KR102523367B1 - Method for recovering surface of silicon structure and apparatus for treating substrate - Google Patents

Abstract

The present invention provides a method for improving surface roughness of a silicon structure. In one embodiment, a method for improving surface roughness of a silicon structure may include disposing a substrate on which a silicon structure is formed in a chamber; and exposing the substrate to hydrogen radicals at a set temperature, a set pressure and a set time.

Description

Silicon structure surface roughness improvement method and substrate processing apparatus

The present invention relates to a method for improving surface roughness of a silicon structure and a substrate processing apparatus.

In the process of manufacturing semiconductor components, microstructures are formed on the surface of a wafer. In general, a microstructure is formed by etching a substrate, and in this process, the structure has a rough surface.

An object of the present invention is to provide a method for improving surface roughness of a silicon structure and a substrate processing apparatus capable of efficiently processing a substrate.

An object of the present invention is to provide a method for improving the surface roughness of a silicon structure and a substrate processing apparatus capable of effectively improving the surface roughness of a silicon structure.

An object of the present invention is to provide a method for improving surface roughness of a silicon structure and a substrate processing apparatus capable of lowering a vacuum level in a chamber during processing.

An object of the present invention is to provide a method for improving surface roughness of a silicon structure and a substrate processing apparatus capable of reducing generation of particles during processing.

The problem to be solved by the present invention is not limited to the above-mentioned problems, and problems not mentioned can be clearly understood by those skilled in the art from this specification and the accompanying drawings. will be.

The present invention provides a method for improving surface roughness of a silicon structure. In one embodiment, a method for improving surface roughness of a silicon structure may include disposing a substrate on which a silicon structure is formed in a chamber; and exposing the substrate to hydrogen radicals at a set temperature, a set pressure and a set time.

In one embodiment, the set temperature may be a temperature at which the wafer can be heated to 400 degrees Celsius or higher.

In one embodiment, the set pressure may be 10 Torr or less inside the chamber.

In one embodiment, the set pressure may be 1 Torr or more inside the chamber.

In one embodiment, the set time may be 1 minute or more and 10 minutes or less.

In one embodiment, the silicon structure may be composed of single crystal Si.

In one embodiment, the hydrogen radicals may be generated by excitation of hydrogen gas into plasma.

In one embodiment, the silicon structure surface roughness improvement method further comprises the step of exhausting the inside of the chamber simultaneously with the step of exposing the substrate to the hydrogen radicals or after a set time.

In addition, the present invention provides an apparatus for processing a substrate. In one embodiment, a substrate processing apparatus includes a process chamber forming a processing space; a support unit provided in the processing space, including a heater on which a substrate to be processed is placed, and which heats the substrate to be processed; a plasma excitation unit generating radicals required by the process chamber; a shower head uniformly spraying radicals generated from the remote plasma excitation unit into the process chamber; and a controller controlling the pressure of the processing space of the process chamber, the heater, and a processing time of the substrate to be processed, wherein the radical is a hydrogen radical, and the substrate to be processed has a silicon structure.

In one embodiment, the substrate processing apparatus may not include a part containing a silicon component.

In one embodiment, the controller may control the heater so that the substrate to be processed is heated to 400 degrees Celsius or more.

In one embodiment, the controller may maintain the pressure in the inner space at 1 Torr or more.

In one embodiment, the controller may control the substrate to be processed to be exposed to the radical for 1 minute or more and 10 minutes or less.

In one embodiment, the silicon structure of the substrate to be processed may be monocrystalline silicon.

In one embodiment, the substrate processing apparatus further includes an exhaust unit for exhausting an atmosphere of the processing space, and the controller controls the processing space at the same time that the substrate to be processed is exposed to the radical or after a set time. The exhaust unit may be controlled to exhaust the atmosphere.

According to one embodiment of the present invention, the substrate can be efficiently processed.

According to one embodiment of the present invention, it is possible to effectively improve the surface roughness of the silicon structure.

According to an embodiment of the present invention, the vacuum level in the chamber may be lowered during processing.

