KR101922771B1 - phase change device having chalcogenide-nonconductor nanocomposite material thin film and method of manufacturing the same - Google Patents

Abstract

The present invention relates to a phase-change element using a phase change property of a chalcogenide and a method of manufacturing the same, and particularly relates to a phase change element using a chalcogenide and a non- To a phase-change element whose power is reduced.
The present invention also relates to a method for forming a chalcogenide-nonconductive nanocomposite thin film using spin coating of nonconductive particles and reflow characteristics of chalcogenide.

Description

TECHNICAL FIELD The present invention relates to a phase change device including a chalcogenide-nonconductive nanocomposite thin film and a method of manufacturing the same.

The present invention relates to a chalcogenide-nonconductive nanocomposite thin film capable of further reducing the power required for phase change of chalcogenide by utilizing the property of accelerating the heat generation of the nanocomposite material comprising a chalcogenide and a nonconductive material And a method of manufacturing the same.

The phase-change element is a device that stores information by using a chalcogenide having a phase-change characteristic as an active material or performs a switch operation in a programmable logic device. When the chalcogenide is crystalline or amorphous Such as CD-RW and DVD-RW, which utilize the difference in optical reflectance due to the reversible phase change of the optical disc.

In addition to the above-mentioned reflectance, the phase-change chalcogenide has a resistivity lower than that of amorphous in crystalline state and has a characteristic such that the difference in resistivity according to the microstructure is as large as 10 ⁵ times. Phase-change electronic devices (phase-change memory elements, phase-change switch elements).

The phase-change memory device, which is one of candidates to replace flash memory in the future, has a faster switching speed and higher integration by scaling than a flash memory based on a MOS transistor including a gate oxide film, And a phase-change switch element is attracting attention as a key component that performs a function of connecting or disconnecting a logic block and a wiring according to a user's programming in a programmable logic device.

In order to commercialize such a phase-change memory element and a phase-change switch element, it is important to improve the amorphous stability of the phase-change chalcogenide and to reduce the power required to induce the phase change, and a lot of research has been conducted thereon.

As a method of reducing the power required to induce a phase change, Korean Patent Laid-Open No. 10-2005-0111469 (Patent Document 1) discloses a method of forming a phase-change memory element capable of increasing contact resistance by a dielectric film Technology. In addition, Korean Patent Publication No. 10-1019989 (Patent Document 2) discloses that a high-retention property and a low operation property are obtained by using a germanium-antimony / germanium-antimony-tellurium (GeSb / GeSbTe) A phase change memory element capable of realizing a current and a method for manufacturing the same.

The phase change device disclosed in the above-described prior art has a complicated process and has a limitation in increasing the contact resistance of the phase change material film itself, so that it is difficult to manufacture a high integration phase conversion device.

Korean Patent Publication No. 10-2005-0111469 (published on November 25, 2005) Korean Registered Patent No. 10-1019989 (registered on April 29, 2010)

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a chalcogenide compound having improved amorphous stability and reduced power required to induce phase change, The present invention provides a phase-change element including a cargo-nonconductive nanocomposite thin film and a manufacturing method thereof.

According to an aspect of the present invention, there is provided a plasma display panel comprising: a first electrode formed on a substrate;

An insulating film formed on the first electrode;

A heat generating layer formed in the insulating film;

Wherein the nonconductive particles are formed in a dispersed phase in the chalcogenide medium, the nonconductive particles being included in a proportion of 20% to 50% by weight,
Coating the colloid with the nonconductive particles and heat treating the colloidal dispersion medium to evaporate the colloidal dispersion medium; and depositing a chalcogenide thin film, wherein the concentration of the nonconductive particles in the colloid, the rate of the spin coating, A chalcogenide-nonconductive nanocomposite thin film layer capable of controlling the phase change behavior by controlling the distance of the nonconductive dispersed phase distributed in the chalcogenide medium by changing the time of the dispersion medium or the evaporation temperature of the dispersion medium; And

And a second electrode formed on the nanocomposite thin film layer, wherein the nanocomposite nanocomposite thin film comprises a chalcogenide-nonconductive nanocomposite thin film.

The first electrode may be made of a metal material or a compound containing a metal element.

