KR100688481B1 - Method of manufacturing tungsten silicide film - Google Patents

Abstract

In the method of forming a tungsten silicide layer, a plasma is generated in the deposition region before the nucleus layer forming step, and a gas containing a silicon component and a gas containing a hydrogen component are introduced into the deposition region to be pre-flushed or a tungsten silicide main layer is formed. After the formation, plasma is generated in the deposition region in which the tungsten silicide layer is formed, and the gas containing hydrogen component is reintroduced into the deposition region and post-flushed, thereby increasing the seeding effect of the nuclear layer and in the nucleus layer and the tungsten silicide main layer. Techniques for significantly eliminating Cl content that may be included are disclosed.

Plunge, Plasma, Polyside

Description

Tungsten silicide layer formation method {Method of manufacturing tungsten silicide film}

1 is a flow chart illustrating the step of forming a tungsten silicide layer in accordance with the present invention.

The present invention relates to a method of forming a tungsten silicide layer having a polyside structure, and more particularly, to a method of forming a tungsten silicide layer capable of reducing or suppressing voids of a gate poly formed under the tungsten silicide layer.

As semiconductor devices have been highly integrated, a polyside structure in which tungsten silicide with low resistivity is applied to bit lines and gate lines is adopted. In general, the tungsten silicide layer is formed by reacting WF ₆ gas and SiH ₄ gas using low pressure chemical vapor deposition. However, the tungsten silicide layer formed by this method has a low step coverage of 25% or less in contact holes having a high aspect ratio due to high integration of semiconductor devices. In addition, a large amount of the F component is contained in the tungsten silicide layer by HF, which is one of by-products generated by the reaction between the WF ₆ gas and the SiH ₄ gas. The F component has a problem of decreasing the reliability of the gate oxide film by increasing the thickness of the gate oxide film by diffusing into the gate oxide film formed under the tungsten silicide.

To solve this problem, a technique of forming a tungsten silicide layer using SiH ₂ Cl ₂ (DCS) gas instead of SiH ₄ gas has been proposed. Since the DCS is less reactive than SiH ₄ , the content of the F component in the tungsten silicide layer is 2 to 3 orders less than that in the case of using SiH ₄ , thereby minimizing the increase in the thickness of the gate oxide film and reducing its reliability. It can be suppressed, and, the step coverage is also increased 2 times as compared with the case of using SiH ₄ in the contact hole having a high aspect ratio.

However, when the gate line is formed using the reaction between DCS and WF ₆ , the following problem occurs. Since DCS has poor initial deposition characteristics, a nucleus layer is formed before full formation of the tungsten silicide layer. In the nucleus layer forming process, DCS: WF6 should be 100: 1 or more. However, since the DCS contains a Cl component, the Cl component reacts with the silicon component of the gate poly formed directly under the tungsten silicide layer, so that the silicon component of the gate poly escapes into the tungsten silicide layer. Therefore, there is a problem that voids occur in the gate poly. When voids occur in the gate poly, the above-described transistors do not serve as semiconductor elements at all, such that the threshold voltage of the transistor including the gate electrode composed of the gate poly and the tungsten silicide layer is not measured.

In order to reduce the content of Cl which causes the gate poly to form voids, it is necessary to reduce DCS: WF ₆ in the nucleus layer formation step, and to do this, it is necessary to uniformly seed silicon on the gate poly surface. A technique for flushing the silicon layer prior to the nuclear layer formation step using a DCS gas has been proposed, but this technique has a limited seeding effect, thus reducing DCS: WF ₆ .

Thus, instead of DCS gas, SiH ₄ gas, Si ₂ H ₆ gas, Si ₃ H ₈ or H ₂ gas is used to pre-flush before the nuclear layer formation step and post the formation of the tungsten silicide layer Post-flushing technology has been developed by AMAT (Applied MATerials, Inc .; related US Pat. Nos. 5,643,633 and 5,997,950).

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a method of forming a tungsten silicide layer capable of suppressing generation of voids in a gate poly of a gate line having a polyside structure.