According to an embodiment of the present invention, generation of particles can be reduced during processing.

The effects of the present invention are not limited to the above-mentioned effects, and effects not mentioned will be clearly understood by those skilled in the art from this specification and the accompanying drawings.

1 is a schematic cross-sectional view of a substrate processing apparatus according to an embodiment of the present invention.
2 is a flowchart illustrating a method of improving surface roughness of a substrate on which a silicon structure is formed according to an exemplary embodiment.
3 illustrates a silicon structure before surface roughness is improved, according to an embodiment.
4 illustrates a silicon structure having improved surface roughness, according to an exemplary embodiment.
5 is a conceptual diagram schematically illustrating a reaction of a surface of a silicon structure according to an embodiment.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following examples. This embodiment is provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes of elements in the figures are exaggerated to emphasize clearer description.

1 is a schematic cross-sectional view of a substrate processing apparatus according to an embodiment of the present invention.

Referring to FIG. 1 , a substrate processing apparatus 100 includes a chamber 2100, a support unit 2200, a shower head 2300, a plasma excitation unit 2400, an exhaust baffle 2500, and a vacuum pump 2600. do.

The chamber 2100 provides a processing space 2101 in which processing is performed. The chamber 2100 has a body 2110 and a sealing cover 2120. The upper surface of the body 2110 is open, and a processing space 2101 is formed therein. An opening (not shown) through which the substrate W enters and exits is formed on the sidewall of the body 2110, and the opening may be opened and closed by an opening and closing member such as a slit door (not shown). The opening/closing member closes the opening while processing the substrate W in the chamber 2100, and opens the opening when the substrate W is carried into the chamber 2100 and taken out of the chamber 2100. do. With the opening open, a hand part (not shown) of the robot for transferring the substrate W enters and exits the chamber 2100 .

An exhaust hole 2102 is formed on the bottom surface of the body 2110 . The exhaust hole 2102 is connected to the exhaust line 2140. The exhaust line 2140 is connected to the vacuum pump 2600. With exhaust through the exhaust line 2140, the processing space 2101 can be maintained at a pressure lower than atmospheric pressure (eg, vacuum). In addition, reaction by-products generated during the process and gas present in the processing space 2101 are discharged to the outside through the exhaust line 2140 .

The airtight cover 2120 is coupled to the upper wall of the body 2110 and covers the open upper surface of the body 2110 to seal the inside of the body 2110. A plasma excitation unit 2400 may be positioned above the airtight cover 2120 . A diffusion space 2121 is formed in the airtight cover 2120 . The diffusion space 2121 may have a wider lower portion than an upper portion. For example, the diffusion space 2121 may have an inverted funnel shape.

The support unit 2200 is positioned inside the chamber 2100 . A substrate W to be processed is placed on the upper surface of the support unit 2200 . The support unit 2200 includes a support plate 2210, a lift pin (not shown), a heater 2220, and a support shaft 2230. In addition, a cooling passage (not shown) through which cooling fluid circulates may be formed inside the support unit 2200 . The cooling fluid circulates along the cooling passage and cools the support unit 2200 .

The support plate 2210 may have a predetermined thickness and may be provided as a disk having a larger radius than the substrate W. A groove in which the substrate W is placed may be provided on an upper surface of the support plate 2210 . An inner wall forming the groove of the support plate 2210 may be inclined downward toward the center of the support plate 2210 .

A plurality of lift pins (not shown) are provided, and each is provided in a lift pin hole (not shown) provided in the support plate 2210 . A plurality of lift pins (not shown) move vertically along the lift pin hole, and load the substrate W onto the support plate 2210 or unload the substrate W from the support plate 2210 .

The heater 2220 is provided inside the support plate 2210 . According to one embodiment, the heater 222 may be provided as a resistance wire generating heat by electrical resistance, a flow path through which fluid flows, and the like. According to one embodiment, the heater 2220 is provided as a spiral coil, and is buried inside the support plate 2210 at regular intervals. The heater 2220 is connected to an external power source and generates heat by resisting a current applied from the external power source. Heat generated by the heater 2220 is conducted to the substrate W through the support plate 2210 . The heater 2220 heats the substrate W to a preset temperature. The heater 2220 may heat the substrate W to 400 degrees Celsius or higher.

