JP3394143B2 - Substrate cleaning method and apparatus - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a semiconductor wafer, a glass substrate for a photomask, a glass substrate for a liquid crystal display device, a substrate for an optical disk (hereinafter simply referred to as a substrate), and a pure water or the like. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a substrate cleaning method and apparatus for supplying a cleaning liquid for cleaning, and more particularly to wet cleaning in which cleaning treatment is performed with an aqueous solution.

[0002]

2. Description of the Related Art In a substrate cleaning process for cleaning a semiconductor substrate such as a Si wafer, a wet cleaning method based on a chemical method proposed by RCA Co. is naturally used. That is, an alkali-based cleaning liquid (SC-1 liquid or A
Cleaning treatment also called PM liquid), cleaning treatment using a dilute solution of hydrofluoric acid (HF) aqueous solution (also called DHF liquid), hydrochloric acid: hydrogen peroxide:
Acid-based cleaning solution consisting of pure water (SC-2 solution or H
(Also called PM solution). In these cleaning processes, the SC-1 liquid removes organic stains and surface-adhered particles, the DHF liquid removes the silicon oxide film, and the SC-2 liquid removes surface metal impurities. There is.

After that, instead of the wet cleaning method in which various chemicals are mixed into an aqueous solution as a cleaning liquid as described above, chemical vapor or gas is diluted with an inert gas to easily vaporize contaminants on the substrate surface. A vapor-phase cleaning method in which the reaction product is removed instead of the reaction product has been studied, but a wet cleaning method using an aqueous solution is predominant except for some cleaning steps. This is because water molecules are extremely polarizable, and it is overwhelmingly advantageous for the cleaning process that the Wanderwers force and electrostatic force acting on the particles attached to the substance in the aqueous solution become much smaller than in the gas. is there. Then, although the vapor-phase cleaning method is adopted in a part of the substrate cleaning process, the research has been vigorously pursued to elucidate the cleaning mechanism of the wet cleaning method using the aqueous solution again. As a result, the cleaning mechanism has been largely clarified, and a new wet cleaning method has been proposed (Ultra Clean Technology Vol.8, No.3, (1996) P.156).

In order to remove the surface-adhered particles adhering to the substrate, the substrate surface and the particles are charged to the same polarity with the same polarity and electrically repel, and the substrate surface or the particle surface thereof is slightly It is concluded that the particles need to be etched off and lifted off. The former of the above conditions for removing particles adhering to the surface is recognized as the most basic item in the field of electrochemistry, particularly in the general cleaning field.

In the process of a semiconductor substrate, various films such as a silicon oxide film, a silicon nitride film, a metal film, and a photoresist film are formed on the surface of the substrate according to the processing, and therefore the surface adhesion depends on the kind of the film. There are various materials that can be used as particles. As described above, it is necessary to charge the material to the same polarity in order to remove the surface-adhered particles, but it has recently become more advantageous in the semiconductor manufacturing field to use an alkaline aqueous solution for this purpose. Was verified. Therefore, an alkaline NH ₄ OH: H ₂ O with etching capability for the silicon surface is used.
_{The 2} : H ₂ O solution is described as effective in removing surface adhering particles. However, since an insulating film such as a silicon oxide film or a silicon nitride film is not reduced by hydrogen ions or hydrogen radicals, hydrofluoric acid is considered to be essential for removing adhered particles on the surface of the insulating film. It is also stated that the same effect can be expected by adding a negative ion surfactant in order to control the surface potential.

[0006]

The cleaning process for removing adhered particles from the substrate surface to clean the substrate is as follows.
To separate the adhered particles from the surface of the substrate, and to separate the separated particles from the substrate so that the separated particles do not redeposit. In order to separate the adhered particles from the surface of the substrate, an ultrasonic system for supplying pure water with ultrasonic vibration,
By using a method such as a brush method that mechanically cleans with a brush or a high-pressure jet method that supplies pure water with a high-pressure jet, it is not necessary to use a chemical solution with etching ability, but these methods separate the substrate surface. In order to prevent redeposition of the particles, an alkaline agent or an agent such as an anionic surfactant must be added.
On the other hand, the drug added for controlling the surface potential must be finally washed off regardless of the amount. In other words, after the anti-redeposition treatment is performed by adding a chemical to remove the surface-adhered particles, a rinse step must be added to wash and remove them. Therefore, there is a problem that the time required for the substrate cleaning process increases due to the addition of the rinsing step, and the throughput in the substrate cleaning process decreases.

