KR100442194B1 - Electrodes For Dry Etching Of Wafer - Google Patents

Abstract

The present invention relates to an electrode for wafer dry etching, wherein the electrode of the present invention comprises a first and a second pair of electrodes, wherein the first electrode has an annular first protrusion facing one of the upper and lower portions of the wafer edge. And a first non-projection portion, wherein the second electrode faces the other side of the upper and lower portions of the edge of the wafer and has a second protrusion and a second ratio having the same dimensions as the first protrusion and the first non-projection portion. It is characterized by having a protrusion.

As a result, the semiconductor manufacturing process eliminates all the foreign matter deposited on the upper and lower sides of the wafer edge, as well as on the side and the lower surface of the semiconductor manufacturing process, thereby simplifying the process and reducing the process cost, yield, quality and productivity. It has the effect of contributing to improvement.

Description

Electrodes For Dry Etching Of Wafer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to dry etching of semiconductor wafers, and more particularly, to a wafer dry etching electrode for removing, by plasma, various foreign matters accumulated on edge portions of semiconductor wafers for fabricating integrated circuit devices.

Typically, in the process of manufacturing a highly integrated semiconductor device, as shown in FIG. 5, poly films, nitride layers, metal layers, etc. 110 and 120 are formed and accumulated at edge portions of the wafer 100. In addition, as shown in FIG. 6, the edge material of the wafer 100 may be broken and introduced into the wafer 100 due to the transportation of the wafer 100 or the contact with the equipment 200.

In addition, recently, the gate electrode of the semiconductor device is changed from tungsten silicide to tungsten gate electrode, and the capacitor insulating film is changed from ONO structure to tantalum oxide, and SiON and barrier are organic bottom arc and inorganic arc layers for forming photomask fine patterns. In accordance with the tendency to use Ti and TiN layers, which are metals, foreign materials in these stacked structures contaminate the wafer through the above paths in the semiconductor device process.

These foreign matters become a particle source as the semiconductor manufacturing process proceeds to contaminate the wafer 100. Particularly, when the diameter of the wafer is changed from 200 mm to 300 mm, the radius of the wafer edge becomes larger and thus particle contamination. The source also has to grow.

Therefore, foreign matters at the edge of the wafer 100 affecting the yield and reliability of the semiconductor device need to be completely removed.

Thus, in the past, the following methods have been used to remove foreign matter accumulated on the edge of the wafer.

That is, as an example, first, the nitride film removing process using wet etching is performed in five steps as follows (see FIGS. 7A to 7E).

Iii. An oxide film 102 is deposited on the silicon wafer 100 by using a plasma deposition apparatus on the nitride film 101 previously deposited (FIG. 7A).

Ii. The photoresist is formed on the oxide film 102 to form the photoresist film 103, and only the photoresist film 103 at the edge of the wafer 100 is removed to expose the oxide film 102 (FIG. 7B).

Iii. The oxide film 102 exposed at the edge of the wafer 100 is removed with a chemical solution (NHF ₄ + HF) using a wet etching apparatus (FIG. 7C).

Iii. The photosensitive film 103 on the oxide film 102 is removed using a dry removal device, and the residual photosensitive film 103 is removed with a chemical solution (H ₂ SO ₄ / H ₂ O ₂ ) using a cleaning device (FIG. 7D). ).

Iii. The nitride film 101 exposed at the edge of the wafer 100 is removed with a hot phosphoric acid (H ₃ PO ₄ ) solution using a wet etching apparatus (FIG. 7E).

However, in the conventional wet etching process, the nitride film removal process is complicated in its steps, and in performing the process, oxide film deposition, photoresist coating, photoresist dry removal, oxide film removal wet etching, photoresist removal, cleaning, nitride film wet etching, and the like are performed. There is a problem that requires various devices.

Meanwhile, as another conventional example, the polysilicon film removing process using dry etching is performed in five steps as follows (see FIGS. 8A to 8E).

Iii. The oxide film 102 is deposited on the polysilicon film 104 previously deposited on the silicon wafer 100 by using a plasma deposition apparatus (FIG. 8A).

Ii. A photosensitive agent is applied to form a photosensitive film 103, and the photosensitive film 103 at the edge of the wafer 100 is removed to expose the oxide film 102 (FIG. 8B).

Iii. The oxide film 102 exposed at the edge of the wafer 100 is removed with a chemical solution (NHF ₄ + HF) using a wet etching apparatus (FIG. 8C).