The width of the heating layer may be 0.5 탆 or less.

The resistance value of the heating layer may be 20 x 10 < ³ > ohm or less.

The chalcogenide constituting the chalcogenide-nonconductive nanocomposite thin film layer may be at least one of GeTe, SiTe, SbTe, GeSbTe, InSbTe, GaSbTe, GaSbSe, and the like.

The nonconductive material constituting the thin film layer of the chalcogenide-nonconductive nanocomposite material may include ZrO ₂ , Al ₂ O ₃ , TiO ₂ , AlTiO, HfO ₂ , SiO ₂ , Si ₃ N ₄ , Si, Ge, SiGe, And the like.

The second electrode may be made of a metal material or a compound containing a metal element.

According to another aspect of the present invention, there is provided a method of manufacturing a semiconductor device, comprising: forming a first electrode on a substrate;

A second step of depositing an insulating film on the first electrode;

Forming a contact hole exposing the first electrode by dry etching the insulating film;

A fourth step of forming a heating layer in the contact hole;

Wherein the nonconductive particles are dispersed in the chalcogenide medium so as to cover the entire upper surface of the insulating layer on which the heating layer is formed, and the nonconductive material includes 20% to 50% by weight,
Coating the colloid with the nonconductive particles and heat treating the colloidal dispersion medium to evaporate the colloidal dispersion medium; and depositing a chalcogenide thin film, wherein the concentration of the nonconductive particles in the colloid, the rate of the spin coating, Conductor nanocomposite thin film layer capable of controlling the phase change behavior by controlling the distance of the nonconductive dispersed phase distributed in the chalcogenide medium by changing the time of the dispersion of the chalcogenide material or the evaporation temperature of the dispersion medium Step 5; And

And a sixth step of depositing a second electrode on the chalcogenide-nonconductive nanocomposite thin film layer. The method for manufacturing a phase change device according to claim 1, wherein the chalcogenide- to provide.

The chalcogenide-nonconductive nanocomposite thin film layer of the fifth step may be prepared by spin-coating and heat-treating a colloid containing nonconductive particles and then depositing a chalcogenide thin film.

The nonconductive particles may be one selected from the group consisting of ZrO ₂ , Al ₂ O ₃ , TiO ₂ , AlTiO, HfO ₂ , SiO ₂ , Si ₃ N ₄ , Si, Ge, SiGe, GaAs and InP.

The chalcogenide may be one selected from the group consisting of GeTe, SiTe, SbTe, GeSbTe, InSbTe, GaSbTe, GaSeTe, SnSbTe, SiSbTe, GeSiSbTe, GeSnSbTe, GeSbSeTe, AgInSbTe, SbSe, InSe, SbSbSe and GaSbSe.

After the deposition of the chalcogenide thin film, a heat treatment for reflow may be performed in a temperature range of 450 ° C or lower.

The phase change device including the chalcogenide-nonconductive nanocomposite material thin film according to the present invention is effective in prolonging the recording retention time of the phase change device by using amorphous stability improvement by the nanocomposite material thin film.

Further, the present invention is effective in reducing the power consumption of the phase-change element by utilizing the property of accelerating the heat generation by the nanocomposite material thin film.

1 is a cross-sectional view of a phase-change element according to the present invention.
2 is a plan view of a chalcogenide-nonconductive nanocomposite material thin film according to the present invention.
3 is a cross-sectional view of a chalcogenide-nonconductive nanocomposite material thin film according to the present invention.
FIG. 4 is a cross-sectional view illustrating a process for producing a chalcogenide-nonconductive nanocomposite thin film according to the present invention.
5 is a view sequentially showing cross-sectional views of respective steps of the method for manufacturing a phase-change element according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail, and a detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted.

According to an aspect of the present invention, there is provided a plasma display panel comprising: a first electrode formed on a substrate;

An insulating layer 200 formed on the first electrode;

A heating layer 300 formed in the insulating layer;

A chalcogenide-nonconductive nanocomposite thin film layer 400 formed in contact with the heating layer; And

And a second electrode (500) formed on the nanocomposite thin film layer, wherein the nanocomposite nanocomposite thin film comprises a chalcogenide-nonconductive nanocomposite thin film.

