KR102566964B1 - Method for fabricating β-Ga2O3 thin film - Google Patents

Abstract

The present invention relates to a method for manufacturing a beta gallium oxide thin film, and the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention includes the steps of transferring liquid gallium in the form of droplets on a substrate, and transferring the transferred gallium to a compression plate. Forming a gallium oxide layer in the form of a two-dimensional thin film by compressing liquid gallium, and forming a beta gallium oxide layer in the form of a two-dimensional thin film by heat-treating the gallium oxide layer.

Description

Beta gallium oxide thin film manufacturing method {Method for fabricating β-Ga2O3 thin film}

The present invention relates to a method for manufacturing a beta gallium oxide thin film, and more particularly, to a method for manufacturing a beta gallium oxide thin film using liquid gallium.

Recently, as the degree of integration of semiconductors increases and the size of devices gradually decreases, problems such as leakage current, channel length modulation, and high-temperature carrier effect occur, and limitations of silicon semiconductor devices appear. In addition, in the field of semiconductors used in environments with high withstand voltage, high current, high temperature, and high frequency, new semiconductor materials are attracting attention as these problems due to miniaturization are very important. In order to implement a semiconductor device having high power and high frequency characteristics, a semiconductor material having a high breakdown voltage and high electron mobility is required. In this regard, SiC, GaN, Ga ₂ O ₃ and the like are suitable. Among them, Ga ₂ O ₃ is a material having a relatively wider energy bandgap than SiC and GaN, and since it is possible to manufacture a single crystal substrate through melt growth, research and development have been actively conducted recently.

Ga ₂ O ₃ may exist in various phases, but the β phase is most suitable for device applications because it is physically and chemically stable. β-Ga ₂ O ₃ has high mechanical and chemical stability and has an energy band gap of 4.9 eV, making it useful as a high-voltage, low-loss power semiconductor material, and has a breakdown strength of 8 MV/cm, three times greater than SiC and GaN. As an oxide semiconductor with a , it is attracting attention in the power semiconductor market. In addition, due to such characteristics, β-Ga ₂ O ₃ can be applied to semiconductor lasers, field effect transistors, switching memories, and high-temperature gas sensors, and has high optical transmittance in the UV and visible light regions, so it is also used for manufacturing solar-blind UV photodetectors. It can be.

As disclosed in non-patent documents of prior art documents, conventional β-Ga ₂ O ₃ Methods for producing thin films include RF-sputtering deposition, MBE growth, MOCVD growth, and sol-gel process. However, conventional β-Ga ₂ O ₃ According to the thin film manufacturing methods, there are problems in that the substrate on which the thin film can be grown is limited, a high vacuum process and a post-process are essential, and the unit cost of growth is high.

Therefore, large-area β-Ga ₂ O ₃ with low growth unit cost There is an urgent need for a technology capable of producing thin films.

"Characteristics of Beta-Ga2O3 thin film fabricated by thermal oxidation of FS-GaN" Journal of the Institute of Electrical and Electronic Materials, Vol. 30, No. 7 (2017.07)

The present invention is to solve the problems of the prior art described above, and one aspect of the present invention is to transfer and compress liquid gallium in the form of droplets on a substrate to create a 2D gallium oxide layer, and to the gallium oxide layer It is an object of the present invention to provide a method for manufacturing a beta gallium oxide thin film by forming a 2D beta gallium oxide layer through heat treatment for a beta gallium oxide thin film.

Another aspect of the present invention is to provide a beta gallium oxide thin film manufacturing method for manufacturing a beta gallium oxide thin film having a multilayer structure by repeatedly performing the transfer, compression, and heat treatment processes on the formed beta gallium oxide layer.

A method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention includes the steps of (a) transferring liquid gallium in the form of droplets on a substrate; (b) forming a gallium oxide layer in the form of a two-dimensional thin film by compressing the transferred liquid gallium with a compression plate; and (c) forming a beta gallium oxide layer in the form of a two-dimensional thin film by heat-treating the gallium oxide layer.

