JP5913839B2 - Polishing method - Google Patents

Description

  The present invention relates to a polishing method using an acidic polishing liquid.

  Conventionally, a chemical mechanical polishing method, so-called CMP (Chemical Mechanical Polishing), has been widely adopted as a polishing method capable of forming a surface having excellent flatness in a semiconductor device manufacturing process.

  It is formed by a crystal growth method such as a method of pulling from melted polycrystalline silicon (CZ method), a single crystal silicon ingot formed by a floating zone method, a ribbon crystal growth method (EFG method) or a heat exchange method (HEM method). In the single crystal sapphire ingot or the like, after an unnecessary portion is removed, an orientation flat for designating a plane orientation or a mark called a notch is formed. Thereafter, it is sliced into individual wafers. The sliced wafer is polished and planarized using a CMP method or the like.

  CMP is performed by relatively sliding while rotating the polishing pad and the object to be polished while supplying a polishing liquid (slurry) between the polishing pad and the object to be polished. For example, a polishing method using CMP is disclosed in Patent Document 1.

  As the polishing pad, a nonwoven fabric is generally used, and the surface of the object to be polished is polished while supplying a polishing liquid (slurry) containing free abrasive grains such as silica.

  In addition, for difficult-to-process materials such as single crystal substrates made of silicon carbide (SiC) or gallium nitride (GaN), in the polishing process by the CMP method, an abrasive-containing polishing pad in the presence of an oxidizing polishing liquid It is known that a sufficient polishing efficiency can be suitably obtained by polishing with the use of. Such a technique is disclosed in Patent Document 2, for example.

JP-A-3-248532 JP 2008-68390 A

  Although polishing pads and polishing liquids (slurry) as members necessary in the polishing process by CMP have been improved day by day, they still face problems related to productivity improvement. Therefore, further improvement in productivity is demanded by achieving a high polishing rate.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a CMP polishing method capable of achieving a high polishing rate by CMP polishing and obtaining a good polished surface. .

The gist of the present invention is a method of polishing a SiC wafer with a fixed abrasive polishing pad and a novel acidic polishing liquid in CMP polishing. Specifically, it is a method of polishing a SiC wafer in CMP polishing, a step of holding one surface of the wafer with a holding member, and a base material and abrasive grains made of a polyurethane resin composed of isocyanate and polyol A fixed abrasive polishing pad having a plurality of grooves for discharging a polishing liquid from the central portion toward the outer peripheral portion and contacting the other surface of the wafer, and rotating the polishing pad and the wafer, respectively Polishing step of relatively pressing and sliding at a pressure of 0.8 to 1.5 kg / cm ² , and an acidic polishing liquid in which potassium permanganate (KMnO ₄ ) and an oxidizing inorganic salt are mixed in the polishing step This is a polishing method characterized in that

  The present invention achieves a high polishing rate by polishing an SiC wafer while discharging an acidic polishing liquid in which potassium permanganate and an oxidizing inorganic salt are mixed between the SiC wafer and a fixed abrasive polishing pad. In addition, productivity can be improved.

It is the front view showing the example of the polish processing apparatus used for the polish method concerning the present invention. It is a front view showing the step which hold | maintains the non-polishing surface of a SiC wafer. It is a front view showing the step which contact | abuts a fixed abrasive polishing pad to the grinding | polishing surface of a SiC wafer. It is a front view showing the step which grind | polishes a SiC wafer with a fixed abrasive polishing pad, discharging | emitting polishing liquid. It is a graph which shows the experimental result of the change of a polishing rate when fixing the addition amount of cerium ammonium nitrate to 0.16%, and changing the potassium permanganate addition rate. It is a graph which shows the experimental result which fixed the potassium permanganate to 0.5%, added 0.2% of each oxidizing inorganic salt, and confirmed the polishing rate about each.

  A polishing apparatus 1 shown in FIG. 1 is an apparatus for flattening irregularities formed on the surface of various workpieces such as a SiC wafer 2. The polishing apparatus 1 polishes the chuck table 3 that holds the protective tape 2c attached to the non-polishing surface 2a that is one surface of the SiC wafer 2, and the polishing surface 2b that is the other surface of the SiC wafer 2. The polishing means 14 includes a polishing wheel 10 and a spindle 6.

  As shown in FIG. 1, the chuck table 3 includes a porous holding member 4 provided with an infinite number of minute holes in the upper part thereof. Further, a suction port 5 for sucking the non-polished surface 2 a side of the SiC wafer 2 is formed at a central portion in the center of the chuck table 3, and the connection port 5 a of the suction port 5 is a lower part of the porous holding member 4. It is linked to.

