KR102387925B1 - High-k hydrocarbon thin film and semiconductor device using the same - Google Patents

Abstract

A semiconductor device according to the inventive concept includes a substrate defining an active region, a gate dielectric layer disposed on the active region, a gate electrode disposed on the gate dielectric layer, and source/drain regions disposed in active regions on both sides of the gate electrode. , a contact structure electrically connected to the source/drain regions, and an ultra-thin insertion layer formed at an interface between the source/drain regions and the contact structure, wherein the ultra-thin insertion layer includes a high dielectric hydrocarbon thin film.

Description

High dielectric hydrocarbon thin film and semiconductor device using same

The technical field of the present invention relates to a method for manufacturing a high dielectric useful for manufacturing highly integrated devices due to high dielectric constant, low leakage current, and high insulation strength, a high dielectric manufactured by the method, and a semiconductor device using the high dielectric will be.

Carbon thin films have attracted a lot of attention in technical and industrial applications due to their excellent electrical and mechanical properties. The carbon-based material constituting the carbon thin film may be classified into diamond, graphene, and amorphous carbon according to bonding. Diamond has no electrical conductivity because carbon atoms are connected by sp3 bonds, but has very high hardness, and graphene has excellent conductivity because it consists only of sp2 bonds. In addition, since amorphous carbon has both sp3 bonds and sp2 bonds, conductivity is lower than that of graphene.

It is known that the bonding of carbon materials can be controlled by controlling the deposition temperature during the manufacture of the carbon thin film. Representatively, chemical vapor deposition (CVD) is a method widely used for manufacturing a carbon thin film, and high-quality graphene and carbon nanotubes can be manufactured at a high temperature of up to about 1000°C. When the deposition temperature is lowered to about 700° C. during deposition by the chemical vapor deposition method, a nano-graphite structure is formed, and at room temperature, amorphous carbon is formed.

Research on carbon-based materials is particularly focused on nanostructures with highly ordered structures such as graphene and carbon nanotubes, which have high potential as transparent conductors or next-generation semiconductors due to their high conductivity properties and transparency. . For this reason, nanographite and amorphous carbon also received less attention despite exhibiting several interesting properties.

The amorphous hydrocarbon film has been used as an etch mask from the advantage that it is easy to form a thin film with a uniform thickness, or has been used as a low-k insulator such as an interlayer material of a semiconductor metal wiring to prevent thin film defects and increase interlayer adhesion.

Since nano graphite and amorphous carbon contain a significant proportion of dangling bonds, which mean fixed free radicals, they react with hydrogen and/or HC radicals under appropriate conditions to form a hydrocarbon structure. However, attempts to develop and apply materials with new properties by utilizing dangling bonds in nano graphite or amorphous carbon have been limited.

On the other hand, the integration of high-density semiconductor devices such as memory devices and logic devices requires a high dielectric having a high dielectric constant, low leakage current, and high dielectric strength. For example, the gate length of a MOSFET transistor has sharply decreased from 10 μm to 10 nm in the past several decades, and thus the effectiveness of the SiO ₂ thin film used as an insulating film has reached its limit. Materials having a higher dielectric constant than SiO ₂ are commonly referred to as high-k materials. Accordingly, the development of a new high-k material having a higher dielectric constant than that of SiO ₂ is active. As a high-k material, Hf- or Zr-based oxides for a node of 100 nm or less have recently been attracting attention. Currently, research is being conducted in several directions, such as finding a material to replace the Hf source (eg, Al, Zr, Ta, STO, BST, etc.), or depositing another material by adding another material to the Hf source. .

Most of these high-k materials can be applied to devices in the form of oxide thin films. However, the high-k layer of the metal oxide includes a large number of bulk traps such as oxygen vacancies, increasing C-V hysteresis, and causing instability of the threshold voltage. In addition, when the node size of the device is reduced by 10 nm, the equivalent oxide thickness is required to be 1 nm or less, and electron tunneling of Hf- or Zr-based oxides may occur under these conditions. Moreover, since Hf- or Zr-based oxides are easy to crystallize, they exhibit high leakage currents and deteriorate the interfacial properties. Accordingly, development of a new high-k material is required for a technology having a node of 10 nm or less.

In order to solve the problems of the prior art, an object of the present invention is to provide a method of manufacturing a high dielectric useful for manufacturing a highly integrated device due to a high dielectric constant, low leakage current, and high insulation strength.

Another object of the present invention is to provide a high dielectric manufactured by the above method and a semiconductor device using the high dielectric.