The support shaft 2230 is located below the support plate 2210 and supports the support plate 2210 .

In addition, power may be applied to the support unit 2200 from the bias power supply 2210 in order to adjust the degree of processing of the substrate W by plasma. Power applied by the bias power supply 2210 may be radio frequency (RF) power. The support unit 2200 may form a sheath by power supplied by the bias power supply 2210 and form high-density plasma in the region to improve process capability.

The shower head 2300 is coupled to the upper wall of the body 2110. The shower head 2300 has a disk shape and may be disposed parallel to the upper surface of the support unit 2200 . The shower head 2300 may be provided with an aluminum material having an oxidized surface. Distribution holes 2310 are formed in the shower head 2300 . The distribution holes 2310 may be formed at regular intervals on a concentric circumference to uniformly supply radicals. The plasma diffused in the diffusion space 2121 flows into the distribution holes 2310 . At this time, charged particles such as electrons or ions are trapped in the shower head 2300, and neutral particles that are not charged, such as radicals, pass through distribution holes 2310 and are supplied to the substrate W. Also, the shower head may be grounded to form a passage through which electrons or ions move.

The plasma excitation unit 2400 generates plasma and supplies it to the chamber 2100 . The plasma excitation unit 2400 may be provided above the chamber 2100 . The plasma excitation unit may be provided as a remote type plasma excitation unit, a capacitive coupled plasma excitation unit, an inductively coupled plasma excitation unit, or the like. Hereinafter, a remote type plasma excitation unit will be described as an example.

The plasma excitation unit 2400 includes an oscillator 2410, a waveguide 2420, a dielectric tube 2430, and a gas supply unit 2440.

The oscillator 2410 generates electromagnetic waves. The waveguide 2420 connects the oscillator 2410 and the dielectric tube 2430, and provides a passage through which electromagnetic waves generated by the oscillator 2410 are transferred to the inside of the dielectric tube 2430.

The gas supplier 2440 supplies process gas to the upper part of the chamber 2100 . In one embodiment, the process gas may be hydrogen gas. In one embodiment, the process gas may be supplied together with the carrier gas. In one embodiment, the carrier gas may be argon (Ar).

The process gas supplied into the dielectric tube 2430 is excited into a plasma state by electromagnetic waves. Gas in a plasma state is introduced into the diffusion space 2121 through the dielectric tube 2430.

The exhaust baffle 2500 is provided in a ring-shaped plate shape. The exhaust holes 2501 are provided to pass through the outer region of the exhaust baffle 2500 in the vertical direction. The exhaust baffle 2500 is fixed to the inner surface of the process chamber 2100 so as to surround the support plate 2210 .

The vacuum pump 2600 forcibly exhausts the inside of the processing space 2101 . The vacuum pump 2600 communicates with the exhaust line 2140 . The atmosphere of the processing space 2101 sucked in by the vacuum pump 2600 passes through the exhaust baffle 2500 and reaches the exhaust line 2140 .

The substrate processing apparatus 100 according to an embodiment of the present invention does not include a material containing Si, such as quartz.

2 is a flowchart illustrating a method of improving surface roughness of a substrate on which a silicon structure is formed according to an exemplary embodiment. Referring to FIG. 2 , a method of improving surface roughness of a substrate on which a silicon structure is formed according to an exemplary embodiment will be described. In an embodiment of the present invention, the operation of the device 100 to improve the surface roughness of the substrate on which the silicon structure is formed is performed as the device 100 is controlled by a controller (not shown). For example, the controller (not shown) may control the operation of the vacuum pump 2600 to control the pressure in the processing space of the process chamber, and may control the heater 2220 to control the temperature of the substrate W, In order to control the exposure time to hydrogen radicals, which is the processing time of the substrate W, the overall configuration of the device may be controlled.