Iii. The photoresist film 103 on the oxide film 102 is removed using a photoresist dry removal device, and the residual photoresist film 103 is removed by a chemical solution (H ₂ SO ₄ / H ₂ O ₂ ) using a cleaning device ( 8d).

Iii. The polysilicon film 104 exposed at the edge of the wafer 100 is removed using a conventional dry etching apparatus (FIG. 8E).

In the conventional dry etching of the polysilicon film removing process as described above, the steps are complicated as in the nitride film removing process by wet etching, and in performing the process, oxide film deposition, photosensitive agent coating, oxide film removing wet etching, and photosensitive film dry There is a problem that requires a variety of devices for removal, cleaning, poly film removal dry etching and the like.

Moreover, when the conventional dry etching apparatus is used to remove the polysilicon film on the wafer edge, the top surface of the wafer edge can be removed, but the side and bottom portions of the wafer edge are incomplete or almost impossible. There is a problem.

In addition, conventional etching apparatuses can only be used individually for each process of forming a pattern on a wafer, and thus, only one foreign substance is removed as in the example described above. There is a problem that can not remove all the foreign matter.

On the other hand, the dry etching apparatus generally used in the formation of a semiconductor element microcircuit pattern in the prior art, as shown in Figure 9, between the first and second electrodes 300, 300 'formed in the form of a plate under a reaction gas atmosphere By forming an electric field to generate a plasma on the upper surface of the wafer 100, the material laminated on the upper surface 100a of the wafer 100 is etched into a fine pattern 103a, at which time the wafer 100 A portion of the foreign matter laminated film accumulated at the edge portion of the) is removed. Reference numerals 400 and 500 are RF generators and matching networks, respectively.

However, in the conventional dry etching apparatus, since the process is performed while the wafer 100 is placed on the electrode 300 ′ on one side, plasma is formed on the side surface 100b and the bottom surface 100c of the wafer 100. There is a problem that it is difficult to remove the foreign matter laminated on the side surface (100b) and the lower surface (100c) of the wafer 100 by not affecting.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object thereof is to effectively and completely remove foreign substances formed on the upper and side surfaces of the wafer edge and the lower surface of the semiconductor manufacturing process without causing damage to the wafer. The present invention provides a wafer dry etching electrode that can be used.

1 is a partial cross-sectional perspective view showing an electrode for wafer dry etching according to the present invention;

2 is a view illustrating top and side etching of a wafer using an electrode according to the present invention;

3 is a view for explaining the bottom and side etching of the wafer using an electrode according to the present invention,

4 is a cross-sectional view showing a dry etching apparatus in which an electrode according to the present invention is installed;

5 is a side view showing a wafer in which foreign materials are stacked;

6 is a view illustrating a scene in which foreign matters are formed and stacked on a wafer by equipment;

7A to 7E are views illustrating a nitride film removing process by conventional wet etching;

8A to 8E illustrate a conventional polysilicon film removing process by dry etching;

9 is a view illustrating etching of a wafer using a conventional electrode.

<Explanation of symbols for the main parts of the drawings>

10: first electrode 10a: first protrusion 10b: gas inlet

10c: first non-projection portion 11: insulator 20: second electrode

20a: opening 20b: second projection 20c: second non-projection

30: wafer 30a: top surface 30b: side

30c: lower surface 31: fine pattern 40: electrostatic chuck

In the wafer dry etching electrode according to the present invention for achieving the above object, in the first and second pair of wafer dry etching electrodes to form a plasma to remove the foreign matter of the wafer edge, the first electrode is A second projection having an annular first projection end facing one side of the upper and lower portions of the wafer edge, the second electrode having the same dimension as the first projection end while facing the other side of the upper and lower portions of the wafer edge; What has a stage shall be characteristic technical idea.

In this case, an insulating film may be applied or an insulator may be applied to a portion of the first electrode that extends from the central portion facing the wafer to the inner diameter of the protruding end.

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

1 is a partial cross-sectional perspective view showing wafer dry etching electrodes according to the present invention, wherein a pair of electrodes, namely, a first electrode 10 and a second electrode, are plasma generating means for removing foreign matters formed on the edge of a wafer; The electrode 20 is shown.