In order to achieve the above object, the present invention comprises the steps of placing a substrate in a plasma reactor; injecting hydrocarbon gas and hydrogen gas together into the reactor; and generating plasma in the reactor; it relates to a method for manufacturing a high dielectric hydrocarbon thin film, comprising: controlling the temperature range in the reactor so that the dielectric constant is 20 or more as an amorphous structure.

In the present invention, the plasma reactor is to induce a reaction of a reaction gas by generating plasma in the reactor, for example, plasma-assisted chemical vapor deposition (PE-CVD) or inductively coupled plasma chemical vapor deposition (ICP-CVD), electron An example is a cyclotron resonance chemical vapor deposition (ECR-CVD) reactor. Plasma generates a large amount of highly reactive radicals from the reaction gas, so that a thin film can be formed even at a low temperature. In the following examples, ICP-CVD has been described as an example, but is not limited thereto.

In the present invention, as the substrate, any of the substrates generally used for the production of thin films may be used. For example, silicon, glass, metal, or a metal oxide substrate may be used, and a separate catalyst layer is not required. The substrate includes not only a substrate for manufacturing a semiconductor device, but also a substrate on which an active layer is formed.

Hydrocarbon gas and hydrogen gas are injected into the reactor as reaction gases. Any hydrocarbon gas may be used as long as it can form a hydrocarbon thin film by plasma, and methane, ethane, propane, ethylene, acetylene, propylene, and benzene, which can be used for graphene production by chemical vapor deposition at high temperatures usually One or more selected from may be used. However, other hydrocarbon gases are not excluded.

It is known that when plasma is applied in the presence of a mixture of hydrocarbon gas and hydrogen gas, a hydrocarbon thin film is formed on the substrate. there is. In the present invention, a mixture of hydrocarbon gas and hydrogen gas is used as a reaction gas to induce bonding of hydrogen and dangling bonds that increase in the thin film as the thin film manufacturing temperature is lowered. Of course, in addition to hydrocarbon gas and hydrogen gas, an inert gas such as argon or helium may be further included as a transport gas.

The volume ratio of hydrocarbon gas and hydrogen gas is preferably about 1:2 to 1:50. If the ratio of hydrogen gas is too low, a hydrocarbon thin film with a rough surface is formed, and if it is too high, the hydrocarbon thin film is not formed well.

When the high dielectric hydrocarbon thin film of the present invention was manufactured, the properties of the thin film produced were changed according to the temperature. Graphene is formed at a high temperature, and as the temperature is lowered, nano graphite containing nano graphene crystals is formed in the amorphous hydrocarbon thin film, and when the thin film manufacturing temperature is further lowered, the high dielectric hydrocarbon thin film of the present invention is formed. When the temperature was lower than that, a low-k hydrocarbon thin film was formed. In the following examples, the high dielectric properties of the hydrocarbon thin film prepared at 200° C. to 600° C. are shown, but since it may vary depending on the equipment and reaction conditions used at the reaction temperature, it is meaningless to limit the value to a specific value. Conditions that may affect the reaction temperature include a volume ratio of hydrocarbon gas and hydrogen gas, reaction pressure, and plasma intensity.

The pressure in the reactor is preferably 0.5 Torr to 5 Torr so that plasma discharge can be smoothly performed. When the pressure is too high, it is difficult to maintain the plasma, so that the hydrocarbon thin film deposition efficiency is lowered, and when the pressure is too low, the process efficiency is lowered.

The present invention also relates to a high dielectric hydrocarbon thin film produced by the method. The thickness of the high dielectric hydrocarbon thin film produced by the method of the present invention can be easily controlled by adjusting the reaction time under the corresponding conditions. The high dielectric hydrocarbon thin film prepared by the thin film of the present invention has a smooth surface structure without pinholes.

The high dielectric hydrocarbon thin film manufactured by the method of the present invention has a dielectric constant of 20 or more, and in one embodiment below, it exhibits a very high dielectric characteristic of 90, so it is expected to be usefully applied to semiconductors having a node of 10 nm or less. do. In particular, in addition to very high dielectric properties, when the equivalent oxide film thickness is 0.2 nm, the leakage current at 1 V is 0.25 A/cm 2 or less, and the insulation strength is 5 MV/cm or more, HfO ₂ , ZrO ₂ , known as a conventional high-k oxide, It goes beyond the properties of Hf- or Zr-based oxides such as HfAlO _x , ZrAlO _x , etc.