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, the step (a) includes dropping the liquid gallium in the form of droplets on the substrate using a micro pipet; can include

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, the step (a) may include disposing the substrate on a hot plate heated to 30° C. or higher; and dropping the liquid gallium on the substrate.

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, in the step (b), the liquid gallium may be compressed with a compression force of 0.5 to 50 N.

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, in the step (b), the compressed plate may be removed while being spaced apart in a direction perpendicular to the upper surface of the gallium oxide layer. there is.

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, in the step (c), heat treatment may be performed at a temperature of 500 to 1000 ° C.

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, by the amount of the liquid gallium transferred in step (a) and the compression force for compressing the liquid gallium in step (b), The thickness and area of the beta gallium oxide thin film can be controlled.

In addition, in the method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention, after the step (c), on the beta gallium oxide layer generated in the step (c), the liquid phase according to the step (a) The transfer step, the step of forming a gallium oxide layer according to step (b), and the step of forming a beta gallium oxide layer according to step (c) are sequentially additionally performed n (n≥1, natural number) times, n+1 (n≥1, natural number) number of the beta gallium oxide layers may be stacked on.

Features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

Prior to this, the terms or words used in this specification and claims should not be interpreted in a conventional and dictionary sense, and the inventor may appropriately define the concept of the term in order to explain his or her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

According to the present invention, by heat-treating a 2D gallium oxide layer generated by transferring and compressing liquid gallium in the form of droplets on a substrate to prepare a 2D beta gallium oxide thin film, the thickness of the thin film can be reduced to nanometers depending on the amount of liquid gallium and compression strength. to micron size, and the area of the thin film can also be controlled.

In addition, conventional beta gallium oxide Since the vacuum process of the thin film manufacturing method (in particular, the epitaxial growth method) is not required, a continuous process is possible to manufacture beta gallium oxide thin films in large quantities, and lattice mismatch due to the use of oxidation of the liquid gallium layer applied to the substrate effect can be reduced, so the degree of freedom of the growth substrate is high.

As a result, when the crystalline beta gallium oxide thin film is directly grown on an arbitrary substrate through the present invention, process time and cost are reduced, and it is easy to manufacture beta gallium oxide-based optical and electronic devices optimized through thin film thickness and area control. can do

1 and 2 are flowcharts of a method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention.
3 is a flowchart of a method for manufacturing a beta gallium oxide thin film according to another embodiment of the present invention.
Figure 4a is a flow chart of a method for manufacturing a beta gallium oxide thin film according to an experimental example, Figure 4b is a microscope image of the gallium oxide thin film before heat treatment, Figure 4c is a height profile of the gallium oxide thin film measured by an atomic force microscope (AFM) profile), and FIG. 4d is an atomic ratio analysis result of a gallium oxide thin film using x-ray photoelectron spectroscopy (XPS).
FIG. 5a is a Raman spectrum of a gallium oxide thin film before heat treatment (as-fabricated) and heat-treated at various temperatures according to an experimental example, FIG. 5b is an x-ray diffraction pattern (XRD) spectrum, and FIG. 5c is The peak intensity according to the heat treatment temperature of the _Ag ³ and _Ag ⁵ phonon modes associated with the liberation and translation of tetrahedral-octahedra chain and the in-plane Ga ₂ O ₆ octahedra related optical mode, 5d is the average crystallite size according to the heat treatment temperature.
Figure 6 shows the characteristics of a 2D beta gallium oxide thin film formed by heat treatment at 900 ° C according to an experimental example, Figure 6a shows the components of the beta gallium oxide thin film calculated from XPS (x-ray photoelectron spectroscopy) data, 6b is a photoluminescence (PL) spectrum of the beta gallium oxide thin film, FIG. 6c is an absorbance spectrum of the beta gallium oxide thin film measured using UV-vis absorption spectroscopy, and FIG. 6d is 6e shows the VBM-core delta region and energy band structure of beta gallium oxide.
7a is an optical microscope image of a beta gallium oxide thin film grown on a graphene, quartz, Si (100), or sapphire substrate, and FIG. 7b is an optical microscope image of a beta gallium oxide thin film. It shows surface roughness (surface topography), Figure 7c is a Raman spectrum (raman spectra) of the beta gallium oxide thin film, Figure 7d shows the XRD (x-ray diffraction pattern) spectrum of the beta gallium oxide thin film.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments taken in conjunction with the accompanying drawings. In adding reference numerals to components of each drawing in this specification, it should be noted that the same components have the same numbers as much as possible, even if they are displayed on different drawings. In addition, terms such as “first” and “second” are used to distinguish one component from another component, and the components are not limited by the terms. Hereinafter, in describing the present invention, detailed descriptions of related known technologies that may unnecessarily obscure the subject matter of the present invention will be omitted.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are flowcharts of a method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, a method for manufacturing a beta gallium oxide thin film according to an embodiment of the present invention includes transferring liquid gallium in the form of droplets on a substrate, and liquid gallium transferred to a compression plate. and forming a gallium oxide layer in the form of a two-dimensional thin film by compressing, and heat-treating the gallium oxide layer to form a beta gallium oxide layer in the form of a two-dimensional thin film.

