KR20180082324A - Process for forming amorphous silicon layer including carbon and/or boron and amorphous silicon formed by the same - Google Patents

Abstract

According to the present invention, a method for forming an amorphous silicon layer having carbon and/or boron with low stress characteristics as a hard mask applies RF power and pulsed cathodic DC power to a substrate support unit on which a substrate is mounted while facing a shower head, and forms an amorphous silicon layer having carbon and/or boron on the substrate by grounding the shower head.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of forming an amorphous silicon film including carbon and / or boron, and an amorphous silicon film formed by the method.

The present invention relates to a method of forming an amorphous silicon film containing carbon and / or boron, and an amorphous silicon film containing carbon and / or boron produced thereby and a method of manufacturing a hard mask film using the same.

In recent years, the semiconductor industry is becoming increasingly refined, and an effective lithographic process is essential to realize such ultra-fine technology. In particular, there is an increasing demand for optimization of the hard mask process, which is essential for the etching process.

The hard mask film acts as an interlayer to transfer the fine pattern of the photoresist to the lower substrate layer through the selective etching process. Therefore, in order to be applied to a mass production process as a hard mask, the hard mask film should have a hardness enough to exhibit sufficient etching resistance, and should not affect the lower substrate layer because the stress is low or close to zero.

The present invention aims to provide an amorphous silicon film containing carbon and / or boron having low stress characteristics as a hard mask.

The present invention aims to provide an amorphous silicon film containing carbon and / or boron having high hardness characteristics as a hard mask.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not to be construed as limiting the invention as defined by the appended art, except as may be apparent to one of ordinary skill in the art, It will be possible.

A method of forming an amorphous silicon film according to embodiments includes (a) forming an amorphous silicon film containing carbon, (b) forming an amorphous silicon film containing carbon and boron, and (b) (b) is carried out alternately at least once. In the method (a), the silicon source gas and the carbon source gas are fed toward the substrate through the showerhead Supplying RF power and pulsed negative DC power to the substrate support on which the substrate is mounted and supplying a carrier gas containing helium and a process gas containing the process gas to the substrate support, Wherein the amorphous silicon film is formed of a carbon-containing amorphous silicon film on the substrate, and the method (b) Supplying a carrier gas containing helium and a process gas containing a source gas, a carbon source gas, a boron source gas, and helium to a substrate support, which is opposed to the showerhead and on which the substrate is mounted, And the showerhead is grounded to form an amorphous silicon film containing carbon and boron on the substrate.

According to the method for forming an amorphous silicon film including carbon and / or boron according to embodiments, an amorphous silicon film including carbon and / or boron applicable to a mass production process can be provided.

The amorphous silicon film comprising carbon and / or boron according to embodiments may have hardness and / or stress properties applicable as a hard mask.

1 is an image of a SiC film formed by a conventional method,
2 is a cross-sectional view of a substrate processing apparatus for forming an amorphous silicon film containing carbon according to embodiments of the present invention,
FIG. 3 is a schematic view showing an example of a duty ratio for each frequency of pulsed DC power used in a method of manufacturing an amorphous silicon film containing carbon according to embodiments of the present invention,
4 is a graph showing film stress according to applied RF power,
5 is a graph showing film stress according to the flow rate of the carbon source gas.
6 is a graph showing the result of measuring the element composition ratio of the film with the flow rate of the carbon source gas.
FIG. 7 shows images obtained by measuring the surface roughness of a film formed by the flow rate of boron with an atomic force microscope (AFM).
8 is a graph showing a result of measuring the selectivity of the film formed according to the flow rate of boron.
Figure 9 shows a cross section of various hard mask films that may be formed according to embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

The hard mask film according to the embodiments is a hard mask film that can be used in the manufacturing process of various elements such as the pre-process and post-process of the semiconductor process, the memory device and the logic device. The hard mask film provided according to the embodiments is a hard mask film made of amorphous silicon including carbon having low stress characteristics and high hardness characteristics.