Another embodiment of the present invention relates to a semiconductor device using the high dielectric hydrocarbon thin film. The high-k hydrocarbon thin film may be used as an ultra-thin insertion layer requiring a high-k dielectric in more detail. The semiconductor device of the present invention may be a memory device or a logic device.

According to the high dielectric hydrocarbon thin film manufactured by the method of the present invention, the dielectric constant is significantly higher than that of SiO ₂ as well as conventional Hf- or Zr-based oxides, but the leakage current is very low, and it shows high insulation strength characteristics at 10 nm node It can be more usefully used for the following semiconductors.

In addition, since the high dielectric hydrocarbon thin film of the present invention does not require a catalyst layer, it can be deposited directly on a required substrate without requiring a transfer process, thereby improving the performance of a semiconductor device due to excellent interfacial properties.

1 shows a schematic diagram and a TEM image of a thin film produced according to the deposition temperature.
2 shows a Raman spectrum and an EELS spectrum of a thin film produced according to a deposition temperature.
3 shows an XPS spectrum and an EXAFS spectrum of a thin film prepared at 400°C.
4 is a schematic diagram of a semiconductor-high dielectric hydrocarbon thin film-metal (MIS) according to an embodiment of the present invention.
5 is a graph showing the electrical characteristics of the high dielectric hydrocarbon thin film prepared according to an embodiment of the present invention.
6 is a cross-sectional view illustrating a semiconductor structure using a high dielectric hydrocarbon thin film.
7 is a diagram illustrating a Fermi level of the semiconductor structure of FIG. 6 .
8 is a cross-sectional view illustrating a semiconductor device according to an embodiment of the present invention using a high dielectric hydrocarbon thin film.
9 is a cross-sectional view illustrating a semiconductor device according to an embodiment of the present invention using a high dielectric hydrocarbon thin film.
10 is a cross-sectional view illustrating a semiconductor device according to an embodiment of the present invention using a high dielectric hydrocarbon thin film.

Hereinafter, the present invention will be described in more detail with reference to the accompanying examples. However, these embodiments are merely examples for easily explaining the content and scope of the technical idea of the present invention, and thereby the technical scope of the present invention is not limited or changed. It will be natural for those skilled in the art that various modifications and changes can be made within the scope of the technical spirit of the present invention based on these examples.

Example 1: Preparation of hydrocarbon thin film

A hydrocarbon thin film was deposited on a Si wafer or Si/SiO ₂ /Ag substrate by inductively-coupled plasma chemical vapor deposition (ICP-CVD) using CH ₄ gas and hydrogen gas under the following conditions. Specifically, 1 sccm of CH ₄ gas and 100 sccm of hydrogen and Ar mixed gas (10% hydrogen) were injected into the reactor, and the pressure was fixed at 1 Torr and the plasma power was set at 600 W. The deposition time was varied from 30 seconds to 1 hour.

Example 2: Evaluation of properties of hydrocarbon thin films according to deposition temperature

The hydrocarbon thin film formed according to the deposition temperature was confirmed with an aberration-corrected transmission electron microscope (Aberration-corrected TEM, Titan G2 Cube 60-300kV, FEI), and the results are shown in FIG. 1 . 1B is a TEM image of a thin film deposited at 950° C., showing that carbon atoms have a highly ordered hexagonal arrangement. The inner figure shows a fast Fourier transformed (FFT) digital diffractogram and shows a hexagonal pattern, which is a typical characteristic of high-quality graphene. In the Raman spectrum of FIG. 2 a, I2D/IG showed a high value of about 3, and the maximum half-width of the 2D peak was small as 32 cm ^-1 , confirming that high-quality graphene was formed.

When the deposition temperature was lowered to 700° C., the resulting thin film exhibited a nano graphite morphology (see FIG. 1 c ) in which hexagonal lattice nanocrystals were partially present in an amorphous matrix. FFT shows a diffused ring morphology with dark spots (indicated by circles). The spacing between the dots is 0.246 nm, which corresponds to carbon allotrope hexagonite. When the deposition temperature was further lowered to 400 °C or 50 °C, the thin film lost nanocrystallinity, exhibited an amorphous structure, and showed a halo FFT pattern (see Fig. 1 d and e). The Raman spectrum shown in a of FIG. 2 also showed a typical aspect of the amorphous carbon structure.