The present invention relates to a method for manufacturing a beta gallium oxide (β-Ga ₂ O ₃ ) thin film. In order to realize a semiconductor device with high power and high frequency characteristics, a semiconductor material with high breakdown voltage and high electron mobility is required. Among them, β-Ga ₂ O ₃ has high mechanical and chemical stability and has an energy band of 4.9 eV. As it has a gap, it is useful as a high-voltage, low-loss power semiconductor material, and an oxide semiconductor with a breakdown strength of 8 MV/cm, three times greater than SiC and GaN. It can be applied to gas sensors, and has high optical transmittance in the UV and visible light regions, so it can be used for manufacturing solar-blind UV photodetectors, so it is attracting attention recently. However, conventional β-Ga ₂ O ₃ such as RF-sputtering deposition method, MBE growth method, MOCVD growth method, sol-gel process, etc. Thin film manufacturing methods have limited substrates on which thin films can be grown, require high vacuum processes and post-processes, and have high growth unit costs. β-Ga ₂ O ₃ Since commercialization of thin films is difficult, the present invention has been devised as a solution to this problem.

Specifically, the method for manufacturing beta gallium oxide according to an embodiment of the present invention includes a liquid gallium transfer step (S100), a gallium oxide layer forming step (S200), and a beta gallium oxide layer forming step (S300).

The liquid gallium transfer step (S100) is a process of dropping liquid gallium on a substrate. Here, the substrate may be made of SiO ₂ , Si, sapphire, quartz, Pt, graphene, GaAs, Cu, etc., but is not particularly limited. The substrate can be used after cleaning with acetone/IPA. Since the melting point of gallium (Ga) is as low as approximately 29°C, it can be made into a liquid phase by applying heat above its melting point. Here, liquid gallium is transferred onto the substrate. For example, liquid gallium may be dropped onto the substrate after placing the substrate on a hot-plate heated above the melting point of gallium, that is, 30° C. or higher. At this time, the transferred liquid gallium does not spread on the substrate and maintains a droplet form. In addition, the liquid gallium may be dropped on the substrate in the form of droplets using a micro pipet. Since the amount of liquid gallium affects the thickness and area of the beta gallium oxide thin film, the thickness and area of the thin film can be adjusted according to the amount.

In the gallium oxide layer forming step (S200), liquid gallium in the form of transferred droplets is compressed. At this time, it may be compressed in a direction perpendicular to liquid gallium in the form of droplets using a compression plate. Here, it is appropriate to select a substrate having high flatness as the pressing plate. It is preferable that the flatness of at least one surface in close contact with liquid gallium is high.

The compression force, which is the force applied to the compression plate to compress the liquid gallium, may be 0.5 to 50 N. However, the range of compression force is not necessarily limited as described above, and since the thickness and area of the beta gallium oxide thin film are determined according to the compression force applied to liquid gallium, the range of compression force may be determined in consideration of this. As a result, the thickness of the beta gallium oxide thin film can be adjusted from several nm to several μm.