The hard mask film according to the embodiments is substantially made of silicon and carbon, and contains a residual amount of hydrogen, and may further include a trace amount of oxygen. The content of silicon in the amorphous silicon film containing carbon constituting the hard mask film is 60 atomic% or more and 80 atomic% or less, and the content of carbon is 40 atomic% or less. When the content of carbon exceeds 40 atomic%, the stress of the amorphous silicon film containing carbon becomes large, causing warpage of the substrate, and an error occurs in the patterning process using the hard mask. The amorphous silicon film containing carbon within the above-mentioned content range may have a low compression stress of -200 MPa to 0 MPa, more preferably -150 MPa to 0 MPa. When the absolute value of the compressive stress is more than 200 MPa, the substrate is warped so that it is difficult to have a precise patterning shape in a subsequent patterning process, and it is difficult to obtain a desired etch selectivity ratio.

The amorphous silicon film containing carbon within the above-mentioned content range shows a hardness of 10 GPa or more. In the case of 10 GPa or less, it is difficult to obtain a desired etch selectivity in the patterning process because the hard mask film is thin.

The average particle diameter of the amorphous silicon film containing carbon according to the embodiments is 2 nm or less, which indicates substantially amorphous state. When a hard mask film is formed of a substantially amorphous film, a desired etching profile can be obtained in a fine patterning process because the average grain size is small. On the other hand, when the average particle size is larger than 2 nm or substantially crystalline, it may be difficult to obtain a desired etching profile in the fine patterning process.

The carbon-containing amorphous silicon film according to the embodiments may be formed by applying RF power only to a conventional CCP (Capacitively Coupled Plasma) type PECVD apparatus or a showerhead, or by applying RF power to the showerhead while DC power is applied to the substrate support It can not be formed with a desired film quality in a RID (Reactive Ion Deposition) type PECVD apparatus. In the case of CCP type PECVD, the peripheral portion of the wafer is severely damaged as shown in FIG. 1 (a). On the other hand, when RF power is applied only to the showerhead and the substrate supporting part is grounded, the surface of the film formed as shown in FIG. 1 (b) is deteriorated and can not be applied as a hard mask film. (Non-pulsed) DC power is applied to the substrate supporting portion, the film formed as shown in FIG. 1 (c) is hazed and the film has a minimum hardness required as a hard mask It is difficult to secure etching selectivity as a hard mask.

In the meantime, the RID type substrate processing apparatus shown in FIG. 2 is used as in the embodiment of the present invention. In the shower head 300, grounding is performed by applying RF power and negative polarity DC power to the substrate supporting unit 200 When the deposition process is carried out, the content of silicon is 60 atomic% or more and 80 atomic% or less, the content of carbon is 40 atomic% or less, and the carbon contains a low compressive stress of -200 MPa to 0 MPa and a high hardness of 10 GPa or more An amorphous silicon film can be formed.

2, a substrate processing apparatus of the RID type includes a chamber 100 having an inner space, a substrate supporting unit 200 for supporting a substrate s drawn into the chamber 100, An RF power supply unit 600 for applying RF power, a DC power supply unit 400 for applying DC power to the substrate support unit 200, and a substrate support unit 200 disposed opposite to the substrate support unit 200, And a shower head 300 which is grounded. A filter 500 installed between the RF power supply unit 600 and the DC power supply unit 400 and first and second raw material supply units 110 and 120 for supplying the process raw material to the showerhead 300. Here, the RF power supply unit 600 and the DC power supply unit 400 are disposed in parallel with each other, and the filter 500 functions to filter RF power to protect the DC power supply unit 400 from RF power.

Unlike the power connection method shown in FIG. 2, the RF power supply unit 600 and the DC power supply unit 400 may be connected in series.

The chamber 100 is formed in the shape of a rectangular tube having an inner space, and a predetermined reaction space for processing the substrate s is provided therein. In the embodiment, the chamber 100 is manufactured in a rectangular tube shape. However, the chamber 100 is not limited to this, and it is preferable to fabricate the chamber 100 so as to correspond to the shape of the substrate s. In the embodiment, the chamber 100 is integrally formed. However, it is also possible to separate the chamber 100 from the lower chamber having the upper portion opened and the chamber lid covering the upper portion of the lower chamber. Although not shown, there is provided an exhaust unit for exhausting the inside of the chamber 100, a substrate entrance for entering and exiting the substrate s, and a pressure regulating unit for regulating the pressure inside the chamber.