2 b and c are electron energy-loss spectroscopy (EELS) spectra of a low-loss region and a carbon K-edge region, respectively, and the bonding pattern of the hydrocarbon thin film according to the deposition temperature can be confirmed. In FIG. 2 b, graphene showed two characteristic peaks. The strong peak at 5 eV is a π plasmon peak related to the π→π* transition by sp2 bonding of carbon, and the broad peak around 15.5 eV is (π +σ) is a plasmon peak. The position of the (π+σ) plasmon peak is proportional to the density of valence electrons, that is, the mass density of the carbon thin film. When the deposition temperature was lowered to 700 °C, the intensity of the π plasmon peak significantly decreased, which was consistent with the TEM image showing the presence of nanocrystalline hexagonite with sp2 bonds in the amorphous matrix. Only (π+σ) plasmon peaks were observed in the thin films prepared at 400°C and 50°C. In the thin films prepared at 50 ° C, 400 ° C, and 700 ° C, the (π + σ) plasmon peak energies are 25.0 eV, 24.5 eV, and 25.8 eV, respectively, which is about 5 eV lower than that of the carbon thin film containing a large amount of sp3 bonds, It was suggested that the proportion of sp3 binding would be small. The relatively large value of energy in the thin film prepared at 700° C. is interpreted because it contains a dense crystalline state.

The presence of π bonds in the thin film can also be confirmed in the EELS spectrum of the carbon K-edge region shown in FIG. 2c . The first peak is observed at 281 eV in the thin films prepared at 50 °C and 400 °C, which corresponds to a transition (1s→π* transition) from the 1s state to the π* state above the Fermi level. From the strong peak observed in the corresponding region, it can be confirmed that a significant amount of sp2 bonds exist in the amorphous thin film. The second peak was observed very broadly in the region of 290 eV to 305 eV, which corresponds to the 1s→σ* transition. When the deposition temperature was increased to 700°C, the first peak was observed up to 289.5 eV, indicating that the energy band was narrowed by nanocrystallization. This peak was observed more clearly in graphene prepared at 950 °C. According to the EELS spectrum, the thin films prepared at 50°C and 400°C were similar to the previously reported amorphous hydrocarbons. The EELS spectrum of graphene oxide showed a different aspect from that of hydrocarbons.

The chemical bonding properties of the hydrocarbon thin film prepared at 400° C. were confirmed by X-ray photoelectron spectroscopy (XPS) and extended X-ray absorption fine structure (EXAFS). 3a is the XPS spectrum, 285.3 eV corresponding to the aliphatic hydrocarbon C _x H _y is observed, and the position of the corresponding peak does not change as the etching is performed using Ar ⁺ plasma, so it can be confirmed that the composition of the hydrocarbon thin film is uniform. . Although not shown, in the XPS spectrum of the graphene thin film, the peak position shifted from 285.0 eV to 284.4 eV according to the etching of the surface. The graphene surface exposed to air can adsorb various types of hydrocarbons, resulting in a high binding energy of 285.0 eV. When the hydrocarbons on the surface are removed by etching, graphene itself shows the binding energy of 284.4 eV.

3b is an EXAFS spectrum at the 1s core level, and c is an EXAFS spectrum near the Fermi level. The strong peak of 285.1 eV in FIG. 2 b corresponds to the 285.3 eV peak of the XPS spectrum. In order to confirm that a significant amount of hydrogen is contained in the hydrocarbon thin film, the thin film was prepared and then heat-treated at 700° C. in-situ.

After the heat treatment, the position of the peak was redshifted to 284.7 eV, indicating that hydrogen was desorbed from the aliphatic hydrocarbon C _x H _y . As a result, the desorbed sample shows that the density of the expanded state increases and the intensity in the region near the Fermi level increases.

Example 3: Evaluation of electrical properties of hydrocarbon thin films

An MIS device having the structure of FIG. 4 using the hydrocarbon thin film according to the present invention as a dielectric layer was manufactured, and the electrical properties of the hydrocarbon thin film were evaluated.

The hydrocarbon thin film was directly grown on a substrate or transferred to prepare an MIS device. More specifically, in order to grow directly on the Si wafer, the Si wafer was immersed in a 10% hydrofluoric acid solution to remove the native oxide film and then washed. After the cleaned substrate was introduced into the ICP-CVD reactor, a hydrocarbon thin film was deposited at 200° C., 250° C., 300° C., 350° C. and 400° C. for 30 minutes, respectively, according to the conditions described in Example 1. For the transfer of the hydrocarbon thin film, the Si/SiO2/Ag substrate was introduced into the ICP-CVD reactor, and then the hydrocarbon thin film was deposited for 5 minutes under the same conditions as for direct growth. After spin coating of PMMA on the deposited hydrocarbon thin film, the Ag catalyst layer was etched by immersion in FeCl ₃ aqueous solution to separate the hydrocarbon/PMMA film. The separated hydrocarbon/PMMA film was transferred onto a Si wafer and then immersed in acetone to remove PMMA.