After pressing the liquid gallium in this way, by separating the pressing plate, a gallium oxide layer in the form of a thin film is formed. Here, liquid gallium is oxidized during compression, and eventually a gallium oxide layer in the form of a two-dimensional thin film is formed. On the other hand, when separating the compression plate, it is preferable to remove the gap in a direction perpendicular to the upper surface of the gallium oxide layer so that slip does not occur.

The beta gallium oxide layer forming step (S300) is a process of performing heat treatment on the gallium oxide layer. Here, a beta gallium oxide layer in the form of a two-dimensional thin film may be generated through heat treatment. The heat treatment is a process of making the gallium oxide layer into a β phase, and the phase and crystallinity of the gallium oxide layer can be adjusted according to the temperature and time of the heat treatment. This heat treatment may be performed under normal pressure and in air. Here, the heat treatment temperature is suitable for 500 ~ 1000 ℃. For example, a beta gallium oxide layer can be created by performing heat treatment at 750° C. or higher for 30 minutes in the air. As the beta gallium oxide layer generated through this heat treatment process, a beta gallium oxide thin film having a single-layer structure is formed.

Overall, according to the present invention, according to the present invention, the 2D gallium oxide layer produced by transferring and compressing liquid gallium in the form of droplets on a substrate is heat-treated to prepare a 2D beta gallium oxide thin film, so that the amount of liquid gallium and compression strength According to this, the thickness of the thin film can be adjusted to nano or micro size, and the area of the thin film can also be adjusted. In addition, conventional beta gallium oxide Since the vacuum process of the thin film manufacturing method (in particular, the epitaxial growth method) is not required, a continuous process is possible to manufacture beta gallium oxide thin films in large quantities, and lattice mismatch due to the use of oxidation of the liquid gallium layer applied to the substrate effect can be reduced, so the degree of freedom of the growth substrate is high. As a result, when the crystalline beta gallium oxide thin film is directly grown on an arbitrary substrate through the present invention, process time and cost are reduced, and it is easy to manufacture beta gallium oxide-based optical and electronic devices optimized through thin film thickness and area control. can do

3 is a flowchart of a method for manufacturing a beta gallium oxide thin film according to another embodiment of the present invention.

Referring to FIG. 3, a method for manufacturing a beta gallium oxide thin film according to another embodiment of the present invention is to form a multi-layered gallium oxide thin film, and through the heat treatment of the embodiment, a single-layer beta gallium oxide layer (hereinafter, a first After creating a beta gallium oxide layer), liquid gallium is transferred in the form of droplets onto the first beta gallium oxide layer and compressed to form a second gallium oxide layer, and heat treatment is performed again to form a second gallium oxide gallium oxide layer. layers can be formed.

That is, according to the above embodiment, the substrate/(beta gallium oxide layer) ₁ is prepared by forming a beta gallium oxide layer on the substrate, and a liquid gallium transfer step (S100) thereon, a gallium oxide layer forming step (S200), and By sequentially performing the beta gallium oxide layer forming step (S300) n (n is a natural number greater than or equal to 1) times, n+1 (n is a natural number greater than or equal to 1) of the beta gallium oxide layers are sequentially stacked on the substrate, thereby forming a multi-layered gallium oxide layer. A beta gallium oxide thin film substrate/(beta gallium oxide layer) _n+1 of the structure can be manufactured.

The band gap of a material tends to increase as its thickness decreases due to the quantum confinement effect. Accordingly, by manufacturing the multi-layered gallium oxide thin film and adjusting the thickness thereof, the band gap can be increased to be greater than or equal to the band gap of the bulk gallium gallium oxide.

Hereinafter, the present invention will be described in more detail through experimental examples.

1. Experimental Example

1.1 Preparation of beta gallium oxide thin film using a squeeze method

A substrate was placed on a hot plate at 75° C., and several mg of liquid gallium metal (99.9999% purity, GalliumLab) was dropped on the substrate using a micropipette. Then, the liquid gallium is compressed with a pressure plate with a flat surface perpendicularly to the substrate with a force of 20 to 50 N, and removed in a vertical direction so as not to cause slip on the pressure plate to obtain a sample of a two-dimensional gallium oxide film. has formed

Thereafter, the sample was subjected to heat treatment at 500 to 1000 °C for two hours using a tube furnace (Lindberg/Blue M) under atmospheric conditions. After heat treatment, the sample was immersed in ethanol at 65° C. and gently rubbed to remove residual gallium.