In order to achieve the technical problem to be achieved by the present invention, the substrate is placed in the deposition region. The plasma is applied directly to the deposition region or remotely using microwave, and a gas containing a silicon component and a gas containing a hydrogen component are introduced into the deposition region and preflushed. The supply of the gas containing the silicon component is continued, but the flow of the gas containing the hydrogen component is blocked, and the gas including the tungsten component is introduced into the deposition region to form a nuclear layer on the upper surface of the substrate. Inflow of a gas containing silicon and a gas containing tungsten is continued to form a tungsten silicide layer on the upper surface of the nuclear layer. Subsequently, the supply of the gas containing the silicon component continues and the supply of the gas containing the tungsten component is interrupted, and then plasma is applied to the deposition region in which the tungsten silicide layer is formed, and the gas containing the hydrogen component is reintroduced into the deposition region. Post flush. Here, the gas containing a silicon component is SiH2Cl2, SiH4, Si2H6 or Si3H8, the gas containing a hydrogen component is H2 PH3 or B2H6, and the gas containing tungsten is WF6.

The method may further include introducing and flushing a gas containing hydrogen into the deposition region between the nucleus layer forming step and the tungsten silicide layer forming step. In the flushing forming step, the substrate in the deposition region is heated or Plasma can be applied.

On the other hand, in order to lower the content of Cl in the nucleus layer or tungsten silicide layer, at least one of the steps of prefluxing before forming the nucleus layer, flushing before forming the tungsten silicide layer, which is the main layer after forming the nucleus layer, and postflushing after forming the tungsten silicide layer, Only can be done.

That is, as an example, the substrate is positioned in the deposition region, the gas including the silicon component and the gas including the tungsten component are introduced into the deposition region to sequentially form the nucleus layer and the tungsten silicide layer on the substrate. Next, the supply of the gas containing the silicon component is continued and the introduction of the gas containing the tungsten component is interrupted, and then a plasma is applied to the deposition region in which the tungsten silicide layer is formed, and the gas containing the hydrogen component is introduced into the deposition region. Post flush.

As another example, after placing the substrate in the deposition region, a gas containing a silicon component and a gas containing a tungsten component are introduced to form a nuclear layer. Next, the introduction of the gas containing the silicon component and the gas containing the tungsten component is blocked and the introduction of the gas containing hydrogen into the deposition region is continued to flush the nuclear layer. The inflow of the gas containing the hydrogen component is blocked, and the supply of the gas containing the silicon component and the gas containing the tungsten component is resumed to form a tungsten silicide layer on the upper surface of the nuclear layer.

Meanwhile, the gas including the hydrogen component may be continuously supplied into the deposition region throughout the nucleus layer forming step, the tungsten silicide layer forming step, the pre-flushing step, the flushing step and the post flushing step.

Hereinafter, the present invention will be described in detail with reference to FIG. 1.

The substrate (not shown) on which the tungsten silicide layer is to be formed is moved to a deposition region (not shown). The tungsten silicide layer is formed in two steps, namely, the nucleus layer forming step 20 and the main deposition 40. The substrate is preflushed before performing the nucleus layer forming step 20. In the pre-flushing step 10, while a plasma is applied to the deposition region, a gas containing a silicon component and a gas containing a hydrogen component are introduced into the deposition region. In addition, argon or helium gas is introduced into the deposition region as a carrier gas. The plasma may be applied directly to a chamber (not shown) having a deposition region or may be applied remotely using microwaves.

Examples of the gas containing a silicon component include SiH 2 Cl 2, SiH 4, Si 2 H 6, or Si 3 H 8, and a gas containing a hydrogen component includes H 2, PH 3, or B 2 H 6, and in this embodiment, SiH 2 Cl 2 is a gas containing a silicon component. Gas containing H2 was used. In the plasma state, SiH 2 Cl 2 is actively decomposed and the reaction between Si and Cl is increased. This Si raises the seeding effect of the silicon component in the nucleus layer forming step 20 which proceeds later. Therefore, the ratio of SiH 2 Cl 2 and WF 6 in the nuclear layer forming step 20 can be reduced to 50: 1 or less. On the other hand, the increased reactivity of Cl actively induces the reaction of Cl with the hydrogen atom supplied from the gas H2 containing the hydrogen component, thereby forming HCl. HCl is a by-product, which is removed from the deposition zone.