  As shown in FIG. 1, bolts 7 are inserted into both ends of a mount 6 a formed at the lower end of the spindle 6 to fix the spindle 6 and the grinding wheel 10. The polishing wheel 10 includes a base 9 and a fixed abrasive polishing pad 11, and the fixed abrasive polishing pad 11 is fixed to the lower portion of the base 9. A penetrating polishing liquid supply port 8 is formed at the center of the spindle 6 and the base 10, and a connection port 8 a is formed at the lower end of the polishing supply port 8. The connection port 8 a is connected to the central portion of the fixed abrasive polishing pad 11 so that the polishing liquid flows through the connection port 8 a and flows to the fixed abrasive polishing pad 11.

  The spindle 6 can be driven to rotate in the direction of arrow A with the central portion as the central axis. Further, the chuck table 3 can also be rotationally driven in the direction of arrow B with the central portion as the central axis. Further, the spindle 6 and the porous holding member 4 are configured to be able to move horizontally in the directions of the horizontal arrows C1 and C2 simultaneously with the rotational drive described above.

  The fixed abrasive polishing pad 11 is formed using a polyurethane resin composed of isocyanate and polyol as a base material, and innumerable silica abrasive grains are fixed inside the base material.

  The fixed abrasive polishing pad 11 is provided with a plurality of supply grooves 12 for discharging the polishing liquid toward the outer peripheral portion. The supply groove 12 is formed by arranging a plurality of blocked fixed abrasive grains with a constant adjacent interval. When the SiC wafer is actually polished using the polishing method of the present invention, the polishing liquid appropriately supplied from the polishing liquid supply port 8 passes through the supply groove 12, and the SiC wafer 2 and the fixed abrasive polishing pad. 11 is configured to discharge between the two. By providing a plurality of supply grooves 12, the acidic polishing liquid uniformly flows over the SIC wafer 2, so that the chemical mechanical action of the polishing apparatus 1 can be sufficiently exerted, and the polishing surface 2 b of the SiC wafer 2 can be highly polished. Can be flattened.

Hereinafter, the polishing process according to the present invention will be described with reference to FIGS.
(1) Holding Step As shown in FIG. 2, in order to hold the non-polished surface 2a of the SiC wafer 2 with the porous holding member 4, a protective tape 2c is attached to the non-polished surface 2a of the SiC wafer 2, The protective tape 2 c is adsorbed to the porous holding member 4 through the suction port 5 and the hole of the porous holding member 4 by the suction force generated from the suction source that is not. Thereby, the SiC wafer 2 is stably held without being displaced from the chuck table 3 during polishing.

(2) Contact Step Next, as shown in FIG. 3, the spindle 6 and the chuck table 3 are driven to rotate in the directions of arrows A and B, respectively, and the fixed abrasive pad 11 is lowered in the direction of arrow D, The lower part of the fixed polishing abrasive pad 11 is brought into contact with the polishing surface 2 b of the SiC wafer 2. Thereby, the SiC wafer 2 is sandwiched between the fixed abrasive polishing pad 11 and the porous holding member 4.

(3) Polishing Step As shown in FIG. 4, in order to make the polishing surface 2 b of the SiC wafer 2 a good flat surface while rotating the spindle 6 and the chuck table 3, for example, 0.8 to 1 from the polishing means 14. A pressure of 0.5 kg / cm ² is applied to press the polished surface 2b of the SiC wafer 2.

  Thus, while obtaining an appropriate pressure, the fixed abrasive polishing pad 11 and the SiC wafer 2 are slid by the rotational driving of the spindle 6 and the chuck table 3 and the relative horizontal movement in the direction of the horizontal arrow C1, thereby the SiC wafer 2 is slid. The polished surface 2b is polished.

As shown in FIG. 4, in the polishing step, an acidic polishing liquid 13 in which potassium permanganate (KMnO ₄ ) and an oxidizing inorganic salt according to the present invention are mixed is further supplied through the polishing liquid supply port 8. It passes through the groove 12 and is uniformly supplied between the fixed abrasive polishing pad 11 and the polishing surface 2 b of the SiC wafer 2. As a result, the chemical action of the acidic polishing liquid 13 and the mechanical action of the fixed abrasive polishing pad 11 are combined, and the polishing surface 2b of the SiC wafer 2 in contact with the fixed abrasive polishing pad 11 is flattened with high polishing efficiency. Can be polished.

Hereinafter, examples of the present invention will be described with reference to experimental results.
First, with the polishing apparatus 1 shown in FIG. 1, a polishing experiment including the above steps was performed under the polishing conditions for SiC wafers shown in Table 1. Table 2 shows the experimental results confirming the change in polishing rate.