Here, the same experiment was conducted using graphene, quartz, sapphire, and Si substrates respectively.

1.2 Analysis method

The elemental composition of the gallium oxide thin film was analyzed using X-ray photoelectron spectroscopy (PHI 5000 VersaProbe, ULVAC PHI) with monochromatized Al Kα x-ray source. The optical properties of the beta gallium oxide thin film were examined using an optical microscope (BX51M, Olympus), UV-vis absorption spectroscope (Lambda 35, PerkinElmer), micro-Raman spectroscopy with 532 nm diode-pumped solid-state laser (Omicron) in a back-scattering geometry, and photoluminescence (PL) spectroscopy with 325 nm He-Cd laser (Kimmon Koha Co.) as an excitation source. The thickness and surface morphology of the beta gallium oxide thin film were analyzed using an atomic force microscope (AFM) in a tapping mode. The crystallinity of the beta gallium oxide thin film was analyzed by X-ray diffraction (XRD, D8 Discover, Bruker) with Cu-Kα radiation.

2. Experimental results

2.1 Fabrication of 2D beta gallium oxide thin film

Figure 4a is a flow chart of a method for manufacturing a beta gallium oxide thin film according to an experimental example, Figure 4b is a microscope image of the gallium oxide thin film before heat treatment, Figure 4c is a height profile of the gallium oxide thin film measured by an atomic force microscope (AFM) profile), and FIG. 4d is an atomic ratio analysis result of a gallium oxide thin film using x-ray photoelectron spectroscopy (XPS).

As shown in FIG. 4A, the beta gallium oxide thin film according to the experimental example is obtained through two steps, such as squeezing liquid gallium and thermal annealing. Metals with low melting points (Ga, In, Sn, etc.) easily undergo self-limiting oxidation by Cabrera-Mott kinetics in air. In addition, the strength of the metal becomes very weak at a temperature above the melting point, and these factors may enable the fabrication of a metal oxide having a thickness of nanometers through a liquid metal squeezing method. Several mg of gallium droplets were dropped on a substrate (with a flat surface) placed on a hot plate at 75° C., and then liquid gallium was compressed in a vertical direction using a compression plate having a flat surface. Thereafter, after removing the pressure plate in the vertical direction so as not to cause slip, it was observed that a homogeneous thin film having a millimeter scale was formed without cracks or aggregation (see FIG. 4B ). Its thickness was measured to be about 3 nm (see Fig. 4c). The liquid gallium was uniformly compressed with a force of 20 to 50 N, and a gallium oxide thin film with a thickness of 2 to 3.2 nm was formed in this range. In addition, the rms (root mean square) of the gallium oxide thin film was about 7.7 Å, and the rms of the SiO ₂ substrate was about 7.0 Å, which indicates that the roughness of the gallium oxide thin film formed through the compression method dominates the substrate to be compressed. show what is affected. Therefore, when the patterned substrate is used as a compression substrate, it is expected that the thickness or shape of the gallium oxide thin film can be controlled.

The atomic ratio of the gallium oxide thin film was analyzed using x-ray photoelectron spectroscopy (XPS) (see FIG. 4d). The stoichiometric _{ratio of the thin film calculated using the areas of the O 1s and Ga 2p 3/2 peaks} and the relative sensitivity factor was observed to be Ga : O = 1 : 0.6. It is a mixture of gallium (I) oxide and gallium (III) oxide due to incomplete oxidation or gallium (I) oxide (Ga ₂ O) when liquid gallium is oxidized in the air by natural oxidation. ) can be explained by the formation of As a result, due to the fast oxidation rate of Cabrera-Mott oxidation, liquid gallium in the air forms a uniform, large-area, nanometer-thick gallium oxide thin film during the compression process.

In order to obtain a beta gallium oxide thin film from the above nanometer-thick gallium oxide thin film, heat treatment was performed under atmospheric conditions.