The substrate supporting unit 200 includes a substrate supporting part 210 installed on the lower side of the chamber 100 to support the substrate s drawn into the chamber 100, a shaft 221 supporting the substrate supporting part 210, A driving unit 220 having a power unit 222 for moving up and down the shaft 221 and a heater for heating the substrate s in the substrate supporting unit 210. Here, the substrate supporter 210 may use either an electrostatic chuck for supporting the substrate s using an electrostatic force or a vacuum chuck for supporting the substrate s using a vacuum suction force. Various means capable of supporting and holding the substrate s can be used. In this embodiment, the substrate supporting part 210 is formed in a rectangular shape in cross section. However, the substrate supporting part 210 may be formed in various shapes corresponding to the substrate s.

A method of forming an amorphous silicon film containing carbon by using the RID type substrate processing apparatus illustrated in FIG. 2 will be described.

First, a wafer (s), for example, is provided, and the wafer is drawn into the chamber 100 and placed on the substrate support 210. At this time, it is preferable that the distance between the substrate supporting part 210 and the shower head 300 is 2 cm or less. For example, if the distance between the substrate support 210 and the showerhead 300 exceeds 2 cm, a plasma discharge may be unstable or an arc may be generated at a high pressure.

Thereafter, the interior of the chamber 100 is stabilized by injecting the process gas toward the substrate s using the first and second raw material supply units 110 and 120 and the shower head 300. The process gas may include a silicon source gas and a carbon source gas. Various sources such as SiH ₄ , Si ₂ H ₆ and Si ₃ H ₈ may be used as the silicon source gas. Various source gases such as CxHy (x: y = 1: 2 to 1:10) can be used as the carbon source gas. The process gas is supplied as a mixed gas with a high purity carrier gas. As the carrier gas, Ar, He, N ₂ , H ₂ , O ₂ gas and the like can be used. The flow rate of the carbon source gas also influences the carbon content in the resulting film, so that the stress and the strength of the film produced can be controlled. Preferably, the flow rate of the carbon source gas is adjusted to be 50 sccm or less in order to control the stress and the strength of the film. As the carrier gas, a He gas may be supplied at a flow rate of 200 to 1400 sccm and other additional carrier gas may be used. The He gas is an inert gas and has a small atomic weight, thereby improving the uniformity and density of the thin film and improving the stability of the plasma. The RF power supply unit 600 and the DC power supply unit 400 are used to supply RF power and DC power to the substrate support unit 210 when the atmosphere in the chamber 100 is stabilized by supplying the process gas. The RF power and the DC power supply can be simultaneously performed, but the present invention is not limited thereto, and one of the RF power and the DC power may be supplied first, and the remaining one may be supplied with a time difference.

Before the process gas is supplied, the interior of the chamber 100 is continuously pumped by a pumping line (not shown) connected to the chamber 100. Therefore, when the process gas is supplied, the flow of the process gas in the chamber 100 becomes unstable and the process pressure becomes unstable. When the RF power and the DC power are supplied when the atmosphere in the chamber 100 is unstable, the plasma formed becomes unstable. Therefore, after the atmosphere in the chamber 100 is stabilized in the desired atmosphere, RF power and DC power are supplied It is preferable to form a plasma. The time required for stabilization may be about 1 minute, but it may vary depending on various conditions such as the size and pressure of the chamber 100.

The RF power can be applied in the range of 100W to 1600W, and the DC power is applied by pulsing the negative voltage. The DC voltage can apply a negative voltage of -1000 V or more. The frequency of the DC power is adjusted to be 20 kHz to 120 kHz. DC power is not applied continuously but pulsed and applied. The pressure is adjusted to be 1.5 to 5 Torr.

Pulsed negative voltage application with DC power is intended to control the stress and hardness of the thin film formed. In other words, it is possible to control the content of carbon in the thin film formed by pulsed negative voltage with DC power. When pulsed DC power is applied, the content of carbon can be controlled by breaking the Si-C bonds by the colliding ions when DC is on.

The DC power is pulsed so that the reserve time during which DC power is not applied during application is 20 μsec or less. When the frequency is low, the possible reserve time is long. When the frequency is high, the possible reserve time can be shortened. However, the relationship is not linear. That is, as shown in FIG. 3, the duty ratio is set such that the DC power is not applied in the range of 0.4 to 0.9. In other words, the duty ratio is adjusted so as to fall within the range of 0.1 to 0.6.