The first electrode 100 may be made of a metal material or a compound containing a metal element.

More specifically, the first electrode 100 is in ohmic contact with the heating layer 300 to smooth the flow of current flowing through the heating layer 300. The first electrode 100 has high electrical conductivity, It is preferable to use a pure metal such as Al, Cu, W, or Ti having chemically stable characteristics in contact or a compound or alloy containing a metal element such as Al, Cu, W or Ti.

The insulating layer 200 is formed on the upper portion of the first electrode 100 and the lower portion of the chalcogenide nonconductive nanocomposite thin film layer 400 so as to be in direct contact with the nanocomposite thin film layer 400 and the first electrode 100 And may be made of a nonconductive material having a high electrical resistivity such as silicon oxide or silicon nitride.

The insulating layer 200 surrounds the side surface of the heating layer 300 so that the upper portion of the heating layer 300 is electrically connected to the nanocomposite thin film layer 400 and the lower portion of the heating layer 300 is electrically connected to the first electrode (Not shown).

The width of the heating layer 300 may be 0.5 μm or less.

More specifically, the smaller the area of the interface between the heating layer 300 and the chalcogenide-nonconductive nanocomposite thin film layer 400 is, the more the resistance component of the heating layer 300 and the heat resistance of the heating layer 300 are increased. The width of the heating layer 300 is preferably 0.5 μm or less, and when the thickness of the heating layer 300 is more than 0.5 μm, There is a problem that the power required for the phase change increases.

The heating layer 300 is a layer located under the chalcogenide-nonselectroconductive nanocomposite thin film layer 400. When the current flows in the layer, the current is squared and proportional to the product of resistance (I ² R) And transfers the generated joule heat to the chalcogenide-nonconductive nanocomposite thin film layer 400 in contact with the heating layer 300 to promote the phase change of the chalcogenide 410.

The heating layer 300 may be formed of TiN, TaN, Si, or SiGe having a relatively high electrical resistivity as compared with the material of the first electrode 100. SiGeSb, or the like. In the case of an electron conductor, the larger the electrical resistivity, the smaller the thermal conductivity. Therefore, when a material having a high electrical resistivity is used, the heat generated by the joule heating dissipates through the heating layer 300 and the first electrode 100, The phase change of the chalcogenide 410 can be further promoted.

The resistance value of the heating layer 300 may be 20 x 10 ³ ohm or less.

More specifically, as the width of the heating layer 300 decreases, that is, as the resistance of the heating layer 300 becomes larger, the line heat lost through the heating layer 300 and the first electrode 100 is further reduced, The current required for causing the phase change of the chalcogenide 410 does not sufficiently flow when the resistance value of the heat generating layer 300 in the direction of the chalcogenide 410 is more than 20 x 10 ³ ohm.

The effect of the resistance of the material constituting the heating layer 300 on the phase change behavior of the chalcogenide 410 is well described in Journal of Non-Crystalline Solids 358 (2012) 2405-2408.

The chalcogenide-nonconductive nanocomposite material thin film layer 400 is an active material of the phase-change device. The chalcogenide material is a chalcogenide material having a property of reversibly changing the phase between amorphous and crystalline materials and a nonconductive material dispersed phase a dispersed phase, and the like.

The chalcogenide 410 constituting the chalcogenide-nonconductive nanocomposite thin film layer 400 may be at least one selected from the group consisting of GeTe, SiTe, SbTe, GeSbTe, InSbTe, GaSbTe, GaSeTe, SnSbTe, SiSbTe, GeSiSbTe, GeSnSbTe, GeSbSeTe, AgInSbTe, SbSe, InSe, SbSbSe, and GaSbSe.

The chalcogenide (410) is a compound or alloy material containing S, Se or Te, which is a chalcogen element corresponding to the VIA group. Part of the chalcogenide (410) is reversibly changed in phase between amorphous and crystalline, The phases have different electrical resistivities. The GeSbTe thin film, which is a typical phase-change chalcogenide 410, has a difference in resistance between crystalline and amorphous about 10 ⁵ times or more. The phase change chalcogenide 410 exhibits a phase change behavior in which the microstructure reversibly changes from crystalline to amorphous or from amorphous to crystalline depending on the magnitude and duration of energy applied unlike a typical solid material, A nonvolatile memory having a function of recording and reading binary information is manufactured using the difference in electric resistivity.