FIG. 5a is a Raman spectrum of a gallium oxide thin film before heat treatment (as-fabricated) and heat-treated at various temperatures according to an experimental example, FIG. 5b is an x-ray diffraction pattern (XRD) spectrum, and FIG. 5c is The peak intensity according to the heat treatment temperature of the _Ag ³ and _Ag ⁵ phonon modes associated with the liberation and translation of tetrahedral-octahedra chain and the in-plane Ga ₂ O ₆ octahedra related optical mode, 5d is the average crystallite size according to the heat treatment temperature.

Figure 5a shows the Raman spectrum of the gallium oxide thin film sample before (as-fabricated) heat treatment and according to the heat treatment temperature, and the Raman signal was obtained in a relatively thick part due to a low scattering yield. No significant phonon mode was observed in the as-fabricated and heat-treated gallium oxide thin film at 500 to 650 °C. However, the phonon mode of beta-gallium oxide was observed in samples heat-treated at 700 °C or higher, which indicates that amorphous Ga 2 O 3 is replaced by β-phase gallium oxide (Ga ₂ O ₃ ) on the phase diagram. ₂ O ₃ ) at the same temperature. Referring to FIG. 5C, the intensities of both Raman modes started to increase after the heat treatment at 800 °C, had the highest value in the sample heat treated at 900 °C, and decreased again at a temperature of 950 °C or higher.

The result of the x-ray diffraction pattern (XRD) shown in FIG. 5b is also consistent with the result of the Raman analysis. No significant peak was observed in the sample heat treated up to 650℃, but diffraction peaks matching the pattern of beta gallium oxide (β-Ga ₂ O ₃ ) were observed in the sample heat treated at a temperature of 700℃ or higher. A peak associated with crystalline gallium oxide (Ga ₂ O ₃ ) was not observed. At all heat treatment temperatures above 800 °C, the most prominent peak was the (111) beta gallium oxide plane (β-Ga ₂ O ₃ plane), and other plane reflections were also observed. These Raman and XRD results show that single-phase monoclinic beta gallium oxide (monoclinic β-Ga ₂ O ₃ ) is formed by squeezing liquid gallium and subsequent annealing at 700 ° C or higher. show that it has been The average crystallite size of beta gallium oxide was calculated from the most prominent (111) orientation diffraction peak using Scherrer's equation below.

where D = average crystallite size, k = 0.9, λ = the wavelength of the x-ray radiation(=1.54056 Å), β = the full width at the half maximum in radians, θ = the Bragg angle of the considered diffraction peak am.

The average grain size of the sample heat-treated at 800 ° C. increased from 36.4 nm to 41.3 nm until heat treatment at 900 ° C., and then decreased at a temperature higher than that to 37.2 nm after heat treatment at 1000 ° C. (see FIG. 5d). The average grain size of beta gallium oxide grown at 900 °C was determined by spray pyrolysis, electron-beam evaporation, sol-gel, pulsed laser deposition, and sputtering. ) has a larger size than beta gallium oxide grown through At a relatively low temperature, a thin film with low crystallinity is formed because sufficient energy is not supplied to generate ad-atomic migration. When the temperature rises above 700 °C, the atoms on the surface gain sufficient kinetic energy and surface mobility, resulting in lattice reconstruction. In this process, a solid Ga-O bond is formed. ), the crystallinity is improved by the formation of However, at a high temperature of 950 ° C or higher, atomic migration occurs too quickly, and instead of forming a regular bond, the bond of β-Ga ₂ O ₃ is split to form a defect. start to become The decrease in the average grain size and the shift in the diffraction peak at 950 ° C or higher shown in FIG. 5d can be explained by lattice deformation due to the formation of such defects and the resulting strain. Therefore, the optimum temperature at which a 2D gallium oxide thin film obtained from liquid gallium is transformed into a 2D beta gallium oxide thin film was determined to be 900 ° C. is similar to the temperature of

2.2 Characteristics of 2D Beta Gallium Oxide Thin Film

Figure 6 shows the characteristics of a 2D beta gallium oxide thin film formed by heat treatment at 900 ° C according to an experimental example, Figure 6a shows the components of the beta gallium oxide thin film calculated from XPS (x-ray photoelectron spectroscopy) data, 6b is a photoluminescence (PL) spectrum of the beta gallium oxide thin film, FIG. 6c is an absorbance spectrum of the beta gallium oxide thin film measured using UV-vis absorption spectroscopy, and FIG. 6d is 6e shows the VBM-core delta region and energy band structure of beta gallium oxide.