Furthermore, as a matter of course, since no chemicals are allowed to be mixed in the rinse step for washing off the chemicals, only pure water is used for the treatment, but particles are generated in ultrapure water having a very high specific resistance. If the particles are mixed in the rinse process, the mixed particles are likely to adhere to the substrate. In particular, a newly purchased substrate cleaning device handed over from a manufacturer to a user has a risk of particle adhesion to the substrate even in the final rinsing step due to contamination that occurs during the manufacturing thereof and during its loading. In the case of such a newly purchased device, it will gradually settle into a clean state by continuing to use it, but it is also necessary to fully consider that particles may adhere to the substrate due to sudden contamination. The reality is that the cleaning liquid used in the final rinse step needs to be provided with anti-adhesion measures that allow for a safety factor.

The present invention has been made in view of the above circumstances, and prevents the particles removed from the substrate from re-adhering by controlling the surface potential with the reducing gas dissolved in the aqueous solution. An object of the present invention is to provide a substrate cleaning method and an apparatus therefor that can be performed.

[0009]

The present invention has the following constitution in order to achieve such an object. That is, the substrate cleaning method according to claim 1, in the substrate cleaning method for cleaning by supplying a cleaning liquid to a substrate, an aqueous solution prepared by dissolving a reducing gas in pure water and the washing solution, a substrate holding means
It is characterized in that the substrate is held in a rotating state by the step .

The substrate cleaning method according to claim 2 is
The substrate cleaning method according to claim 1, wherein the reducing gas is hydrogen.

The substrate cleaning method according to claim 3 is
In the substrate cleaning method according to claim 1 or 2, the pure water is cooled.

A substrate cleaning apparatus according to a fourth aspect is
In a substrate cleaning apparatus that supplies a cleaning liquid to a substrate to perform cleaning, a rotation holding unit that rotatably holds the substrate, a dissolving unit that dissolves a reducing gas in pure water, and an aqueous solution generated by the dissolving unit are used as the cleaning liquid. As the rotation holding means
And a cleaning liquid supply unit that supplies the substrate held in a rotating state .

A substrate cleaning apparatus according to a fifth aspect of the present invention is
The substrate cleaning apparatus according to claim 4 is characterized by comprising pressure adjusting means for adjusting the pressure of the reducing gas and supplying it to the dissolving means.

A substrate cleaning apparatus according to a sixth aspect of the present invention is
The substrate cleaning apparatus according to claim 4 or 5, further comprising a cooling means for cooling the pure water and supplying it to the dissolving means.

A substrate cleaning apparatus according to a seventh aspect is
The substrate cleaning apparatus according to any one of claims 4 to 6, wherein the dissolving means is provided in a liquid chamber to which pure water is supplied and a plurality of liquid chambers that are permeable to a reducing gas. And a reducing gas is dissolved in pure water by permeating the reducing gas from the hollow portion of the hollow fiber.

[0016]

The operation of the method according to the first aspect of the present invention is as follows. Conventionally, for example, the surface potential of the substrate has been controlled by adjusting the pH by adjusting the ratio of mixing an alkaline chemical with pure water. In particular, in order to prevent re-adhesion, it is necessary to make the potential polarities of the substrate and the particles equal to each other and repel them. In the field of electrochemistry, the isoelectric point of many substances (the value peculiar to a substance at which the surface potential becomes zero and no electrophoretic phenomenon or other interfacial phenomenon is shown) is on the acidic side. In order to achieve this, it was considered advantageous to align the polarities on the alkaline side. This is no exception to the washing of the substrate held in a rotating state by the substrate holding means, and it was confirmed that most of the particles can be negatively charged by making the substrate alkaline. Has been done.

The inventors have found that the potential can be controlled by directly dissolving a reducing gas in pure water and adjusting the activity of the reducing gas instead of mixing the alkaline chemical to adjust the pH. In this case, since it has been experimentally confirmed that the pH hardly changes with the activity of the reducing gas, the potential is not determined by the intervention of ions, but the reducing gas reacts directly with the substance surface. It is considered that the electric potential is determined by giving electrons as a result.
By supplying the substrate with the aqueous solution in which the reducing gas is dissolved in pure water as the cleaning liquid, the potentials of the substrate surface and the particles can be controlled to have the same polarity. Further, since this cleaning liquid does not contain a chemical such as an alkaline chemical or an anionic surfactant, it can be used in the final rinsing step.

According to the second aspect of the present invention, hydrogen, which is a reducing gas, is dissolved in pure water so that the surface of the substrate is not mixed with an alkaline agent or an anionic surfactant. And the electric potential of the particles can be controlled to have the same polarity.