As described above, an MIS device was manufactured by forming an Au electrode having a diameter of 100 μm on a hydrocarbon thin film directly grown or transferred on a Si wafer.

The thickness of the hydrocarbon thin film measured from cross-sectional TEM and AFM (Asylum Research, MFP-3D) in this MIS device was 2.6 nm, 2.4 nm, and 3.1 nm at growth temperatures of 200°C, 250°C, 300°C, 350°C, and 400°C, respectively. , 5.0 nm and 6.5 nm. AFM images of hydrocarbons grown on the Si wafer itself without the Ag catalyst layer showed a uniform, pinhole-free, smooth surface. The rms roughness of the hydrocarbon thin film prepared by each method was 3.06 nm and 1.61 nm, respectively.

5 is a graph showing electrical characteristics measured for the manufactured MIS device. 5A is a C-V curve of a hydrocarbon thin film directly grown on a Si wafer, where ■ is a value measured from -4V to +4V, and □ is a value measured from +4V to -4V. An important characteristic of the C-V curve is that the hysteresis in the C-V loop for all samples is close to zero with less than 5 mV, which meets the criteria for high-k gate dielectrics (about 30 mV or less). The rapid transition from accumulation and depletion and a very small hysteresis value mean that the thin film and the charge density trapped at the Si interface between the thin film and the thin film are very small. In comparison, the hydrocarbon thin film transferred to Si exhibited significant hysteresis, and the transition from accumulation and depletion was relatively slow. This is estimated to be due to deterioration of the interface properties during the transfer process and contamination during the etching process of the Ag catalyst thin film during transfer. As can be seen from the inner drawing of FIG. 5A , the flat band voltage of the hydrocarbon thin film slightly shifted toward the -voltage due to the fixed positive charge, whereas the C-V curve showed an ideal shape. The difference in the flat band voltage between the samples was not large, and all of them were in the range of -0.3V to 0.4V.

The dielectric constant (k) of the hydrocarbon thin film can be calculated from the following equation.

C=E/T: where C is the integrated capacitance, E is the dielectric constant of the hydrocarbon thin film, and T is the thickness of the hydrocarbon thin film.

5B is a graph showing the dielectric constant of a thin film prepared at each temperature. The dielectric constant of a hydrocarbon thin film grown directly on a Si wafer is up to 90, and the dielectric constant of Hf- and Zr-based oxides known as high-k gate oxides. It was better than the constant 20 to 30. As the thin film growth temperature increased, the dielectric constant gradually increased and showed a maximum of 90 at 350°C, and when the temperature was further increased to 400°C, the dielectric constant decreased to 13. The hydrocarbon thin film transferred on the Si wafer has similar tendencies to the direct grown hydrocarbon thin film and the thin film growth temperature. As the deposition temperature increased, the dielectric constant also gradually increased, reaching a maximum of 61 at 500 ° C. It increased and decreased again when it reached 600°C. This is because in the hydrocarbon thin film deposited at a low temperature, disordered dipole moments cancel each other out, resulting in a relatively low k value, and as the temperature increases, the structuring of the carbon skeleton structure increases and the dipole moment also increases. It can be seen that When the critical temperature is higher than the critical temperature, hydrogen and hydrocarbons are difficult to be trapped in the dangling bond, resulting in the breakdown of the hydrocarbon structure and loss of properties as a high-k dielectric.

One of the important characteristics of a high-k dielectric is that the leakage current density should be low and the insulation strength should be high. 5c is an I-V curve, and the thin films prepared at 300° C. and 350° C. with dielectric constants of 82 and 90, respectively, had a leakage current of 0.15 A/cm 2 at 1 V for equivalent oxide thicknesses of 0.15 nm and 0.2 nm. The leakage current showed the lowest value in the thin film deposited at 400°C, and the thickness was about 6.5 nm, the thickest among the thin films. All the samples did not show breakdown up to 5V, so it was found that the dielectric strength had a high value of at least 10MV/cm or more. Such leakage current and dielectric strength are at least equal to or superior to those of conventional high-k oxides.

6 is a cross-sectional view illustrating a semiconductor structure using a high dielectric hydrocarbon thin film, and FIG. 7 is a view illustrating a Fermi level of the semiconductor structure of FIG. 6 .

6 and 7 together, a semiconductor structure including a semiconductor material layer 160M, a metal material layer 170M, and an ultra-thin insertion layer 180 is shown.