The nonconductive material 420 constituting the chalcogenide-nonconductive nanocomposite material thin film layer 400 may be at least one selected from the group consisting of ZrO ₂ , Al ₂ O ₃ , TiO ₂ , AlTiO, HfO ₂ , SiO ₂ , Si ₃ N ₄ , Si, Ge , SiGe, GaAs, and InP.

The nonconductive dispersed phase is not particularly limited as long as it is a nonconductive material which is a semiconductor or a nonconductive material having a lower electric conductivity than an alloy containing a metal and a metal element.

The particle size of the nonconductive dispersed phase is such that the electric conductivity and thermal conductivity of the active material are sufficiently reduced by the presence of the nonconductive dispersed phase in the chalcogenide medium to reduce the power consumption of the phase- .

The second electrode 500 may be made of a metal material or a compound containing a metal element.

The second electrode 500 may be made of the same material as that of the first electrode 100. More specifically, the second electrode 500 may be made of Al, Cu, or W having high electrical conductivity and chemically stable characteristics , Ti, or the like, or a compound or alloy containing a metal element such as Al, Cu, W, Ti, or the like.

According to another aspect of the present invention, there is provided a method of manufacturing a semiconductor device, comprising: forming a first electrode on a substrate;

A second step of depositing an insulating layer (200) on the first electrode (100);

A third step of dry-etching the insulating layer 200 to form a contact hole 210 exposing the first electrode 100;

A fourth step of forming a heating layer 300 in the contact hole 210;

A fifth step of forming a chalcogenide / nonconductive nanocomposite thin film layer 400 so as to cover the entire upper surface of the insulating layer 200 on which the heating layer 300 is formed; And

And a sixth step of depositing a second electrode (500) on the chalcogenide-nonconductive nanocomposite thin film layer (400). The chalcogenide-nonconductive nanocomposite thin film layer A method of manufacturing a variable element is provided.

The chalcogenide-nonconductive nanocomposite thin film layer 400 of the fifth step is prepared by spin-coating and heat-treating a colloid containing nonconductive particles 420 and then depositing a thin film of chalcogenide 410 .

The nonconductive particles 420 may be one selected from the group consisting of ZrO ₂ , Al ₂ O ₃ , TiO ₂ , AlTiO, HfO ₂ , SiO ₂ , Si ₃ N ₄ , Si, Ge, SiGe, GaAs, .

The chalcogenide 410 is one kind selected from the group consisting of GeTe, SiTe, SbTe, GeSbTe, InSbTe, GaSbTe, GaSeTe, SnSbTe, SiSbTe, GeSiSbTe, GeSnSbTe, GeSbSeTe, AgInSbTe, SbSe, InSe, SbSbSe and GaSbSe .

More specifically, the chalcogenide-nonconductive nanocomposite thin film layer 400 is formed by spin-coating and heat-treating a colloid containing nano- or micrometer-sized nonconductive particles 420 on a substrate 600 to evaporate the colloidal dispersion medium And leaving only the nonconductive particles 420 on the substrate.

The colloid may be one prepared by dispersing the nonconductive particles 420 in a dispersion medium such as ethylene glycol or tripropylene glycol mono methyl ether (TPM) The weight percent of the conductor particles is not particularly limited, but is preferably 20% to 50%. If the weight percentage of the nonconductive particles 420 dispersed in the colloid is less than 20%, there is a problem that an excessive amount of dispersion medium is used compared to the nonconductive particles 420, which is not economical. When the weight percentage exceeds 50% And there is a problem that dispersion stability is lost. Therefore, it is preferable to maintain the above range.

In addition, the spin coating proceeds to a step of applying the colloid to the substrate and a step of uniformly coating the colloid on the substrate, and the rotation speed of the coating step is faster than the coating step and takes longer time.

The spin coating may be conducted at a rotational speed of 500 to 8000 rpm.