First, the substrate W on which the silicon structure is formed is disposed on the support unit 2220 of the above-described substrate processing apparatus 100 (S110). Thereafter, the substrate W is exposed to hydrogen radicals at a set temperature, a set pressure, and a set time (S120). The set temperature is 400 degrees Celsius or more and 1000 degrees Celsius or less, and the set pressure is 10 Torr or less, preferably 1 Torr or more. In addition, the setting time is 1 minute or more and 10 minutes or less.

If the substrate is treated at 400 degrees Celsius or less, the effect of improving the roughness does not occur, and when the substrate is treated at 1000 degrees Celsius or more, degradation of the substrate may occur. A setting pressure of 10 Torr or less is sufficient. This is a vacuum level that is significantly more relaxed than the conventionally required vacuum level of 100 mTorr or less. If exposed to radicals for 1 minute or less, the effect of improving roughness does not sufficiently occur, and if exposed to radicals for 10 minutes or more, deterioration may occur due to heating the substrate to a high temperature, which is disadvantageous.

At the same time as exposing the substrate W to hydrogen radicals (S120) or after a set time, the inside of the chamber is evacuated (S130). The setting time may be 30 seconds. Preferably, the setting time may be 1 minute. Exposing the substrate W to hydrogen radicals (S120) and evacuating the inside of the chamber (S130) may be performed simultaneously or sequentially. For example, after exposing the substrate W to hydrogen radicals (S120) is performed for a set time (eg, 1 minute or more and 10 minutes or less), exhausting the inside of the chamber (S130) may be performed.

3 shows a silicon structure before surface roughness is improved according to an embodiment, FIG. 4 shows a silicon structure whose surface roughness is improved according to an embodiment, and FIG. According to an embodiment, it is a conceptual diagram schematically illustrating a reaction of a surface of a silicon structure.

Referring to Figs. 3, 4 and 5, the principle of improving the surface roughness of the substrate will be described.

In an embodiment of the present invention, the surface subject to roughness improvement is a silicon structure, and its chemical formula is expressed as Si. In one example, the silicon structure is single-crystal silicon, or may be poly-crystal silicon. Si reacts with hydrogen radicals (H*) to generate reactants through a reaction as shown in [Chemical Formula 1]. For reference, SiH _n generated in the reaction process is not a gas.

[Formula 1]

Si(s) + H* -> SiH _n -> Si(s) + H ₂ (g)

In an embodiment of the present invention, the silicon structure is preferably a pure silicon crystal, but in some cases, as it is oxidized, its surface may include SiO ₂ . In this case, SiO ₂ reacts with hydrogen radicals (H*) to generate reactants through a reaction as shown in [Formula 2]. For reference, SiO _n H _n generated in the reaction process is not a gas.

[Formula 2]

SiO ₂ (s) + H* -> SiO _n H _n -> Si (s) + H ₂ (g) + H ₂ O (g) + O ₂ (g)

In an embodiment of the present invention, the silicon structure is preferably a pure silicon crystal, but in some cases, as it is nitrided, its surface may include SiN. In this case, SiN reacts with hydrogen radicals (H*) to generate reactants through a reaction as shown in [Chemical Formula 3]. For reference, SiN _n H _n generated in the reaction process is not a gas.

[Formula 3]

SiN(s) + H* -> SiN _n H _n -> Si(s) + H ₂ (g) + NH ₃ (g) + N ₂ (g)

The inventors of the present invention found that migration of Si occurs on the surface of the silicon structure from the reactions such as [Formula 1], [Formula 2], and [Formula 3] described above. In the description of the present invention, the migration of Si is defined as improving the roughness of the surface by moving Si of the protruding surface to the depressed surface and filling it, rather than Si being cut out as referenced through FIG. 5 do.