In a semiconductor device to be described later, in a semiconductor structure such as a contact structure, the ultra-thin insertion layer 180 is disposed at the interface between the semiconductor material layer 160M and the metal material layer 170M.

Due to the unavoidable Fermi level fixing phenomenon at the interface between the semiconductor material layer 160M and the metal material layer 170M, the effective metal work function Φ is fixed at a level different from that of the ideal vacuum work function, so that the non-ideal Schottky There is a problem in that a barrier (Schottky barrier) is formed. This has a problem in that electron injection efficiency is reduced at the interface between the semiconductor material layer 160M and the metal material layer 170M, and thus the performance of the device is deteriorated.

In the technical idea of the present invention, the ultra-thin insertion layer 180 is conformally formed at the interface between the semiconductor material layer 160M and the metal material layer 170M, and the Fermi level fixing phenomenon is eliminated, thereby providing ideal and efficient electron injection efficiency. can be achieved

The ultra-thin insertion layer 180 may be formed to have an atomic layer thickness, and may be formed using the high dielectric hydrocarbon thin film described above. That is, the ultra-thin insertion layer 180 may have low leakage current density and high insulation strength.

Although the ultra-thin insertion layer 180 is formed of an insulating material or an atomic layer thickness, it has been confirmed by the inventors that electrical connection is possible due to electron movement due to a tunneling phenomenon.

In addition, the ultra-thin insertion layer 180 may serve to heal the dangling bonds DB included in the semiconductor material layer 160M.

8 is a cross-sectional view illustrating a semiconductor device according to an embodiment of the present invention using a high dielectric hydrocarbon thin film.

Referring to FIG. 8 , a semiconductor device including a substrate 110 , a device isolation layer 120 , a gate structure GS, a source/drain region 160 , a contact structure 170 , and an ultra-thin insertion layer 180 ( 10) is provided.

The substrate 110 may be a semiconductor substrate. In some embodiments, the substrate 110 may include a semiconductor such as silicon (Si) or germanium (Ge), or a compound semiconductor such as SiGe, SiC, GaAs, InAs, InP, etc. . In other embodiments, the substrate 110 may have a silicon on insulator (SOI) structure.

The device isolation layer 120 may be formed of a single insulating layer, or may include an external insulating layer and an internal insulating layer. The outer insulating layer and the inner insulating layer may be formed of different materials. For example, the outer insulating film may be formed of an oxide film, and the inner insulating film may be formed of a nitride film. However, the configuration of the device isolation layer 120 is not limited thereto. Due to the device isolation layer 120 , an active region may be defined in the substrate 110 .

The gate structure GS may include a gate dielectric layer 130 , a gate electrode 140 , and a spacer 150 .

The gate dielectric layer 130 may be formed of a low-k material layer or a high-k material layer. The gate dielectric layer 130 may be made of, for example, a material selected from a silicon oxide layer, a silicon oxynitride layer, a hafnium oxide layer, a zirconium oxide layer, a tantalum oxide layer, and a titanium oxide layer, but is not limited thereto.

The gate electrode 140 may be formed of a single gate layer or may be formed of multiple layers. In some embodiments, the gate electrode 140 may include at least one material selected from a semiconductor doped with an impurity, a metal, a conductive metal nitride, and a metal silicide.

Spacers 150 may be formed on sidewalls of the gate dielectric layer 130 and the gate electrode 140 . The spacer 150 may be formed of at least one of silicon oxide, silicon nitride, and silicon oxynitride. In this embodiment, although the case where the spacer 150 is formed of a single layer is illustrated, the technical spirit of the present invention is not limited thereto, and the spacer 150 may be formed of a double layer or a triple layer.

The source/drain regions 160 are formed in the substrate 110 on both sides of the gate structure GS, and a channel region interposed between the source/drain regions 160 is defined under the gate structure GS. do.

The contact structure 170 may be electrically connected to the source/drain region 160 . In some embodiments, the contact structure 170 may be referred to as a source/drain contact. The contact structure 170 may be formed of one selected from a conductive metal layer, a metal nitride layer, a metal oxide layer, a metal oxynitride layer, and a polysilicon layer doped with impurities.

The ultra-thin insertion layer 180 may be formed using the high dielectric hydrocarbon thin film described above. That is, the ultra-thin insertion layer 180 may have low leakage current density and high insulation strength. Although the ultra-thin insertion layer 180 is an insulating material, as its thickness is formed to the thickness of an atomic layer, electrons may move due to a tunneling phenomenon, so that the source/drain region 160 and the contact structure 170 are electrically connected to each other. make the connection possible.

