KR101934545B1 - Wavelength Conversion Nano Structure Light Source and Tunable Multicolor Emitting Display Using the Same - Google Patents

Abstract

The present invention relates to a wavelength conversion nanostructure light source which emits light of various collars by differentiating excitation energy based on the characteristics of emission wavelengths varying according to excitation wavelengths, and a tunable multicolor emitting display using the same. The wavelength conversion nanostructure light source includes a wavelength variable light source part for controlling the wavelength of light emitted depending on an electric signal applied; a wavelength conversion part including a nanostructure which receives near-infrared light transmitted from the wavelength tunable light source part as excitation light and converts it into the emission light of visible light; and a light emitting part for transmitting light of wavelengths of visible light transmitted from the wavelength converting part to the outside. The wavelength of the visible light obtained from the light emitting part depends on an electric signal applied to the wavelength variable light source part.

Description

TECHNICAL FIELD [0001] The present invention relates to a wavelength conversion nano structure light source and a variable multicolor display device using the same. ≪ Desc / Clms Page number 1 >

The present invention relates to a multi-color display device, and more particularly, to a wavelength converting nanostructure luminescent source that emits light of various colors from the same particle by varying excitation energy based on a characteristic that emission wavelength varies depending on excitation wavelength, To a multi-color display device.

Among the recently developed light emitting diode (LED) materials, the most popular materials for next generation display devices are quantum dots based on electroluminescence, nanocrystalline semiconductor crystals, and nanostructures such as nanoparticles with nonlinear optical properties to be.

Quantum dots have characteristics such as high color tone efficiency, narrow emission spectrum, high brightness, light stability, and air stability compared to conventional organic light emitting materials.

Recently, quantum dot light-emitting diodes (QLEDs) have been developed in which three kinds of quantum dots of different sizes, red, green, and blue (RGB), are precisely arranged on a substrate by using the characteristics that emit colors vary according to the size of the quantum dots, We implement several colors accordingly.

However, this method is complicated in the process of arranging particles of different sizes and requires three sizes of particles.

Quantum dot (or Quantum dot) refers to ultrafine semiconductor particles with a diameter of less than a few nanometers (nm). The inorganic material is composed of a core and a shell having a size of 2 to 10 nm. Finally, the polymer coating is wrapped.

The quantum dot display is called a quantum dot display in which the characteristics of the display are improved by using the quantum dot as a fluorescent material or a light emitting material or utilized as a display itself.

The unique point of the QDs is that, even though they are the same material, the color of light differs depending on the size of the particles when light is supplied or current is supplied.

The principle of the conventional quantum dot display is that when light of a specific wavelength is illuminated, blue light is emitted when a particle size is small, and red light is emitted when a particle size is large, So that various colors can be realized through the particle size.

The light that excites the quantum dots is based on a fast wavelength variable light source in which the wavelength of light emitted is dependent on the voltage or current of the electrical signal and is controlled in real time.

The conventional high-speed wavelength tunable light source is not yet realized in the visible light wavelength region required for display due to the wavelength limit of the optical gain medium, and is mainly implemented only in the near infrared wavelength region of 700 nm or more.

Nonlinear optical crystalline materials such as Lithium Niobate (LiNbO ₃ ), BBO, and KDP have been used to convert such invisible near-infrared light into visible light. However, It is difficult to apply it to a display application requiring at least RGB three wavelengths or more due to the limited conversion limit of the wavelength.

Korean Patent Laid-Open Publication No. 10-2016-0105460 Korean Patent Registration No. 10-0982991

In order to solve the problems of the conventional light source and display device, the present invention is directed to a wavelength conversion nano-optical device having different excitation energies based on characteristics of emission wavelengths varying according to excitation wavelengths, And a variable multi-color display device using the same.

The present invention realizes an environmentally friendly selenium fluoride quantum dot light emitting source and a selenium nano particle light emitting source that emit different colors from quantum dots of the same size by changing the excitation wavelength instead of adjusting the band gap by controlling the size of the quantum dots, The present invention provides a wavelength conversion nanostructure light source and a variable multicolor display device using the same, which can realize a display device emitting light of various colors from the same particle.

The present invention relates to a wavelength converting nanostructure light emitting source which emits light of different wavelengths by a plurality of wavelength conversion nanostructure light emitting sources and which emits different colors to serve as display pixels to represent image information, And it is an object of the present invention to provide a multi-color display device.

The present invention relates to a near infrared ray wavelength variable light source unit in which the wavelength of light emitted in dependence on an electric signal is controlled, a wavelength conversion unit configured to convert near infrared rays transmitted from the wavelength variable light source unit into excitation light, And a variable multi-color display device using the same.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a wavelength converting nanostructure light source including a wavelength tunable light source unit configured to control a wavelength of light emitted in response to an applied electrical signal, a near- And a light emitting unit for transmitting light having a wavelength of visible light transmitted from the wavelength converting unit to the outside, wherein the wavelength conversion unit comprises a nano structure for converting visible light, And the wavelength depends on an electric signal applied to the variable wavelength light source unit.