More specifically, when the spin coating is conducted at a rotational speed of less than 500 rpm, the uniformity of the coating layer of the nonconductive particles 420 deteriorates. When the spin coating proceeds at more than 8000 rpm, the amount of the non- Is too small and there is a problem that the coating layer becomes thin, it is preferable to keep the above range.

The spin coating may proceed in a time range of 30 seconds to 10 minutes, and if it is less than 30 seconds, the formation of the coating layer of the nonconductive particles 420 may be deteriorated. If the coating time is longer than 10 minutes, There is a problem that the uniformity of the coating layer of the particles 420 deteriorates. Therefore, it is preferable to maintain the above range.

The heat treatment may be carried out at a reaction temperature of 50 to 150 ° C.

More specifically, after spin coating is completed, the dispersion medium may be evaporated by performing heat treatment in a temperature range of 50 ° C to 150 ° C for 2 seconds to 10 minutes, and when the heat treatment temperature is less than 50 ° C There is a problem that evaporation of the dispersion medium is not sufficiently carried out. When the temperature exceeds 150 ° C, decomposition of the nonconductive particle layer 420 occurs. When the heat treatment is carried out for less than 2 seconds, the dispersion medium is not sufficiently evaporated to form a heterogeneous particle layer. When the heat treatment is performed for more than 10 minutes, a phase different from the desired nonconductive particle layer 420 Because there is a problem to be made, it is good to keep the above range.

By varying the concentration of the nonconductive particles 420 in the colloid, the spin-coating rate, the spin-coating time, or the evaporation temperature of the dispersion medium, the distance of the non-conductive distribution surface to be distributed in the chalcogenide 410 medium is controlled, It is possible to control the phase change behavior of the nano composite thin film layer 400 of the cogenitride-nonconductive material.

The chalcogenide (410) thin film is formed on the entire upper surface using sputter deposition, and Ar gas is injected in a flow rate range of up to 20 sccm for sputter deposition to maintain a deposition pressure of up to 10 × 10 ^-3 torr, And the cathode target made of the chalcogenide 410 in the range of 20W to 150W.

The deposition may be performed at a flow rate of 0.2 to 20 sccm.

More specifically, when the deposition is performed in a flow rate range of less than 0.2 sccm, the deposition rate is too slow. When the deposition rate is more than 20 sccm, the deposition rate is fast and efficient deposition is performed on the first electrode 100 It is preferable to maintain the above range.

The deposition may be conducted at a pressure of 1 x ^10-3 to 10 x ^10-3 torr.

More specifically, when the deposition is performed at a pressure of less than 1 x ^10-3 torr, the thin film is not formed. When the deposition is performed at a pressure exceeding 10 x ^10-3 torr, And there is a problem that direct deposition is not performed on a desired portion. Therefore, it is desirable to maintain the above range.

When the power applied to the negative electrode target made of the chalcogenide 410 is less than 20 W, sufficient sputtering does not occur. When the power exceeds 150 W, the deposition rate is greatly increased and the thickness of the chalcogenide 410 The above-described range is preferable.

The chalcogenide thin film 410 may be formed by chemical vapor deposition or atomic deposition to form a thin film by decomposing a chalcogenide precursor such as TDMAGe or DIPTe at a temperature of 450 ° C or lower. layer deposition).

After the thin film deposition of the chalcogenide 410, a heat treatment for reflowing may be performed in a temperature range of 450 ° C or less.

More specifically, when the heat treatment for reflow is carried out in a temperature range exceeding 450 캜, there is a problem of causing a change in physical properties of the materials (for example, the first electrode 100) formed before the reflow process, Deg.] C or less.

A chalcogenide-nonconductor composed of a chalcogenide medium and a nonconductive dispersed phase is formed by reflowing to form a chalcogenide (410) thin film by filling the vacant space between the nonconductive particles (420) The nanocomposite thin film layer 400 is completed.

When a phase-change chalcogenide is formed by sputter deposition at room temperature, it has an amorphous phase. Since the amorphous phase can flow by viscous flow even at a temperature below the melting point similar to the liquid phase, if heat treatment is performed at a temperature higher than room temperature, it flows by reflow to form chalcogenide medium.

The heat treatment atmosphere for reflow may be Ar, N ₂ , H ₂ , O ₂ , Cl _2, and the like.

