesive layer, and the diamond-grain bonded portions, Each of the different types of diamond particles is bonded, and the surface of the dresser after the diamond particles are bonded is adjusted to form a substantially flat surface. • On the surface of the dresser substrate, a concentric strip is formed. The plurality of diamond enamel adhesion portions are formed by a strip-shaped portion and an inner peripheral strip portion and a central circular portion which are separated from each other by an annular groove, and are bonded to the outer peripheral strip portion. Have: average grain In the diamond granules having a particle diameter of 45 or more and an average particle diameter of 250 or less, the inner peripheral band portion is adhered with an average particle diameter of 20% or more different from the outer peripheral band portion, and the particle diameter is smaller than the outer circumference. The particle size of the strip of diamond particles. 1. The diamond dresser of the first aspect of the invention, wherein the width of the outer peripheral strip portion is 2 or more and 30 or less when the radius of the dresser substrate is set to 100. In the case where the radius of the center circular portion is 2 or more and 50 or less, the size is selected to be 20 or more, and the inner circumferential band portion has a longer dimension in the radial direction than the outer circumferential band portion. 3_ The diamond dresser of claim 2, wherein a bevel is present on the outermost circumference of the outer peripheral strip, and diamond crucible is also adhered to the bevel, and the bevel is bonded to the inclined surface. Larger diameter diamond granules. 4. A diamond dresser which is a dresser for trimming a surface state of a honing cloth used in a CMP apparatus for honing a semiconductor wafer, characterized by: having a disk shape a trimmer substrate; and a plurality of concentric ribbon-shaped diamond-grain bonded portions disposed on the trimmer substrate and separated by an annular groove; and a diamond enamel adhered thereto via the adhesive layer The diamond on the surface of the grain bonding part is granulated, and the diamond granules are bonded to different types of diamond granules, and the surface of the dresser after the diamond granules are bonded is formed into a substantially flat surface. Adjusting, on the surface of the above-mentioned finisher substrate, a plurality of concentric strip-shaped 1334374 diamond enamel adhesion portions are formed, which are: a strip portion and an inner circumference strip which are separated from each other by an annular groove And a central portion of the inner circumference of the strip portion having an average particle diameter of 45 or more to an average particle diameter of 250 #m or less, and the inner peripheral strip portion is bonded to the outer peripheral strip portion. Bonding: average particle size and above Differences over the strip portion 20%, and the particle size is larger than the outer periphery of the belt-like portion of diamond abrasive grains. 5. A diamond dresser which is a dresser for trimming the surface state of a polishing cloth used in a CMP apparatus for honing a semiconductor wafer, characterized by: having a disk shape a trimmer substrate; and a plurality of concentric ribbon-shaped diamond-grain bonded portions disposed on the trimmer substrate and separated by an annular groove; and a diamond enamel adhered thereto via the adhesive layer The diamond granules on the surface of the grain bonding part, and the bonding parts of the diamond granules are respectively bonded to different types of diamond granules, and the surface of the dresser after the diamond granules are bonded is formed into a substantially flat surface. Adjusting, on the surface of the dresser substrate, a plurality of concentric ribbon-shaped diamond-grain bonded portions are formed by: a strip-shaped portion and an inner peripheral strip separated by an annular groove The portion and the central portion are formed, and a biocky diamond crucible is adhered to the strip portion on the outer circumference, and a sharp diamond crucible-3 is adhered to the inner peripheral strip portion. - 1334374 Private, bonded in the outer band The inner circumference of the strip has a larger particle size of the diamond granule. A diamond dresser which is a dresser for trimming the surface state of a polishing cloth used in a CMP apparatus for honing a semiconductor wafer, characterized by: having a disk-shaped trimming And a plurality of concentric ribbon-shaped diamond-grain bonded portions disposed on the substrate of the trimmer and separated by an annular groove; and bonded to the diamond particles via the adhesive layer The diamond granules on the surface of the joint, and the diamond granules of the joints are bonded to different types of diamond granules, and the surface of the dresser after the diamond granules are bonded is adjusted to form a substantially flat surface. a plurality of concentric strip-shaped diamond-grain bonded portions formed on the surface of the trimmer substrate, wherein the strip portions and the inner peripheral strip portions are separated from each other by an annular groove In the center round portion, a biocky diamond crucible is adhered to the strip portion on the outer circumference, and sharp diamond grains are adhered to the inner peripheral strip portion, and the outer circumference is adhered to the outer circumference. The band is bonded to the inner band Smaller particle size diamond abrasive grains. -4 - 1334374 7. A diamond dresser for trimming the surface state of a polishing cloth used in a CMP apparatus for honing a semiconductor wafer, characterized by: a plate-shaped finisher substrate; and a pant disposed on the dresser substrate, and a plurality of concentric ribbon-shaped diamond-grain bonded portions separated by an annular groove; and being adhered thereto via an adhesive layer The diamond enamel on the surface of the diamond 黏 黏 , , , , , , , , , , 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥 砥In the manner of adjusting the surface of the dresser substrate, a plurality of concentric ribbon-shaped diamond-grain bonded portions are formed by: a strip portion and an inner circumference separated from each other by an annular groove The strip portion and the central round portion are formed, and sharp diamond granules are adhered to the strip portion on the outer circumference, and a blocky diamond gang is adhered to the inner peripheral strip portion.丄fAi.' Bonding in the outer band There are diamond particles larger than the inner circumference of the strip. 8. A diamond dresser which is a trimmer for trimming the surface state of a polishing cloth used in a CMP apparatus for honing a semiconductor wafer, characterized in that: -5 - 1334374 has: a disc-shaped finisher substrate; and a plurality of concentric strip-shaped diamond-grain bonded portions disposed on the trimmer substrate and separated by an annular groove; and bonded thereto via an adhesive layer The diamond granules on the surface of the diamond granules are bonded to each other, and the diamond granules are bonded to different types of diamond granules, and the surface of the dresser after the diamond granules are bonded to form a substantially flat surface. In a manner of adjusting the surface, a plurality of concentric ribbon-shaped diamond-grain adhesion portions are formed on the surface of the dresser substrate, and are: a strip portion and an inner circumference separated from each other by an annular groove The strip portion and the central portion are formed, and sharp diamond particles are adhered to the strip portion on the outer circumference, and a bio cky diamond is adhered to the strip portion on the inner circumference. The granules are bonded in the outer band More circumferential strip portion diamond abrasive grains of small particle size. 9. The diamond dresser of any one of claims 1 to 8 wherein the above-mentioned bonded strip has a smaller particle size than the strip of the diamond granule having a larger particle size. The strip of the diamond enamel has a longer dimension in the radial direction. 10. The diamond dresser of any one of claims 1 to 8 wherein 'there is a bevel on the outermost periphery of the outer peripheral strip portion, and the bevel is also adhered to the beveled surface at -6 - 1334374 A diamond granule having a larger particle diameter than the other surfaces is adhered to the inclined surface. 11. The diamond dresser of claim 9, wherein a bevel is present on an outermost periphery of the outer peripheral strip portion, and diamond crucibles are also adhered to the bevel surface, and the bevel is bonded to the inclined surface. Larger diameter diamond granules.