The wavelength tunable light source unit is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied from light of a plurality of wavelengths corresponding to a plurality of resonators.

The wavelength variable light source unit is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied to a wavelength filter unit in a single resonator.

The wavelength variable light source unit is based on an output wavelength control in which light of a specific wavelength is selected by injection of a corresponding electric signal for each mode locking frequency depending on a resonance distance of each wavelength of light resonated in a single resonator do.

And the wavelength converting unit is based on the synthesized nanostructure.

And the wavelength converting unit is based on the synthesized Selenium Iron Qdots.

And to synthesize the selenium hwacheol quantum dots, hydrated perchlorate, iron (Fe (ClO4) 2 and xH ₂ O), glutathione (glutathione), dimethyl sulfonic Foxy cargo (Dimethyl sulfoxide (DMSO)), sodium selenite (Sodium selenite) Is synthesized by using the above-mentioned method.

The wavelength converting unit is based on synthesized selenium nanoparticles.

In order to synthesize selenium nanoparticles, glutathione, dimethyl sulfoxide (DMSO), and sodium selenite are used.

The light emitting unit is based on pixelization of a single nano structure, and emits different colors of light by giving different excitation energies to the same particles.

According to another aspect of the present invention, there is provided a variable multi-color display device using a wavelength converting nanostructure light emitting source, including a driving unit for applying an electric signal to control the wavelength of light emitted from the light source unit, A control unit for selecting a position of the light emitting unit corresponding to the output wavelength of the wavelength variable light source unit and outputting electric signal information for transmitting the selected light emitting unit to the driving unit, A wavelength conversion unit configured to receive the transmitted near-infrared light as excitation light and convert the converted near-infrared light into emission light of a visible light ray, and a light emitting unit to transmit light having a wavelength of visible light transmitted from the wavelength conversion unit to the outside, The wavelength of the visible light ray obtained from the light emitting portion is changed by the wavelength- And a plurality of wavelength conversion nanostructure light emitting sources are gathered to emit different colors by different electric signals applied to each of the plurality of wavelength conversion nanostructure light emitting sources to serve as respective display pixels to express image information .

The wavelength variable light source unit is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied from light of a plurality of wavelengths corresponding to a plurality of resonators.

The wavelength variable light source unit is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied to a wavelength filter unit in a single resonator.

The wavelength variable light source unit is based on an output wavelength control in which light of a specific wavelength is selected by injection of a corresponding electric signal for each mode locking frequency depending on a resonance distance of each wavelength of light resonated in a single resonator do.

And the wavelength converting unit is based on the synthesized nanostructure.

And the wavelength converting unit is based on the synthesized Selenium Iron Qdots.

And to synthesize the selenium hwacheol quantum dots, hydrated perchlorate, iron (Fe (ClO4) 2 and xH ₂ O), glutathione (glutathione), dimethyl sulfonic Foxy cargo (Dimethyl sulfoxide (DMSO)), sodium selenite (Sodium selenite) Is synthesized by using the above-mentioned method.

The wavelength conversion unit is based on synthesized selenium nanoparticles.

It is characterized by using glutathione, dimethyl sulfoxide (DMSO), and sodium selenite to synthesize selenium nanoparticles.

The light emitting unit is based on pixelization of a single nano structure, and emits different colors of light by giving different excitation energies to the same particles.

The wavelength converting nanostructure light source according to the present invention and the variable multicolor display device using the same have the following effects.

First, we implement wavelength conversion nanostructures (Selenium and Fe-Cu quantum dots, Selenium nanoparticles) emitters that emit light of various colors from the same particles by different excitation energies based on the characteristic that emission wavelength varies according to excitation wavelength.

A second aspect of the present invention provides a variable multi-color display device using a wavelength-converted nano-structured light emitting source that emits light of various colors from the same particle by varying excitation energy based on characteristics of varying emission wavelengths according to excitation wavelengths.

Third, by implementing the environmentally-friendly Selenium and Fe-Cu quantum dot and Selenium nanoparticle emission source that emit different colors from the same particle by changing the excitation wavelength instead of adjusting the band gap by controlling the size, a display device Can be implemented.

Fourth, a plurality of wavelength conversion nanostructure light emitting sources are gathered and emit different colors by different electric signals applied to each other, and the image information can be expressed by serving as respective display pixels.

Fifth, by using a wavelength converting nanostructure light emitting source including a nanostructure that receives near-infrared light transmitted from a wavelength variable light source as excitation light and converts the light into emitted light of visible light, the structure and manufacturing process of the display device Can be simplified.