Next, in the nuclear layer formation step 20, SiH 2 Cl 4 already supplied is used as the silicon source gas, and the supply of the gas H 2 including the hydrogen component is cut off, and then WF 6 is introduced into the deposition region as a tungsten source gas to form a low temperature chemical vapor deposition. Proceed with the process. By the way, during the low temperature chemical vapor deposition process in which the nuclear layer having a predetermined thickness is formed on the upper surface of the substrate, since the Cl component reacts with H in the deposition region, a substantial portion thereof is removed. Thus, the nuclear layer is pre-filled using SiH4 or SiH2Cl4 without plasma treatment. Compared to the technique described above, the Cl content in the nuclear layer is less.

On the other hand, Cl generated in the nucleus layer forming step 20 can be removed by a flushing step 30 which is subsequently performed. That is, in the flushing step 30, the supply of SiH2Cl4, which is a silicon source gas, and WF6, which is a tungsten source gas, is cut off and flushed using a gas containing a hydrogen component, for example, H2, PH3, or B2H6 gas. In this example, H2 gas was used. However, since Cl is removed to some extent in the pre-flushing step 10, in the flushing step 30, the substrate may be heated with an energy source for improving the reactivity of Cl and hydrogen. Plasma may also be used.

Now in tungsten silicide buildup step 40, a tungsten silicide layer is formed on top of the nucleus layer. The H2 gas supplied from the flush formation step 30 was stopped, and the SiH2Cl4 supplied from the nuclear layer formation step was used as the silicon source gas and WF6 was used as the tungsten source gas to resume the supply to the deposition region, followed by low temperature chemical vapor deposition. To form a tungsten silicide layer.

Meanwhile, Cl generated in the forming step 40 of the tungsten silicide layer may be removed in the post flushing step 50. That is, in the post flushing step 50, SiH 2 Cl 6 is employed as the gas containing the silicon component, the supply of the gas is continued, the supply of the tungsten source gas is stopped, and the plasma is applied to the deposition region in which the tungsten silicide layer is formed. And supply of the hydrogen component containing gas and the carrier gas again.

In the present exemplary embodiment, the present invention is limited to performing the flushing using plasma before the nucleus layer forming step, after the tungsten silicide layer forming step, and after the nucleus layer forming step. At least one of these steps may be carried out to reduce the content of cl.                     

Specifically, in order to perform pre-flushing only, after placing a substrate in a deposition region, a plasma is applied to the deposition region, and a gas containing a silicon component and a gas containing a hydrogen component are introduced into the deposition region. and swing. Next, the supply of the gas including the silicon component is continued, but the inflow of the gas including the hydrogen component is blocked, and the gas including the tungsten component is introduced into the deposition region to form a nuclear layer on the substrate. Inflow of a gas containing silicon and a gas containing tungsten is continued to form a tungsten silicide layer on the upper surface of the nuclear layer.

In order to perform only post flushing, the substrate is placed in the deposition region, and a gas containing a silicon component and a gas containing a tungsten component are introduced into the deposition region to sequentially form a nucleus layer and a tungsten silicide layer on the substrate. Next, the supply of the gas containing the silicon component is continued and the introduction of the gas containing the tungsten component is interrupted, and then a plasma is applied to the deposition region in which the tungsten silicide layer is formed, and the gas containing the hydrogen component is introduced into the deposition region. Post flush.

In order to flush the nuclear layer, after placing the substrate in the deposition region, a gas containing a silicon component and a gas containing a tungsten component are introduced to form a nuclear layer. Next, the introduction of the gas containing the silicon component and the gas containing the tungsten component is blocked and the introduction of the gas containing hydrogen into the deposition region is continued to flush the nuclear layer. The inflow of the gas containing the hydrogen component is blocked, and the supply of the gas containing the silicon component and the gas containing the tungsten component is resumed to form a tungsten silicide layer on the upper surface of the nuclear layer.