The atomic composition of the beta gallium oxide thin film calculated from the XPS data of FIG. 6a was observed to be Ga:O = 1:1.67, which is similar to the stoichiometric ratio of gallium oxide (Ga ₂ O ₃ ), which is dry air It shows complete oxidation of the gallium oxide thin film by heat treatment at 900 °C in the atmosphere. In addition, the XPS peak of the O 1s core level was observed at a higher binding energy after heat treatment, which shows a decrease in oxygen vacancy ( _VO ) concentration due to additional oxidation.

6B shows a photoluminescence (PL) spectrum of a beta gallium oxide thin film measured at room temperature using a 325 nm laser as an excitation source. Here, the emissions centered at 437 and 527 nm are gallium-oxygen vacancy pairs (V _{Ga -VO} ) and neutral oxygen interstitials (O _i ), respectively. ⁰ ) is the result of electron-hole recombination.

6C shows an absorbance spectrum of a beta gallium oxide thin film measured using UV-vis absorption spectroscopy. The optical band gap (E _g ) of a direct band gap material can be calculated from the absorption edge using the equation

Here, α = the absorption coefficient, hυ = the photon energy, and c = constant. As shown in the inset of FIG. 6c, the optical band gap of 2D beta gallium oxide derived from the Tauc plot is about 5.34 eV, which is about 5.34 eV, which is larger than the band gap of bulk beta gallium oxide (4.7-4.9 eV). eV) has a larger value than The thickness of the 2D beta-gallium oxide thin film formed by the squeezing method is about 2-3 nm, which is smaller than the exciton Bohr radius of 3.29 nm of beta-gallium oxide, so the observed band gap difference is strong quantum. This can be explained by the effect of the quantum confinement effect. In addition, the band gap of 2D beta gallium oxide enables the formation and epitaxial growth of an additional beta gallium oxide layer using van der Waals epitaxy. As shown in FIG. 3, after forming the first beta gallium oxide layer through compression and heat treatment, a beta gallium oxide layer may be additionally formed thereon by repeating the same process. After forming an additional 3.2 nm β-gallium oxide layer on the 2-nm-thick β-gallium oxide layer, E _g was about 5.18 eV, and a decrease in the optical band gap due to a decrease in the quantum confinement effect was observed. Therefore, like conventional van der Waals two-dimensional materials such as TMD or black phosphorus, it can be used by adjusting a desired thickness or band gap using van der Waals epitaxy according to the application. The valence band maximum (VBM) of the two-dimensional beta gallium oxide was calculated through linear fitting of the flat energy distribution and the leading edge of VB through XPS as shown in FIG. 6d. The calculated VBM is about 4.85 eV, showing intrinsic n-type characteristics of 2D beta gallium oxide. In addition, the VBM-core delta region and energy band structure of 2D beta gallium oxide calculated from FIGS. 6a to 6d are summarized in FIG. 6e.

2.3 Growth of 2D beta gallium oxide thin film on various substrates

7a is an optical microscope image of a beta gallium oxide thin film grown on a graphene, quartz, Si (100), or sapphire substrate, and FIG. 7b is an optical microscope image of a beta gallium oxide thin film. It shows surface roughness (surface topography), Figure 7c is a Raman spectrum (raman spectra) of the beta gallium oxide thin film, Figure 7d shows the XRD (x-ray diffraction pattern) spectrum of the beta gallium oxide thin film.