According to the third aspect of the present invention, by cooling the pure water in which the reducing gas (for example, hydrogen) is dissolved, the saturated dissolution concentration of the reducing gas can be increased and the potential can be increased. Enough electrons can be included in the cleaning liquid to control

The operation of the invention device according to the fourth aspect is as follows. A reducing gas (for example, hydrogen) is dissolved in pure water by the dissolving means, and the aqueous solution thus generated is used as a cleaning liquid, which is held in a rotating state by the rotating holding means.
Supplied from the cleaning liquid supply unit to the substrate it is. Since the reducing gas is dissolved in the cleaning liquid, the electric potentials of the substrate surface and the particles can be controlled to have the same polarity. Further, since this cleaning liquid does not contain an alkaline chemical or a chemical such as an anionic surfactant as in the conventional example, it can be used in the final rinsing step.

According to the fifth aspect of the invention, when the pressure of the reducing gas is adjusted by the pressure adjusting means and supplied to the dissolving means, the concentration of the reducing gas dissolved in pure water can be controlled. . For example, when hydrogen is dissolved as the reducing gas, its concentration may be adjusted in consideration of safety.

According to the sixth aspect of the present invention, when the pure water is cooled by the cooling means, the saturated dissolution concentration of the reducing gas can be increased, and the electrons sufficient for controlling the electric potential can be obtained. Can be included in the wash solution.

According to the seventh aspect of the present invention, the reducing gas is passed through the hollow portions of the plurality of hollow fibers having permeability to the reducing gas, so that the reducing gas is added to the pure water in the liquid chamber. As a result, the contact area between the reducing gas supply port and the liquid chamber increases.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic vertical sectional view of a substrate cleaning apparatus according to the present invention, and FIG. 2 is a plan view thereof. A spin chuck 3 that holds the substrate W by vacuum suction is attached to an upper end portion of a rotating shaft 2 that rotates around an axis in the vertical direction by driving the first electric motor 1. By these, the substrate holding means 4 that holds the substrate W rotatably around the vertical axis is configured. A support bracket 6 is disposed at a predetermined position above the substrate W held by the substrate holding means 4 so as to be rotationally displaceable by a second electric motor 5. The support bracket 6 is provided with a nozzle 7 for supplying an aqueous solution in which a reducing gas is dissolved in pure water as a cleaning liquid to the substrate W. The nozzle 7 corresponds to the cleaning liquid supply unit in the present invention.

The above-mentioned substrate holding means 4 is not limited to the above-mentioned vacuum suction type, but, for example, a plurality of substrate supporting members for supporting the outer peripheral edge of the substrate W are erected on the spin chuck 3 and these substrates are supported. A positioning pin that regulates the horizontal position of the substrate W may be provided on the upper end of the support member to rotatably hold the substrate W in a state of being separated from the upper surface of the spin chuck 3. .

The periphery of the substrate holding means 4 and the substrate W held thereby is surrounded by a cup 8 which can be moved up and down by an elevator drive mechanism (not shown), and the cleaning liquid supplied onto the substrate W at the time of cleaning the substrate W. It is configured to prevent scattering.

To the side of the cup 8 (on the right side in the figure), the cup 8 is lowered to the non-acting position, and the cleaning position on the surface of the substrate W and the non-cleaning position above the substrate W are removed. A cleaning brush 9 for cleaning the surface of the substrate W is arranged so as to be displaceable over the standby position. The cleaning brush 9 is contained in the standby pot 10 at the standby position in order to remove particles and the like attached during cleaning. Further, when the substrate W is cleaned by the cleaning brush 9, a cleaning liquid such as pure water is supplied from the cleaning liquid supply nozzle 11.

A dissolving device 12 as the dissolving means of the present invention is connected to the nozzle 7 through a transfer pipe 13. The dissolving device 12 is configured to be divided into an air chamber 15a and a liquid chamber 15b by a permeable membrane 14 that is permeable to hydrogen, which is a reducing gas. The air chamber 15a is connected to an inlet pipe 17 and an exhaust pipe 18 for supplying hydrogen gas, which is provided with an on-off valve 16 and a pressure regulator P, and a liquid chamber 15b is connected to a pure water supply pipe 19 and a cooling device 20, and a transfer device. The pipe 13 is connected. The permeation membrane 14 is, for example, about 0.
It has innumerable pores of about 05 μm and does not permeate water molecules but permeates only gas molecules.