According to the above-described embodiment, the Si surface roughness of a silicon structure (eg, pattern) can be improved by using H Radical generated from a high density remote plasma (>10xE13/cm3), In particular, the Si shape of the Fin-FET pattern can be improved. For example, in the case of a microplasma generator, the plasma density tends to decrease rapidly as the distance from the antenna increases. In comparison, in the case of the substrate processing apparatus according to an embodiment of the present invention, the plasma density of 10xE13/cm3 or more As hydrogen gas is excited into plasma in the state of plasma density, the generation rate of hydrogen radicals (H radicals) can be rapidly increased, which is a material for improving the surface roughness of silicon structures. As a large amount is effectively generated, the maximum of the Si Migration effect of the silicon structure can be expected.

In addition, even if the 3D Fin-FET structure is changed to the GAA (Gate All Around) structure, the surface roughness and Si migration of the silicon structure can be implemented.

In addition, the effect of improving the specific resistance (Rs) of the metal film may be expected by using the hydrogen radical (H radical) generated by the remote plasma.

In addition, since the inside of the process chamber has a structure that does not contain Si-containing parts, such as quartz (SiO2), there is no etching phenomenon due to the reaction between the parts of the device and hydrogen radicals, so MTBP improvement can be expected. .

The above detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and describe preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed in this specification, within the scope equivalent to the written disclosure and / or within the scope of skill or knowledge in the art. The written embodiment describes the best state for implementing the technical idea of the present invention, and various changes required in the specific application field and use of the present invention are also possible. Therefore, the above detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to cover other embodiments as well.

Claims (15)

arranging in a chamber of a substrate processing apparatus for processing a substrate on which a silicon structure composed of single crystal Si is formed, wherein a component of the substrate processing apparatus exposed to the following hydrogen radical does not contain a silicon component;
In order to improve the surface roughness of the silicon structure through Si migration in which the Si of the protruded surface of the silicon structure moves to and fills the depressed surface, the substrate is subjected to hydrogen radicals at a set temperature, a set pressure and a set time. Including the step of exposure to,
The set temperature is a temperature at which the substrate can be heated to 400 degrees Celsius or more and 1000 degrees Celsius or less,
The set pressure is 1 Torr or more and 10 Torr or less inside the chamber,
The setting time is 1 minute or more and 10 minutes or less of the silicon structure surface roughness improvement method. delete delete delete delete delete According to claim 1,
The hydrogen radical is a silicon structure surface roughness improvement method that is generated by exciting hydrogen gas with plasma. According to claim 1,
The method of improving the surface roughness of the silicon structure further comprising the step of evacuating the inside of the chamber simultaneously with the step of exposing the substrate to the hydrogen radicals or after a set time. In the substrate processing apparatus,
a process chamber defining a processing space;
a support unit provided in the processing space, including a heater on which a substrate to be processed is placed, and which heats the substrate to be processed;
an inductively coupled plasma excitation unit generating radicals required by the process chamber;
a shower head to uniformly spray the radicals generated from the plasma excitation unit into the process chamber;
an exhaust unit for exhausting the atmosphere of the processing space;
A controller for controlling the pressure of the process chamber processing space, the heater, and a processing time of the substrate to be processed;
The radical is a hydrogen radical,
The substrate to be processed is one on which a silicon structure, which is single crystal silicon, is formed,
The part of the substrate processing apparatus exposed to the hydrogen radical does not contain a silicon component,
In order to improve the surface roughness of the silicon structure through Si migration in which Si of the protruded surface of the silicon structure moves to and fills the depressed surface, the controller:
controlling the heater so that the substrate to be processed is heated to 400 degrees Celsius or more and 1000 degrees Celsius or less;
controlling the exhaust unit to maintain the pressure in the processing space at 1 Torr or higher and at 10 Torr or lower;
A substrate processing apparatus for controlling the substrate to be processed to be exposed to the radical for 1 minute or more and 10 minutes or less. delete delete delete delete delete According to claim 9,
The controller,
The substrate processing apparatus controls the exhaust unit to exhaust the atmosphere of the processing space at the same time that the substrate to be processed is exposed to the radical or after a set time.

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