The gas containing the hydrogen component may continue to be supplied into the deposition region throughout the nucleation layer formation step, tungsten silicide layer formation step, pre-flushing step, flushing step and post flushing step.

As described above, the present invention, before the nucleus layer forming step, after the tungsten silicide layer forming step and / or after the nucleus layer forming step, by introducing a gas containing a hydrogen component into the deposition region in the plasma applied to the deposition region By lowering the amount of Cl that can be included in the nucleus layer or the tungsten silicide layer, void formation of the gate poly can be suppressed.

In addition, in the pre-flushing step, the seeding effect can be increased by introducing and flushing a gas containing a silicon component into the deposition region while the plasma is applied. Therefore, the ratio of SiH 2 Cl 2 and WF 6 in the case of using SiH 2 Cl 2 in the nuclear layer formation step can be lowered, thereby reducing the amount of Cl generated.

Claims (14)

Positioning the substrate in the deposition region, Applying a plasma to the deposition region, introducing a gas containing a silicon component and a gas containing a hydrogen component into the deposition region and preflushing the same; Supplying the gas containing the silicon component to continue but interrupting or continuing the inflow of the gas containing the hydrogen component, and introducing a gas containing a tungsten component into the deposition region to form a nuclear layer on the substrate; , And And continuing to inflow of the gas containing the silicon component and the gas including the tungsten to form a tungsten silicide layer on the upper surface of the nuclear layer. The method of claim 1 wherein the gas comprising a silicon component is SiH 2 Cl 2, SiH 4, Si 2 H 6, or Si 3 H 8. The method of claim 1, wherein the gas containing hydrogen component is H2, B2H6 or PH3. The method of claim 1, wherein the gas comprising tungsten is WF6. The method of claim 1, wherein after the forming of the tungsten silicide layer, the supply of the gas including the silicon component is continued but the supply of the gas including the tungsten component is interrupted, and then the deposition region in which the tungsten silicide layer is formed is formed. And applying a plasma and introducing a gas containing the hydrogen component into the deposition region to post flush the tungsten silicide layer. The method of claim 1 or 5, wherein between the nucleus layer forming step and the tungsten silicide layer forming step, the supply of the gas containing the silicon component and the gas containing the tungsten component is interrupted, and then to the deposition region. The method of claim 12, further comprising the step of introducing and flushing the gas containing hydrogen. The method of claim 6, wherein the substrate of the deposition region is heated in the flushing step. The method of claim 6, wherein a plasma is applied to the deposition region in the flushing step. The method of claim 6, wherein the hydrogen containing gas is H 2, B 2 H 6, or PH 3.  7. The method of claim 6, further comprising the step of shutting off the supply of the gas comprising hydrogen between the flushing step and the tungsten silicide layer forming step. 6. The method of claim 1 or 5, wherein the plasma is applied directly to a reaction chamber having the deposition region or remotely using microwaves. Positioning the substrate in the deposition region, Introducing a gas containing a silicon component and a gas including a tungsten component into the deposition region to sequentially form a nuclear layer and a tungsten silicide layer on the substrate; The supply of the gas containing the silicon component is continued, but the introduction of the gas containing the tungsten component is blocked, a plasma is applied to the deposition region in which the tungsten silicide layer is formed, and a gas containing a hydrogen component is transferred to the deposition region. Tungsten silicide layer formation method comprising the step of introducing and post-flushing Positioning the substrate in the deposition region, Introducing a gas containing a silicon component and a gas containing a tungsten component into the deposition region to form a nuclear layer, Interrupting the introduction of the gas containing the silicon component and the gas containing the tungsten component and proceeding to introduce a gas containing hydrogen into the deposition region to flush the nuclear layer; and Tungsten silicide layer comprising the step of blocking the inflow of the gas containing the hydrogen component and resuming the supply of the gas containing the silicon component and the gas containing the tungsten component to form a tungsten silicide layer on the upper surface of the nuclear layer. Forming method. The method of claim 13, wherein plasma is applied to the deposition region in the flushing step.

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