The pressure adjuster P corresponding to the pressure adjusting means of the present invention adjusts the pressure of hydrogen supplied to the melting device 12. By adjusting the pressure of hydrogen with the pressure adjuster P, the concentration of hydrogen dissolved in pure water can be controlled.

The cooling device 20 arranged in the pure water supply pipe 19 cools the pure water and supplies it to the dissolving device 12. The cooling temperature is preferably in the range of 0 to 20 ° C. (or room temperature). As described above, the temperature of pure water is lowered and supplied to the melting device 12, whereby the saturated dissolution concentration of hydrogen gas is increased and the hydrogen gas can be dissolved at a high concentration. By dissolving hydrogen at a high concentration in pure water, sufficient electrons can be contained to control the potentials of the substrate W and surface-adhered particles, and the particles can be reliably removed from the substrate W. In this way, hydrogen is dissolved in pure water, and this aqueous solution is supplied to the substrate W from the nozzle 7 as a cleaning liquid.

The concentration of hydrogen contained in the cleaning liquid is set by adjusting the pressure of the pressure regulator P and / or the cooling temperature of the cooling device 20. The concentration may be high, but the dissolved concentration of hydrogen does not necessarily have to be the saturated concentration. Since hydrogen is associated with the risk of explosion, the concentration may be set to 4% or less of the explosion limit in consideration of safety. With this setting, the solubility of hydrogen is 0.
Since it is 018 (at P = 1 kg / cm ² ), the saturated hydrogen concentration is 8
× 10 ^-4 mol / liter, the pressure of the mixed gas is 1 kg
When it is set to / cm ² , the maximum dissolved concentration is 3.2 × 10 ^-5 mol / liter when the hydrogen partial pressure is 4% according to Henry's law. Therefore, the control range is reduced by about 0.7 in terms of pH value, but it can be compensated by increasing the pressure with the pressure regulator P.

Next, a substrate cleaning method using the substrate cleaning apparatus having the above structure will be described. Pure water is cooled to a constant temperature and supplied to the dissolving device 12, and the liquid chamber 15
The cooled pure water is circulated in b, and hydrogen adjusted to a constant pressure is supplied from the introduction pipe 17 to generate the air chamber 15a.
Distribute hydrogen to. Hydrogen permeates from the gas chamber 15a through the permeation membrane 14 to the liquid chamber 15b side, and hydrogen is dissolved at a constant concentration in the cooled pure water. In this way, the nozzle 7 is attached to the substrate W held in a rotating state by the substrate holding means 4 using the aqueous solution in which pure water is dissolved in hydrogen at a constant concentration as a cleaning liquid.
Supplied for a certain period of time.

By supplying an aqueous solution in which hydrogen, which is a reducing gas, is dissolved in pure water to the substrate W as a cleaning liquid, hydrogen directly reacts with the substrate W and the adhering particles to give electrons. The surface potentials of the substrate W and the adhered particles can be controlled to have the same negative polarity. Therefore, it is possible to prevent particles attached to the substrate W from electrically repelling the substrate W to be removed from the surface thereof, and to prevent particles removed from the substrate W from reattaching. In this process, the electron-releasing hydrogen is ionized, but not in an amount enough to change the pH. Since the above cleaning liquid does not contain a chemical such as an alkaline chemical or an anionic surfactant,
It is not necessary to perform the final rinse step after that, the cleaning process can be shortened, and the throughput can be improved. Further, the above cleaning solution can be used in the final rinse step.

In the above-mentioned apparatus, hydrogen is dissolved in pure water by the dissolving device 12 which employs the osmotic membrane 14, but instead of the dissolving device 12, a dissolving device as shown in FIG. 3 is adopted. May be. Note that FIG. 3 is a schematic vertical sectional view of the melting apparatus. The dissolving device 30 has an infiltration part 31 in which a plurality of hollow fibers having permeability to hydrogen are bundled,
The introduction pipe 17 is provided in the hollow portion of each hollow fiber that is the air chamber of the permeation portion 31.
More hydrogen is supplied and discharged to the exhaust pipe 18. Cooling device 2
The pure water that has been cooled through 0 is introduced into the liquid chamber 33, and hydrogen is melted from each hollow fiber of the permeation section 31 while moving toward the transfer pipe 13. As described above, since the permeation portion 31 of the dissolving device 30 is composed of a plurality of hollow fibers, the air chamber 15a and the liquid chamber 15b are in planar contact with each other like the dissolving device 12 described above. The contact area between the hydrogen supply port and the liquid chamber 33 can be made very large as compared with the conventional one. Therefore, the dissolving device 30 can be downsized, and hydrogen can be efficiently dissolved in pure water.