9 is a cross-sectional view illustrating a semiconductor device according to an embodiment of the present invention using a high dielectric hydrocarbon thin film.

Referring to FIG. 9 , a substrate 110 including a fin-type active region AR, a device isolation layer 120 , a source/drain region 160 , a contact structure 170 , and an ultra-thin film insertion layer 180 . A semiconductor device 20 is provided.

Materials constituting the substrate 110 and the device isolation layer 120 may be substantially the same as those described above with reference to FIG. 8 . However, it may include a plurality of fin-type active regions AR protruding from the substrate 110 and extending in the first direction. The device isolation layer 120 may expose an upper region of the fin-type active region AR.

Source/drain regions 160 may be respectively interposed on the fin-type active region AR on both sides of the gate structure (not shown). The source/drain regions 160 may be spaced apart from each other with the gate structure therebetween. The source/drain region 160 may be a selective epitaxial growth layer formed by using the fin-type active region AR as a seed.

A material constituting the contact structure 170 may be substantially the same as described above with reference to FIG. 8 . The contact structure 170 may contact the plurality of source/drain regions 160 .

The ultra-thin insertion layer 180 may be formed using the high dielectric hydrocarbon thin film described above. That is, the ultra-thin insertion layer 180 may have low leakage current density and high insulation strength. Although the ultra-thin insertion layer 180 is an insulating material, as its thickness is formed to the thickness of an atomic layer, electrons may move due to a tunneling phenomenon, so that the source/drain region 160 and the contact structure 170 are electrically connected to each other. make the connection possible.

10 is a cross-sectional view illustrating a semiconductor device according to an embodiment of the present invention using a high dielectric hydrocarbon thin film.

Referring to FIG. 10 , a gate electrode 140 including a substrate 110 including a fin-type active region, an isolation layer 120 , a gate dielectric layer 130 , a main gate electrode 140M and a sub-gate electrode 140S. , a spacer 150 , a contact structure 170 , and a semiconductor device 30 including an ultra-thin insertion layer 180 is provided.

Materials constituting the substrate 110 and the device isolation layer 120 may be substantially the same as those described above with reference to FIG. 8 . However, it may include a plurality of fin-type active regions protruding from the substrate 110 and extending in the first direction. The device isolation layer 120 may expose an upper region of the fin-type active region.

The plurality of semiconductor patterns NS may be disposed to be spaced apart from the top surface of the substrate 110 in a vertical direction on the fin-type active region.

The plurality of semiconductor patterns NS may have a shape of, for example, a nanosheet.

The gate electrode 140 surrounds the plurality of semiconductor patterns NS and may extend on the fin-type active region and the device isolation layer 120 . The gate electrode 140 may include a main gate electrode 140M and a plurality of sub-gate electrodes 140S.

The gate dielectric layer 130 may be disposed between the gate electrode 140 and the plurality of semiconductor patterns NS. The gate dielectric layer 130 may be conformally disposed on top surfaces and sidewalls of the plurality of semiconductor patterns NS. A material constituting the gate dielectric layer 130 may be substantially the same as described above with reference to FIG. 8 .

The source/drain region 160 may be a selective epitaxial growth layer formed using the fin-type active region as a seed.

A material constituting the contact structure 170 may be substantially the same as described above with reference to FIG. 8 . The contact structure 170 may contact the plurality of source/drain regions 160 .

The ultra-thin insertion layer 180 may be formed using the high dielectric hydrocarbon thin film described above. That is, the ultra-thin insertion layer 180 may have low leakage current density and high insulation strength. Although the ultra-thin insertion layer 180 is an insulating material, as its thickness is formed to the thickness of an atomic layer, electrons may move due to a tunneling phenomenon, so that the source/drain region 160 and the contact structure 170 are electrically connected to each other. make the connection possible.

In the above, embodiments of the technical idea of the present invention have been described with reference to the accompanying drawings, but those of ordinary skill in the art to which the present invention pertains will realize that the present invention has other specific shapes without changing the technical spirit or essential features. It will be appreciated that this may be practiced. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10, 20, 30: semiconductor device
110: substrate 120: device isolation film
130: gate dielectric film 140: gate electrode
150: spacer 160: source/drain region
170: contact structure 180: ultra-thin insert layer