It is possible to use a method in which a current is applied after the fabrication of the phase-change element is completed without performing the heat treatment for reflow.

The nanoparticle spin coating, chalcogenide deposition, and reflow may be sequentially repeated several times to control the thickness of the chalcogenide-nonconductive nanocomposite thin film layer 400.

Alternatively, the chalcogenide-nonconductive nanocomposite thin film layer 400 contacting the heating layer 300 may be formed, and only the chalcogenide 410 may be deposited thereon.

 When the active material of the device is composed of the chalcogenide-nonconductive nanocomposite material thin film layer 400 rather than the active material of the phase-change device alone, the chalcogenide 410 is crystallized Higher amorphous stability can be ensured because it is disturbed by the nonconductive phase evenly distributed in the chalcogenide-nonconductive nanocomposite thin film layer 400.

The phase change is generated by the energy applied to the chalcogenide 410 and becomes amorphous so that crystallization of the amorphous phase spontaneously proceeding for a long time is suppressed as much as possible in order to maintain the information recorded state as it is, The thermal stability of the phase amorphous phase with the phase change element is directly related to the recording retention time of the phase change element.

The chalcogenide 410 alone constitutes the active material of the device with the chalcogenide-nonconductive nanocomposite material thin film layer 400 rather than the active material of the phase-change device, The nonconductive phase with low conductivity or low thermal conductivity is distributed in the nanocomposite material, and thus the effect of accelerating the heat generation by decreasing the electrical conductivity and thermal conductivity of the whole thin film [IEEE Transactions on Electron Devices 51 (2004) 452-459] ≪ / RTI > is reduced. That is, even with a small current, the phase change of the chalcogenide 410 is induced, thereby reducing the power consumption of the phase-change element.

The electrical resistivity (ρ) of a material in which a heterogeneous phase is dispersed in the medium is expressed by the following mixing rule when the resistivity (ρ _d ) of the dispersed phase is at least 10 times the resistivity (ρ _m ) of the medium [O .Kasap, Principles of Eletronic Materials and Devices, p. 150]

X _d is the volume fraction of the dispersed phase to the total volume. Specifically, when the electrical resistivity of the crystalline GeSbTe chalcogenide is 3.02 10 ^-1? M, the electrical resistivity of the ZrO ₂ nonconductor is 3.16 10 ^5? M, and the ZrO ₂ nonconductor occupies 3/10 of the total volume, the GeSbTe chalcogenide medium And the chalcogenide-nonconductive nanocomposite thin film layer 400 composed of the ZrO ₂ nonconductor dispersed phase has an electric resistivity of 4.96 × 10 ^-1 Ωm which is about 1.64 times larger than that of GeSbTe chalcogenide, Constructing the active material with the chalcogenide-nonconductive nanocomposite material thin film layer 400 rather than by itself constituting the active material reduces the power that causes the phase change.

Hereinafter, the present invention will be described in more detail with reference to examples, but these examples are for illustrative purposes only and are not intended to limit the scope of protection of the present invention.

In order to fabricate a phase change device including a chalcogenide-nonconductive nanocomposite thin film layer 400, the present invention proceeds as follows.

An insulating layer 200 is deposited on the first electrode 100 and a contact hole 210 to be filled with the heat generating layer 300 is formed through a photolithography process and a dry etching process, And is planarized using chemical mechanical polishing to form a heating layer 300 located only in the contact hole 210. A chalcogenide-nonconductive nanocomposite thin film layer 400 is formed on the entire upper surface of the insulating layer 200 where the heating layer 300 is formed, and the second electrode 500 is deposited. A part of the chalcogenide-nonconductive nanocomposite thin film layer 400 and the second electrode 500 is confined on the insulating layer 200 through photolithography and dry etching to complete the phase-change element.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept as defined by the appended claims. It will be possible. The scope of the present invention is defined by the appended claims, and all differences within the scope of the claims are to be construed as being included in the present invention.