On all substrates, beta gallium oxide showed millimeter-scale void-free full coverage, with rms values of 0.76, 1.5, 2.2, and 14 nm, respectively. The roughness of the grown nano beta gallium oxide thin film is influenced by two factors. The first factor is the roughness of the underlying substrate. The rms of the graphene, quartz, Si, and sapphire substrates were 0.67, 1.5, 0.86, and 9.9 nm, respectively, which are similar to those of the beta gallium oxide thin film. However, in the case of the Si substrate, the thin film has a high roughness despite the low rms of the substrate, which can be explained by the effect of interface tension. Liquid gallium has low viscosity and high surface energy, but high wettability to hydrophilic substrates due to surface oxide formed as a result of Cabrera-Mott oxidation. Therefore, even Si or Pt substrates with high surface energy have dewetting due to high interfacial tension (see FIG. 7b). Surface energy can be controlled by methods such as UV/ozone, oxygen plasma, or acid etching, and thus wettability can be controlled.

7c and 7d show Raman and XRD spectra of beta gallium oxide grown on graphene, quartz, Si, and sapphire, respectively. Characteristic Raman peaks and diffraction peaks of beta gallium oxide were observed on all substrates. Formation of beta gallium oxide layers on various substrates without affecting the lattice constant of the lower substrate because the growth of thin films using liquid gallium compression depends on the oxidation of the gallium oxide layer adhered to the substrate by van der Waals forces. makes it possible It is expected that in the future, it will be possible to integrate with substrates with various functions, including flexible substrates and transparent substrates, using heterostructures. Some features of alpha gallium oxide were observed on Si and sapphire substrates. If sufficient thermal energy is supplied to the strained beta gallium oxide, a phase change to alpha gallium oxide can occur. The strain is relaxed through a phase change from a twin boundary to a metastable α phase in a hexagonal form (see FIG. 7e). Accordingly, heterophase Ga ₂ O ₃ in which α and β phases are mixed may be formed due to strain in the gallium oxide layer caused by a difference in surface morphology or surface energy of the substrate. Since this metastable alpha gallium oxide has a wider band gap than that of the β phase, interest is growing as a candidate material for ultra-high breakdown transistors or deep UV opto-electronics at sub-240 nm wavelength.

Although the present invention has been described in detail through specific examples, this is for explaining the present invention in detail, the present invention is not limited thereto, and within the technical spirit of the present invention, by those skilled in the art It is clear that modifications and improvements are possible.

All simple modifications or changes of the present invention belong to the scope of the present invention, and the specific protection scope of the present invention will be clarified by the appended claims.

Claims (8)

(a) transferring liquid gallium in the form of droplets onto a substrate;
(b) forming a gallium oxide layer in the form of a two-dimensional thin film by compressing the transferred liquid gallium with a compression plate; and
(c) forming a beta gallium oxide layer in the form of a two-dimensional thin film by heat-treating the gallium oxide layer;
Method for producing a beta gallium oxide thin film in which the gallium oxide layer is formed based on oxygen adsorbed on the surface of the liquid gallium.
The method of claim 1,
In step (a),
Dropping the liquid gallium in the form of droplets on the substrate using a micro pipet.
The method of claim 1,
In step (a),
placing the substrate on a hot plate heated to 30° C. or higher; and
Dropping the liquid gallium on the substrate; beta gallium oxide thin film manufacturing method comprising a.
The method of claim 1,
In step (b),
A method of manufacturing a beta gallium oxide thin film by compressing the liquid gallium with a compressive force of 0.5 to 50 N.
The method of claim 1,
In step (b),
The compressed plate is removed while being spaced apart in a direction perpendicular to the upper surface of the gallium oxide layer.
The method of claim 1,
In step (c),
Method for manufacturing a beta gallium oxide thin film by heat treatment at a temperature of 500 ~ 1000 ℃.
The method of claim 1,
The thickness and area of the beta gallium oxide thin film are controlled by the amount of the liquid gallium transferred in the step (a) and the compressive force for compressing the liquid gallium in the step (b). Method for manufacturing a gallium oxide thin film.
The method of claim 1,
After step (c),
On the beta gallium oxide layer generated in step (c), the liquid phase transfer step according to step (a), the gallium oxide layer forming step according to step (b), and beta oxidation according to step (c) A method for manufacturing a beta gallium oxide thin film in which n+1 (n≥1, natural number) of the beta gallium oxide layers are stacked on the substrate by sequentially performing the gallium layer forming step n (n≥1, natural number) times. .