Claims (10)

delete delete semiconductor material layer;
metal material layer; and
and an ultra-thin insertion layer formed at an interface between the semiconductor material layer and the metal material layer;
The ultra-thin insert layer,
positioning a substrate in a plasma reactor;
injecting hydrocarbon gas and hydrogen gas together into the plasma reactor;
Setting the temperature in the plasma reactor to 200 °C to 600 °C, and the pressure to 0.5 Torr to 5 Torr; and
Including; generating plasma in the plasma reactor to form a high dielectric hydrocarbon thin film on the substrate;
The high dielectric hydrocarbon thin film has an amorphous structure and includes a high dielectric hydrocarbon thin film manufactured by a method of controlling the temperature in the plasma reactor so that the dielectric constant is 20 or more,
The ultra-thin intercalation layer suppresses dangling bonds of the semiconductor material layer. 4. The method of claim 3,
The ultra-thin insert layer,
and preventing a Fermi level pinning phenomenon between the semiconductor material layer and the metal material layer. delete a substrate defining an active area;
a gate dielectric layer disposed on the active region;
a gate electrode disposed on the gate dielectric layer;
source/drain regions disposed in the active region on both sides of the gate electrode;
a contact structure electrically connected to the source/drain region; and
and an ultra-thin insertion layer formed at an interface between the source/drain region and the contact structure
The ultra-thin insert layer,
positioning a substrate in a plasma reactor;
injecting hydrocarbon gas and hydrogen gas together into the plasma reactor;
Setting the temperature in the plasma reactor to 200 °C to 600 °C, and the pressure to 0.5 Torr to 5 Torr; and
Including; generating plasma in the plasma reactor to form a high dielectric hydrocarbon thin film on the substrate;
The high dielectric hydrocarbon thin film has an amorphous structure and includes a high dielectric hydrocarbon thin film manufactured by a method of controlling the temperature in the plasma reactor so that the dielectric constant is 20 or more,
The ultra-thin insertion layer suppresses dangling bonds of materials constituting the source/drain regions. a fin-type active region extending in a first direction on the substrate;
a gate structure extending in a second direction crossing the fin-type active region on the substrate;
source/drain regions disposed on both sides of the gate structure;
a contact structure electrically connected to the source/drain region; and
and an ultra-thin insertion layer formed at an interface between the source/drain region and the contact structure
The ultra-thin insert layer,
positioning a substrate in a plasma reactor;
injecting hydrocarbon gas and hydrogen gas together into the plasma reactor;
Setting the temperature in the plasma reactor to 200 °C to 600 °C, and the pressure to 0.5 Torr to 5 Torr; and
Including; generating plasma in the plasma reactor to form a high dielectric hydrocarbon thin film on the substrate;
The high dielectric hydrocarbon thin film has an amorphous structure and includes a high dielectric hydrocarbon thin film manufactured by a method of controlling the temperature in the plasma reactor so that the dielectric constant is 20 or more,
The ultra-thin insertion layer suppresses dangling bonds of materials constituting the source/drain regions. a fin-type active region protruding from the substrate and extending in a first direction;
a plurality of semiconductor patterns spaced apart from each other from an upper surface of the fin-type active region and having a channel region;
Between the plurality of semiconductor patterns and a main gate electrode that surrounds the plurality of semiconductor patterns and extends in a second direction perpendicular to the first direction, is disposed on top of the plurality of semiconductor patterns and extends in the second direction a gate electrode including a sub-gate electrode disposed on;
a gate dielectric layer disposed between the gate electrode and the plurality of semiconductor patterns;
spacers disposed on both sidewalls of the main gate electrode; and
a source/drain region disposed on both sides of the gate electrode, connected to the plurality of semiconductor patterns, and in contact with a lower surface of the spacer;
a contact structure electrically connected to the source/drain region; and
and an ultra-thin insertion layer formed at an interface between the source/drain region and the contact structure
The ultra-thin insert layer,
positioning a substrate in a plasma reactor;
injecting hydrocarbon gas and hydrogen gas together into the plasma reactor;
Setting the temperature in the plasma reactor to 200 °C to 600 °C, and the pressure to 0.5 Torr to 5 Torr; and
Including; generating plasma in the plasma reactor to form a high dielectric hydrocarbon thin film on the substrate;
The high dielectric hydrocarbon thin film has an amorphous structure and includes a high dielectric hydrocarbon thin film manufactured by a method of controlling the temperature in the plasma reactor so that the dielectric constant is 20 or more,
The ultra-thin insertion layer suppresses dangling bonds of materials constituting the source/drain regions. 9. The method according to any one of claims 6 to 8,
The ultra-thin insert layer,
and preventing a Fermi level fixation phenomenon between a material constituting the source/drain region and a material constituting the contact structure. delete

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