For convenience, the first electrode 10 is used as an anode and the second electrode 20 is a cathode. The first electrode 10 is a cathode and the second electrode 20 is an anode. It can also be

An alternative shape of the first electrode 10 is made of a circular flat plate like a conventional electrode, and has a characteristic structure in which an annular projecting end 10a is formed at the bottom thereof, and the projecting end 10a is formed. Between the outer diameter and the outer diameter, a gas inlet 10b for blowing the reaction gas for plasma formation into the vacuum chamber (not shown) in which the first and second electrodes 10 and 20 of the present invention are installed.

The second electrode 20 is formed of a circular flat plate having the same diameter corresponding to the first electrode 10, and has an opening 20a penetrating up and down in the center thereof. Between the outer diameter, the protruding end 10a of the first electrode, which is referred to as " first protruding end " for convenience,-an annular protruding end 20b having the same dimension as opposed to the " second protruding end " Stage "-is formed.

In addition, the flat portions outside the first protrusion 10a of the first electrode 10 and the second protrusion 20b of the second electrode 20 are, for convenience, the first non-projection portion 10c and the second ratio, respectively. The protrusion 20c is referred to as division.

On the other hand, when RF power is applied between the first electrode 10 and the second electrode 20 to a portion from the center of the bottom surface of the first electrode 10 to the inner diameter of the first protrusion 10a, an electric field or An insulating film may be applied or the insulator 11 may be attached to prevent an electromagnetic field from being generated by the reaction gas. Examples of the insulator 11 include polyimide, polypropylene, teflon, silicon, quartz, ceramic, and ceramics.

2 and 3 illustrate etching of a wafer using an electrode according to the present invention. Hereinafter, interaction between the electrodes 10 and 20 of the present invention and the wafer 30 will be described based on these drawings. Explain.

First, referring to FIG. 2, the wafer 30 is interposed between the first electrode 10, which is an anode, and the second electrode 20, which is a cathode, by the electrostatic chuck 40. The lower surface 30c of the edge portion of the wafer 30 is placed on the upper side of the second protrusion 20b of the second electrode 20 by being lowered through the opening 20a of the second electrode 20. You are in contact.

In this state, when the reaction gas is blown through the gas inlet 10b of the first electrode 10, and power is applied to the second electrode 20 from the RF generator 50, the first electrode 10 is discharged. An electric field or an electromagnetic field is formed through the first protrusion 10a and the first non-projection portion 10c, the second protrusion 20b of the second electrode 20 and the second non-projection portion 20c, Two kinds of plasma having different intensities are generated between the protruding ends 10a and 20b and the two non-protruding portions 10c and 20c.

At this time, the plasma is formed along the width of each of the first protrusion 10a and the second protrusion 20b, and the widths of the protrusions 10a and 20b are to be etched from the wafer 30 facing each other. By fabricating and using the size corresponding to the edge portion (region indicated by "B" in the drawing), plasma is formed in the region where the fine pattern 31 of the wafer 30 is formed (region indicated by "A" in the figure). Is not affected, and the plasma formed between the first non-projection portion 10c and the second non-projection portion 20c (indicated by “C” in the drawing) induces side etching of the wafer.

In particular, since the lower surface 30c of the wafer 30 is in contact with the upper surface of the second protruding end 20b of the second electrode 20, the wafer 30 is mainly in the form of plasma reactive ion etching (RIE). Etching is limited to the upper surface 30a and the side surface 30b of the c) within a range capable of removing foreign matter on this portion.

In addition, since the insulator 11 provided at the portion from the center of the bottom surface of the first electrode 10 to the inner diameter of the first protrusion 10a does not form an electric field or an electromagnetic field in the "A" region, this "A" Since plasma generation in the region is prevented in advance, a more stable etching effect can be seen.

Reference numeral 60 in the drawing is a matching network.

Meanwhile, as shown in FIG. 3, the electrostatic chuck 40 is raised through the opening 20b of the second electrode 20 so that the upper surface 30c of the edge portion of the wafer 30 is the first electrode of the first electrode 10. When the reaction gas is blown through the gas inlet 10b of the first electrode 10 in a state of being in contact with the upper end of the protruding end 10a, and power is applied from the RF generator 50, the first protruding end as before. Plasma is generated through the 10a and the second protruding end 20b, but in this case, the plasma is theoretically limited to the lower surface 30c and the side surface 30b of the edge of the wafer 30 by the plasma type. The etching is performed within the range to remove the foreign matter on the area).