100: first electrode
200: insulating film
210: Contact hole
300: heating layer
400: chalcogenide - nonconductive nanocomposite thin film layer
410: chalcogenide
420: nonconductive particles
500: Second electrode
600: substrate

Claims (12)

A first electrode formed on the substrate;
An insulating film formed on the first electrode;
A heat generating layer formed in the insulating film;
Wherein the nonconductive particles are formed in a dispersed phase in the chalcogenide medium, the nonconductive particles being included in a proportion of 20% to 50% by weight,
Coating the colloid with the nonconductive particles and heat treating the colloidal dispersion medium to evaporate the colloidal dispersion medium; and depositing a chalcogenide thin film, wherein the concentration of the nonconductive particles in the colloid, the rate of the spin coating, A chalcogenide-nonconductive nanocomposite thin film layer capable of controlling the phase change behavior by controlling the distance of the nonconductive dispersed phase distributed in the chalcogenide medium by changing the time of the dispersion medium or the evaporation temperature of the dispersion medium; And
A second electrode formed on the nanocomposite thin film layer;
Wherein the chalcogenide-nonconductive nanocomposite material thin film comprises a chalcogenide-nonconductive nanocomposite material thin film,
The chalcogenide constituting the chalcogenide-nonconductive nanocomposite thin film layer may be at least one of GeTe, SiTe, SbTe, GeSbTe, InSbTe, GaSbTe, GaSbSe, < / RTI >
The nonconductive material constituting the thin film layer of the chalcogenide-nonconductive nanocomposite material may include ZrO ₂ , Al ₂ O ₃ , TiO ₂ , AlTiO, HfO ₂ , SiO ₂ , Si ₃ N ₄ , Si, Ge, SiGe, And a chalcogenide-nonconductive nanocomposite material thin film, wherein the chalcogenide-nonconductive nanocomposite material thin film comprises a chalcogenide-nonconductive nanocomposite material thin film. The method according to claim 1,
Wherein the first electrode is made of a metal material or a compound containing a metal element, the chalcogenide-nonconductive nanocomposite material thin film. The method according to claim 1,
Wherein the heating layer has a width of 0.5 占 퐉 or less, wherein the chalcogenide-nonconductive nanocomposite material comprises a thin film. The method according to claim 1,
Wherein the resistance value of the heating layer is 20 x 10 < ³ > ohm or less. delete delete The method according to claim 1,
Wherein the second electrode is made of a metal material or a compound containing a metal element, and the chalcogenide-nonconductive nanocomposite material thin film. A first step of forming a first electrode on a substrate;
A second step of depositing an insulating film on the first electrode;
Forming a contact hole exposing the first electrode by dry etching the insulating film;
A fourth step of forming a heating layer in the contact hole;
Wherein the nonconductive particles are dispersed in the chalcogenide medium so as to cover the entire upper surface of the insulating layer on which the heating layer is formed, and the nonconductive material includes 20% to 50% by weight,
Coating the colloid with the nonconductive particles and heat treating the colloidal dispersion medium to evaporate the colloidal dispersion medium; and depositing a chalcogenide thin film, wherein the concentration of the nonconductive particles in the colloid, the rate of the spin coating, Conductor nanocomposite thin film layer capable of controlling the phase change behavior by controlling the distance of the nonconductive dispersed phase distributed in the chalcogenide medium by changing the time of the dispersion of the chalcogenide material or the evaporation temperature of the dispersion medium Step 5; And
And a sixth step of depositing a second electrode on the chalcogenide-nonconductive nanocomposite thin film layer. The method for manufacturing a phase change device according to claim 1, wherein the chalcogenide- ,
The chalcogenide constituting the chalcogenide-nonconductive nanocomposite thin film layer may be at least one of GeTe, SiTe, SbTe, GeSbTe, InSbTe, GaSbTe, GaSbSe, < / RTI >
The nonconductive material constituting the thin film layer of the chalcogenide-nonconductive nanocomposite material may include ZrO ₂ , Al ₂ O ₃ , TiO ₂ , AlTiO, HfO ₂ , SiO ₂ , Si ₃ N ₄ , Si, Ge, SiGe, Wherein the chalcogenide-nonconductive nanocomposite material comprises a chalcogenide-nonconductive nanocomposite material. delete delete delete 9. The method of claim 8,
Wherein the chalcogenide thin film is subjected to a heat treatment for reflow in a temperature range of 450 ° C or lower after the deposition of the chalcogenide thin film.

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