On the other hand, when the RF power is as high as 1600 W, since the plasma density is high, when -1000 V DC power is applied, plasma density is superimposed and reflection power is generated between RF power and DC power of different frequency bands, have. Therefore, when the RF power is as high as 1600 W, the DC voltage is preferably -600 V to -300 V, but this is merely an example.

That is, the RF power, the DC voltage, the DC voltage frequency, and the reserve time (or duty-to-charge ratio) in which the pulsed DC power is not applied are mutually influential variables,

As described above, when RF power is supplied to the showerhead 300 using the RF power supply unit 600 in the stabilized chamber 100 supplied with the process gas, plasma is generated between the showerhead 300 and the substrate supporting unit 210 Is generated. Further, when pulsed DC power of negative voltage is applied to the substrate supporter 210 using the DC power supply unit 400, the sheath potential difference between the generated plasma and the substrate is increased, And the ion energy is increased. In addition, since the DC power reserve time is adjusted to 20 μsec or less (or the duty on ratio (DC power applied) is adjusted to 0.1 to 0.6), uniformity of film quality and hardness hardness and stress can be adjusted to a desired range.

On the other hand, as described above, when the ground is connected to the base supporting part using RF power on the shower head using the CEC (Charge Coupled Plasma) PECVD equipment, the moving speed and energy of ions incident on the substrate are low, The peripheral portion of the wafer is seriously damaged. Also, when DC power is continuously applied, the ions collide with each other continuously, so that the film quality formed as shown in FIG. 1 (c) is opaque and the etching selectivity can not be controlled within a desired range.

However, in the embodiment of the present invention, the reserve time during which the pulsed DC power is not applied is adjusted to 20 μsec or less (or the range of duty-on ratio in which DC power is applied is 0.1 to 0.6) , The uniformity, hardness and stress of the film can be adjusted to a desired range.

Table 1 shows the results of measuring the characteristics of the film formed according to the RF power, and FIG. 4 is a graph showing the relationship between the RF power and the stress of the film to be formed.

[Characteristics of amorphous silicon film containing carbon by RF power] RF power (W) Si (atomic%) C (atomic%) 0 (atomic%) Stress (MPa) Hardness
(GPa) 0 81.7 13.7 4.6 -89.2 11.1 100 76.4 19.2 4.4 -113 11.4 400 73.3 22.3 4.4 -165 12 700 70 25.4 4.6 -190 12.35 1000 68.9 26.5 4.6 -194 12.74 1300 67.5 26.8 5.7 -208.3 12.96 1600 66.2 27.1 6.7 -249.9 13.7

The results shown in Table 1 are obtained by fixing the DC voltage at -600 V, the DC power frequency at 80 kHz, the reserve time at 10 μsec (duty-off ratio of 0.8), the CH ₄ gas flow rate at ₄₀ sccm, and the Si ₂ H ₆ flow rate at (Atomic concentration% (atomic%)) of the film after deposition of the film at a flow rate of 20 sccm, a flow rate of He and Ar of 1400 sccm and 3000 sccm, a pressure of 2.5 Torr, and an RF power of 0 W to 1600 W, And the hardness is measured.

Referring to Table 1 and FIG. 4, when the RF power is increased, stress is increased in the case of depositing a thin film having a certain thickness. It can also be seen that the content of carbon increases with increasing RF power as shown in Table 1.

From this, it can be seen that there is a positive correlation between stress and carbon content. It can be seen that the composition ratio, stress and hardness of the film formed according to the RF power can be controlled.

Oxygen may be contained in the chamber 100 of the substrate processing apparatus while oxygen (impurities in the vacuum) is formed while the thin film is formed, or oxygen contained in the raw material precursor itself, or an analysis for analyzing an element contained in the deposited thin film May be oxygen generated during the process. Since the content of oxygen is less than 7 atomic%, the effect of the thin film is not greatly affected.

On the other hand, the produced film has an average particle diameter of 2 nm or less, which indicates that the film is substantially amorphous. Since the average particle diameter is 2 nm or less, a desired etching profile can be obtained in the fine patterning process.