4 shows an example in which the electrode of the present invention is installed and applied to a conventional vacuum chamber. The vacuum chamber 70 includes a reaction gas blowing conduit for generating plasma from the electrodes 10 and 20 of the present invention. 71, an entrance 70a for carrying in the wafer 30, an outlet 70b for discharging the gas after etching of the wafer 30, and an electrostatic power that allows the wafer 30 to be seated and lifted up and down The chuck 40 is provided.

Accordingly, the wafer 30 enters the vacuum chamber 70 through the entrance 70a and is placed on the electrostatic chuck 40, and then the voltage of the RF generator 50 through the second electrode 20 under a reaction gas atmosphere. When is applied, the central portion of the upper surface of the wafer 30 is intactly maintained by the insulator 11 of the first electrode 10 while the first protrusion 10a and the first non-projection portion of the first electrode 10 are maintained. Plasma is formed only between the second protrusion 20b and the second non-projection portion 20c of the second electrode 20 and the second electrode 20, thereby etching the edge portion of the wafer 30 through the above-described process. This is done.

In this manner, during the etching process, the foreign substances and the reaction gas removed from the wafer 30 are pumped out through the outlet 70b as in the related art.

On the other hand, dry etching on the edge of the wafer using the electrode according to the present invention, the foreign matters can be removed using the etching reaction gas shown in Table 1.

Foreign object type Reaction Gas for Etching Inorganic Arc (SiON) CF ₄ , SF ₆ Organic Arc (C _x Si _y ) CF ₄ , O ₂ Oxide (SiO ₂ ) CF ₄ , CHF ₃ , C ₄ F ₈ , C ₂ F ₆ , Ar, O ₂ , C ₄ F ₈ , CH ₂ F ₂ Nitride Film (Si ₃ N ₄ ) CF ₄ , SF ₆ , CHF ₃ , Ar, O ₂ Polysilicon (Si) HBr, Cl ₂ , CCl ₄ , SF ₆ , O ₂ Tungsten Silicide (WSi _x ) SF ₆ , Cl ₂ Tungsten (W) SF ₆ , CF ₄ , Ar, O ₂ Aluminum (Al) Cl ₂ , CCl ₄ , BCl ₃ Copper (Cu) Cl ₂ Tantalum Oxide (TaO ₂ ) SF ₆ / Cl ₂ / CF ₄ Tantalum Oxynitride (TaON) SF ₆ / Cl ₂ / CF ₄ Titanium (Ti) CF ₄ , SF ₆ Titanium Silicide (TiSi _x ) SF ₆ , CF ₄ , O ₂ SOG, [R _x SiO _y SiO ₂ ] n, H (SiO _3/2 ) n SF ₆ , CF ₄ , O ₂

As described above, conventionally, since etching devices having only such a function or having only such a function, such as a nitride etching removal wet etching device or a dry etching device for forming a fine pattern, have been used for various purposes, In order to remove foreign substances, the etching apparatus was required and the process was complicated.

Also, in the structure of the electrode, only foreign matters on the upper and side portions of the wafer edge portion have been properly removed, but foreign matters on the lower portion of the wafer edge have been very difficult.

However, when the electrode of the present invention is applied, the foreign matter immediately after completion of the process only by replacing the etching reaction gas for the removal of the foreign matter illustrated in Table 1 not removed in the process of forming a fine pattern on the wafer. This eliminates the need for additional equipment and simplifies the process.

In addition, since the influence of plasma is not applied to the portions other than the upper, side, and lower edges of the wafer, effective etching is performed on the edges, and the pattern portions of the wafer are not damaged at all.

As described above, the electrode for wafer dry etching according to the present invention removes all the foreign matters stacked on the upper and side surfaces and the lower surface of the wafer edge portion without requiring an additional step in the semiconductor manufacturing process. This simplifies the process, lowers the cost of the process, and contributes to yield, quality and productivity.

Claims (2)

delete In the first and second pair of wafer dry etching electrodes to form a plasma to remove foreign substances on the wafer edge, The first electrode has an annular first protruding end and a first non-projection part facing one of the upper and lower parts of the wafer edge, and the second electrode faces the other one of the upper and lower parts of the wafer edge. A second protrusion and a second non-projection having the same dimensions as the first protrusion and the first non-projection, and an insulating film is applied to a portion of the first electrode extending from the central portion facing the wafer to an inner diameter of the protrusion; Wafer dry etching electrode characterized in that the insulator is attached.