[Table 1]

[Table 2]

  (1) shown in Table 2 shows the amount of polishing when only the fixed abrasive polishing pad is polished. The fixed abrasive polishing pad has colloidal silica abrasive fixed to a hard polyurethane (PI95) pad. Is. (2) to (4) represent cases where polishing is performed by a polishing method using a fixed abrasive polishing pad and a polishing liquid. It can be confirmed that (3) and (4) using a polishing liquid obtained by adding an oxidizing inorganic salt to potassium permanganate has a higher polishing amount than (1) and (2). Particularly in the case of (4), the polishing efficiency is high, a remarkable chemical action effect is exhibited, a good flat surface is obtained, and the productivity can be improved.

Next, an experiment was conducted to obtain the cerium ammonium nitrate addition rate at which the polishing rate was maximized under the condition where potassium permanganate was fixed at 0.5%. The experimental results are as shown in Table 3. Under conditions where potassium permanganate was fixed at 0.5%, it was confirmed that the polishing rate reached a maximum of 122.81 nm / min when the addition amount of cerium ammonium nitrate was 0.16%. Silica is fixed to the fixed abrasive polishing pad, but is not used in the acidic polishing liquid as free abrasive grains.
[Table 3]
0.5% potassium permanganate fixed (no colloidal silica in polishing liquid)

Then, an experiment for confirming the change in the polishing rate due to the potassium permanganate addition rate was performed under the condition that the optimum addition amount of cerium ammonium nitrate 0.16 shown in Table 3 was fixed. The experimental results are as shown in Table 4 and FIG. From this result, it was confirmed that the polishing rate when potassium permanganate was 3% was the highest at 197 nm / min. Therefore, when polishing a SiC wafer, it is desirable to use the acidic polishing liquid according to the present invention in which 3% potassium permanganate and an oxidizing inorganic salt are mixed. Silica is fixed to the fixed abrasive polishing pad, but is not used in the acidic polishing liquid as free abrasive grains.
[Table 4]
Fixed cerium ammonium nitrate 0.16% (no colloidal silica in the polishing liquid)

  Next, when condition 1 is fixed with potassium permanganate at 0.5%, condition 2 is added with an addition ratio of oxidizing inorganic salt to 0.2%, and various oxidizing inorganic salts are added. An oxidizing inorganic salt test was performed to confirm how much the polishing rate difference appears. As the oxidizing inorganic salt, an oxidizing inorganic salt was used for each of cerium ammonium nitrate, ammonium nitrate, ammonium persulfate, iron nitrate, iron chloride, and perchloric acid. The perchloric acid in Table 5 was tested as a control for comparison with cerium ammonium nitrate, ammonium nitrate, ammonium persulfate, iron nitrate, and iron chloride in Table 5. The test results are as shown in Table 5 and FIG. From this result, since perchloric acid is not oxidizing, the polishing rate is the lowest at 57.1 nm / min. However, when the oxidizing inorganic salt is added, the polishing rate is higher than when the oxidizing inorganic salt is not added. It was confirmed that it would be higher. In particular, for cerium ammonium nitrate, it was confirmed that the polishing rate was the highest at 122.5 nm / min.

[Table 5]
Oxidizing inorganic salt test condition 1: Potassium permanganate 0.5% fixed condition 2: Oxidizing inorganic salt addition rate fixed 0.2%

1: Polishing apparatus 2: SiC wafer 2a: Non-polished surface 2b: Polished surface 2c: Protective tape 3: Chuck table 4: Porous holding member 5: Suction port 5a: Connection port 6: Spindle 6a: Mount 7: Bolt 8 : Polishing liquid supply port 8a: connecting port 9: base 10: polishing wheel 11: fixed abrasive polishing pad 12: supply groove 13: acidic polishing liquid 14: polishing means

Claims (1)

A method for polishing a SiC wafer in a CMP polishing process,
Holding one side of the wafer with a holding member;
A fixed abrasive polishing pad comprising a base material composed of a polyurethane resin composed of isocyanate and polyol and abrasive grains and having a plurality of grooves for discharging a polishing liquid from the central portion to the outer peripheral portion is provided on the other surface of the wafer. Abutting step;
A polishing step in which a polishing liquid is discharged from the fixed abrasive polishing pad and the polishing pad and the wafer are each pressed and slid by a relative pressure of 0.8 to 1.5 kg / cm ² while rotating the polishing pad and the wafer; Consisting of
A polishing method comprising using an acidic polishing liquid in which potassium permanganate (KMnO ₄ ) and an oxidizing inorganic salt are mixed in the polishing step.

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