From the results shown in FIG. 4, it is necessary to set the RF power to 1000 W or less in order to make the stress of the film -200 MPa or more under the condition that the DC voltage is -600 V, the DC power frequency is 80 kHz, and the reserve time when DC power is not applied is 10 μsec It is possible to deduce that it is preferable. Of course, the range of the RF power can be changed when the DC power condition is changed.

Table 2 and Table 4 show the measurement result of the relationship between the DC power and the compressive stress of the formed film, and Table 3 shows the result of measuring the relationship between the DC power and the compressive stress and hardness of the film to be formed. Si ₂ H ₆ as the silicon source gas, CH ₄ as the carbon source gas, and He and Ar as the carrier gas. The compressive stress is measured using FSM-128L flatness meter and the hardness is measured using Nano Indenter XP by MTS.

[DC power condition and compressive stress of film formed] RF power (W) 300 300 DC voltage (V) -300 -300 Frequency (kHz) 20 80 Reserve time (μsec) 20 10 Duty Off Ratio 0.4 0.8 Duty On Ratio 0.6 0.2 Compressive stress
(Compressive Stress) (MPa) -55.35 -412.6

[DC power condition and compressive stress and hardness of film formed] RF power (W) 700 700 700 700 DC voltage (V) -600 -600 -600 -600 Frequency (kHz) 20 60 80 120 Reserve time (μsec) 20 15 10 5 Duty-off ratio
(Duty Off Ratio) 0.4 0.9 0.8 0.6 Duty On Ratio 0.6 0.1 0.2 0.4 Compressive stress
(Compressive Stress) (MPa) -533.90 -279.90 -198.70 -134.50 Hardness (GPa) 15.62 14.23 13.51 11.79

[DC power condition and compressive stress of film formed] RF power (W) 1600 1600 1600 DC voltage (V) -450 -450 -450 Frequency (kHz) 20 60 80 Reserve time (μsec) 20 15 10 Duty-off ratio
(Duty Off Ratio) 0.4 0.9 0.8 Duty On Ratio 0.6 0.1 0.2 Compressive stress
(Compressive Stress) (MPa) -282.8 -139.4 -260.4

From the results of Tables 2 to 4, it can be seen that the frequency of the DC power at the same RF power and the time (Reserve Time) at which the DC power is not applied (or the duty ratio) are affected.

The results of Table 2 show that the compressive stress of the film formed at a low RF power (300 W) and a relatively low negative DC voltage (-300 V) at 20 kHz and a reserve time of 20 μsec (duty ratio 0.6) is as low as -55.35 MPa Can be seen.

The results of Table 3 show that the compressive stress of the film formed at an intermediate RF power (700 W) and a relatively large negative DC voltage (-600 V) at 120 KHz and a reserve time of 5 μsec (duty ratio 0.4) is as low as -134.5 MPa Can be seen.

The results of Table 4 show that the compressive stress of the film formed at a high RF power (1600 W) and a relatively intermediate negative DC voltage (-450 V) at 60 KHz and a reserve time of 15 μsec (duty ratio 0.1) is -139.4 MPa It is shown that it is low.

Therefore, from the results of Tables 2 to 4, the reserve time during which the negative DC voltage is not applied in accordance with the RF power and the DC voltage is set to 20 μsec to 5 μsec (or the duty ratio is 0.1 to 0.6) it is possible to similarly form an amorphous silicon film containing carbon having a desired low compression stress or high hardness by similarly controlling the effect of ion acceleration applied to the film formed on the silicon substrate (s).

If the above-mentioned pulsed DC voltage deviates from the reserve time (or the duty ratio 0.1 to 0.6) in which no pulsed DC voltage is applied, the instability of the plasma formed in the chamber 100 increases, the voltage is not properly applied, It is impossible to control the compression stress or hardness of the film formed on the substrate to a desired range even if the deposition is not performed or the film is formed.

FIG. 5 is a graph showing a change in film stress according to a flow rate of a carbon source gas, and FIG. 6 is a composition ratio of a film with respect to a flow rate of a carbon source gas.

The amorphous silicon film containing carbon is formed by varying the deposition temperature to 500 degrees Celsius and 550 degrees Celsius by varying the flow rates of the carbon source gas CH ₄ to 10 sccm, 20 sccm, 30 sccm, ₄₀ sccm, and 50 sccm for each group. At this time, the RF power was 1600 W, the DC voltage was -300 V, the DC power frequency was 20 kHz, the reserve time during which the DC power was not applied was 20 μsec (duty ratio 0.6), and the pressure was 3 Torr.