[0035]

[0036]

As is apparent from the above description, according to the method of the present invention as set forth in claim 1, the reducing gas is converted to pure water without using a chemical such as an alkaline chemical or an anionic surfactant. Use the dissolved aqueous solution as a cleaning solution to hold the substrate.
By supplying to the substrate that is held in a rotating state in steps ,
The surface potentials of the substrate and the particles can be controlled to have the same polarity. Therefore, the particles adhering to the substrate can be electrically repelled and removed from the substrate, and their re-adhesion can be prevented. Further, since no chemical is used, it is not necessary to perform the final rinsing step, the washing process can be shortened, and the throughput can be improved. Further, this cleaning solution can be used in the final rinse step.

According to the method of the second aspect of the present invention, by dissolving hydrogen, which is a reducing gas, in pure water, the surface potentials of the substrate and the particles can be controlled to have the same polarity, and the particles attached to the substrate can be removed. It is possible to remove and prevent reattachment.

According to the method of the third aspect of the present invention, it is possible to make the cleaning liquid contain enough electrons to increase the saturated dissolution concentration of the reducing gas and control the surface potential, and to reliably deposit the adhered particles. It can be removed from the substrate.

According to the invention apparatus described in claim 4, the substrate cleaning method described in claim 1 can be suitably implemented.

Further, according to the device of the fifth aspect of the present invention, the concentration of the reducing gas in the cleaning liquid can be adjusted by adjusting the pressure of the reducing gas.

According to the sixth aspect of the present invention, it is possible to make the cleaning liquid contain sufficient electrons to increase the saturated dissolution concentration of the reducing gas and control the surface potential. An apparatus that can be removed from the substrate can be provided.

According to the invention apparatus of claim 7, the contact area between the reducing gas supply port and the liquid chamber can be increased, and the reducing gas can be efficiently dissolved in pure water. Therefore, the dissolving means can be downsized.

[Brief description of drawings]

FIG. 1 is a schematic vertical sectional view showing a substrate cleaning apparatus according to the present invention.

FIG. 2 is a plan view of FIG.

FIG. 3 is a schematic vertical sectional view showing another configuration of the melting device.

[Explanation of symbols]

4 ... Substrate holding means 7 ... Nozzle (cleaning liquid supply unit) 12 ... Dissolution device (dissolution means) 14 ... Permeation membrane 20 ... Cooling device (cooling means) 30 ... Dissolution device (dissolution means) 31… Penetration part 33 ... Liquid chamber P ... Pressure regulator (pressure regulator) W ... Substrate

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-4-58528 (JP, A) JP-A-7-263430 (JP, A) JP-A-4-51521 (JP, A) JP-A-7- 58076 (JP, A) JP 7-256261 (JP, A) JP 10-128253 (JP, A) JP 9-10713 (JP, A) JP 5-67601 (JP, A) JP-A-7-311938 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H01L 21/304 B08B 3/00-3/14

Claims (7)

(57) [Claims] 1. A substrate cleaning method for supplying a cleaning liquid to a substrate for cleaning, wherein an aqueous solution prepared by dissolving a reducing gas in pure water is used as the cleaning liquid and is supplied to a substrate held in a rotating state by a substrate holding means.
A method of cleaning a substrate, comprising: 2. The substrate cleaning method according to claim 1, wherein the reducing gas is hydrogen. 3. The substrate cleaning method according to claim 1 or 2, wherein the pure water is cooled. 4. A substrate cleaning apparatus for supplying a cleaning liquid to a substrate to perform cleaning, a rotation holding means for rotatably holding the substrate, a dissolving means for dissolving a reducing gas in pure water, and a dissolving means for producing the reducing gas. A substrate cleaning apparatus, comprising: a cleaning solution supply unit configured to supply the aqueous solution as the cleaning solution to the substrate held in a rotating state by the rotation holding unit . 5. The substrate cleaning apparatus according to claim 4, further comprising a pressure adjusting unit that adjusts the pressure of the reducing gas and supplies the reducing gas to the dissolving unit. 6. The substrate cleaning apparatus according to claim 4 or 5, further comprising cooling means for cooling pure water and supplying the pure water to the dissolving means. 7. The substrate cleaning apparatus according to any one of claims 4 to 6, wherein the dissolving means is provided in a liquid chamber to which pure water is supplied and in the liquid chamber, and with respect to a reducing gas. A substrate cleaning apparatus comprising: a plurality of hollow fibers having permeability, wherein the reducing gas is dissolved in pure water by allowing the reducing gas to permeate from the hollow portion of the hollow fiber.