Referring to FIG. 5, as the flow rate of CH ₄ increases under the same temperature condition, the stress of the film formed increases. This is consistent with the increase in the compressive stress as the content of carbon increases as the reason explained with reference to Table 2.

6 is a graph showing the result of measuring the element composition ratio of the film formed at 550 degrees. Referring to FIG. 6, it can be seen that as the flow rate of CH ₄ increases, the content of C increases and the content of Si decreases.

Table 5, but unlike the flow rate of CH ₄ to 20sccm, 25sccm, 30sccm, 40sccm, 50sccm, Si 2 H 6 The results are obtained by measuring the element composition ratio of the film formed by fixing the flow rate at a constant flow rate, setting the DC power frequency to 80 kHz, and the reserve time when the DC power is not applied to 10 μsec (duty ratio 0.2).

[Flow rate and element composition ratio of CH ₄ ] Flow rate of CH ₄ 20 25 30 40 45 50 C (atomic%) 21.1 26.9 28.9 33.2 35.1 35.6

On the other hand, when the content of carbon in the deposited thin film is 40 atomic% or more, there is a problem that compression stress is increased, a large number of particles are formed on the substrate, the deposition is difficult and the thin film is opaque And is therefore unsuitable as a hard mask film.

The hard mask film according to other embodiments further includes boron in addition to silicon and carbon, and contains a residual amount of hydrogen, and may further contain a trace amount of oxygen. By further including boron, the selectivity of the hard mask film can be further improved. The content of silicon in the hard mask film constituting the hard mask film is 30 atomic% to 50 atomic%, the content of carbon is 10 atomic% to 15 atomic%, and the content of boron is 15 atomic% to 30 atomic% . Considering the allowable range of stress and surface roughness of the hard mask film, the content of boron is preferably 30 atomic% or less.

The hardness and the average grain size of the amorphous silicon film containing boron and carbon are substantially the same as those of the amorphous silicon film containing carbon described with reference to Figs. A method of forming an amorphous silicon film containing boron and carbon may be substantially the same as the method described with reference to FIGS. 2 and 3. FIG. The RID type substrate processing apparatus of FIG. 2 further includes a third supply unit (not shown) for supplying boron in addition to the first and second raw material supply units 110 and 120, and the boron source gas may include B ₂ H ₆ Of gas can be used. The supply of the boron source gas may be adjusted to be more than 0 sccm and less than 30 sccm considering the selection ratio of the hard mask film, stress, and surface roughness.

Table 6 shows the measurement results of the element composition ratio and the surface roughness of the film formed according to the flow rate of boron. Fig. 7 shows images obtained by measuring the surface roughness with an atomic force microscope (AFM). Fig. Graph. At the film formation, the flow rate of Si ₂ H ₆ was 40 sccm, the flow rate of C ₃ H ₆ was 7 sccm, RF power was 1600 W, DC voltage was -300 V, DC power was 20 kHz, (Duty-to-noise ratio 0.6) and the pressure was 3 Torr.

[Flow rate and element composition ratio of B ₂ H ₆ ] B ₂ H ₆ flow rate (sccm) Si (atomic%) C (atomic%) B (atomic%) Surface roughness (RMS) (nm) 0 74.8 18.5 0 0.35 25 51.6 15.9 27.4 1.50 50 45.1 13.3 37.2 2.47

From the results in Table 6 and FIG. 7, it can be seen that the surface roughness increases as the flow rate of boron increases. From the results of FIG. 8, it can be seen that the selectivity ratio increases as the boron flow rate increases. In the case of FIG. 8, when the boron is not included (when the flow rate of B ₂ H ₆ is 0), the selection ratio increases by about 15-30% when the contrast boron is included.

It is preferable to set the flow rate of the boron source gas to 30 sccm or less and the boron content in the hard mask film to be 30 atomic% or less since it is important to reduce the surface roughness and increase the selectivity of the hard mask film have.

Figure 9 shows a cross section of various hard mask films that may be formed according to embodiments.

9 (a) shows an amorphous silicon film (A) containing carbon and a double film of an amorphous silicon film (B) containing boron and carbon. In the case of the amorphous silicon film (B) containing boron and carbon, it is advantageous to improve the selectivity. However, when the boron is diffused into the underlying film of the hard mask film, the reliability of the device may be lowered. An amorphous silicon film (A) containing carbon may be formed as a contact film, and an amorphous silicon film (B) containing boron and carbon having a high selectivity may be formed as an upper film.

9 (b) shows a multilayer film of an amorphous silicon film (A) containing carbon and an amorphous silicon film (B) containing boron and carbon. The lowermost layer may be formed of an amorphous silicon film (A) containing carbon to prevent the diffusion of boron and the uppermost layer may be formed of an amorphous silicon film (A) containing carbon, and SiON It is possible to improve the adhesion of the lower antireflection film to the lower antireflection film. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

Claims (18)

(A) a method of forming an amorphous silicon film containing carbon, (b) a method of forming an amorphous silicon film containing carbon and boron, and (a) a method of performing the method (b) Wherein the amorphous silicon film is formed by a method comprising the steps of:
The method (a) comprises: supplying a carrier gas including helium and a process gas containing a silicon source gas and a carbon source gas toward the substrate through a showerhead;
Applying a DC power of RF power and pulsed negative polarity to a substrate supporting part on which the substrate is mounted facing the shower head and grounding the showerhead to form an amorphous silicon film containing carbon on the substrate,
The method (b) includes: supplying a carrier gas including helium and a process gas including a silicon source gas, a carbon source gas, and a boron source gas toward the substrate through a showerhead;
Applying RF power and pulsed negative DC power to a substrate support that is opposite to the showerhead and on which the substrate is mounted and grounding the showerhead to form an amorphous silicon film comprising carbon and boron on the substrate, A method of forming an amorphous silicon film. The method according to claim 1,
Wherein the amorphous silicon film containing carbon has a carbon content of less than 40 atomic% and a silicon content of 60 to 80 atomic%. The method according to claim 1,
Wherein the amorphous silicon film containing carbon and boron has a carbon content of 15 atomic% or less, a silicon content of 30 atomic% to 50 atomic%, and a boron content of 30 atomic% or less. The method according to claim 1,
Wherein the amorphous silicon film containing carbon or the amorphous silicon film containing carbon and boron has an average grain size of 2 nm or less. The method according to claim 1,
Wherein the amorphous silicon film containing carbon or the amorphous silicon film containing carbon and boron has a compressive stress of -200 MPa to 0 MPa. The method according to claim 1,
Wherein the amorphous silicon film containing carbon or the amorphous silicon film containing carbon and boron has a hardness of 10 GPa or more. The method according to claim 1,
A method of forming an amorphous silicon film having a reserve time of 20 mu sec or less in which the pulsed negative DC power is not applied 8. The method of claim 7,
A method of forming an amorphous silicon film having a reserve time of 5 占 sec or more in which the pulsed negative DC power is not applied The method according to claim 1,
And the frequency of the pulsed negative DC power is 20 kHz to 120 kHz. The method according to claim 1,
Wherein the RF power is in a range of 100W to 1600W. The method according to claim 1,
Wherein the DC voltage of the negative polarity is -1000 V or more. The method according to claim 1,
Wherein the carbon source gas is supplied at a flow rate of more than 0 sccm and not more than 50 sccm. The method according to claim 1,
Wherein the boron source gas is supplied at a flow rate of more than 0 sccm and not more than 30 sccm. The method according to claim 1,
Wherein the RF power and the pulsed negative DC power are simultaneously applied to the amorphous silicon film. The content of carbon is 40 atom% or less,
The content of silicon is 60 atomic% or more and 80 atomic% or less,
Compression stress is -200 MPa to 0 MPa,
An amorphous silicon film comprising carbon having a hardness of 10 GPa or more. 14. The method of claim 13,
Wherein the amorphous silicon film containing carbon has an average grain size of 2 nm or less. The content of carbon is 15 atom% or less,
Wherein the content of silicon is 30 atom% to 50 atom%
The content of boron is 30 atom% or less,
Compression stress is -200 MPa to 0 MPa,
Having a hardness of 10 GPa or more
An amorphous silicon film comprising carbon and boron. 18. The method of claim 17,
Wherein the amorphous silicon film containing carbon and boron has an average grain size of 2 nm or less and boron.

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