1 is a schematic diagram of a wavelength converting nanostructure light emitting source according to the present invention
FIG. 2 is a configuration diagram of a variable multi-color display device using a wavelength converting nanostructure light emitting source according to the present invention
Fig. 3 is a flow chart of a process for producing selenium metal quantum dots constituting the wavelength converting nanostructure light emitting source according to the present invention
FIG. 4 is a graph showing a spectrum of a luminous visible light excited in the near-infrared region at various wavelengths of the Selenium Fe Qdots according to the present invention (left graph) and a linear fitting result graph of the center wavelength (right graph) of the visible light for the center wavelength of near-
FIG. 5 is a graph showing a spectrum of a luminous visible light excited in the near-infrared region at various wavelengths of selenium nanoparticles according to the present invention (left graph) and a linear fitting result graph of a center wavelength (right graph) of visible visible light with respect to a center wavelength of near-

Hereinafter, preferred embodiments of the wavelength converting nanostructure light source and the variable multi-color display device using the same according to the present invention will be described in detail as follows.

The features and advantages of the wavelength converting nanostructure light emitting source and the variable multicolor display device using the same according to the present invention will be apparent from the following detailed description of each embodiment.

FIG. 1 is a configuration diagram of a wavelength converting nanostructure light source according to the present invention, and FIG. 2 is a configuration diagram of a variable multicolor display apparatus using a wavelength converting nanostructure light emitting source according to the present invention.

The present invention relates to a wavelength-converted nanostructure light source and a variable multi-color display device using the same, wherein excitation energy is differentiated based on characteristics of emission wavelengths varying according to excitation wavelengths to emit light of various colors in the same particle. Selenium flame-retardant quantum dot or selenium nanoparticle emitter that emits different colors from the same particle by changing the excitation wavelength instead of adjusting the bandgap by controlling the band gap. So that the device can be implemented.

The structure of the wavelength converting nanostructure light emitting source according to the present invention will be described in detail as follows.

As shown in FIG. 1, the wavelength-converted nanostructure light source according to the present invention includes a wavelength variable light source unit 10 in which the wavelength of light emitted is dependent on an applied electrical signal, A wavelength conversion unit 11 composed of a nano structure that receives near infrared light as excitation light and converts the near infrared light into emitted light of a visible light ray and a light emitting unit 11 that transmits light of a wavelength of visible light transmitted from the wavelength conversion unit 11 to the outside 12, and the wavelength of the visible light obtained from the light emitting portion 12 depends on the electric signal applied to the wavelength variable light source portion 10. [

Here, the wavelength variable light source unit 10 is a wavelength variable light source unit based on a pulse light output.

The wavelength converter 11 composed of the nanostructure may be based on the synthesized selenium metal quantum dot or the wavelength converter 11 composed of the nanostructure may be based on synthesized selenium nanoparticles. It is natural that nanostructures using different materials can be used.

And the light emitting portion 12 is preferably based on a single nanostructure pixelization.

The wavelength variable light source unit 10 is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied from light of a plurality of wavelengths corresponding to a plurality of resonators.

The wavelength variable light source unit 10 is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied to a wavelength filter unit in a single resonator.

The wavelength tunable light source unit 10 is based on an output wavelength control in which light of a specific wavelength is selected by injection of a corresponding electric signal for each mode locking frequency depending on a resonance distance for each wavelength of light resonated in a single resonator.

2 is a configuration diagram of a variable multi-color display device using a wavelength converting nanostructure light emitting source according to the present invention.

The variable multi-color display device using the wavelength converting nanostructure light emitting source according to the present invention collects a plurality of wavelength converting nanostructure light emitting sources and emits different colors by different electric signals applied to each of the wavelength converting nanostructure emitting light sources, To represent the image information.

The variable multi-color display device using the wavelength converting nano structure light source according to the present invention includes a driving unit 21 for applying an electric signal to control the wavelength of light emitted from the light source unit 22, A wavelength tunable light source unit 22 for outputting near infrared rays by controlling the wavelength of light emitted depending on an electric signal to be supplied to the driving unit 21, and a controller for selecting the position of the light emitting unit corresponding to the output wavelength of the wavelength variable light source unit 22, A wavelength conversion unit 23 including a nano structure for converting near-infrared light received from the tunable light source unit 22 into excitation light and converting the light into emitted light of visible light, And a light emitting unit 24 for transmitting the visible light having a wavelength of visible light transmitted from the wavelength converting unit 23 to the outside, And the wavelength depends on the electric signal applied to the tunable light source section 22. [

Here, the wavelength variable light source unit 22 is a wavelength variable light source unit based on a pulse light output.

The wavelength variable light source unit 22 is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied from light of a plurality of wavelengths corresponding to a plurality of resonators.

The wavelength variable light source unit 22 is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied to a wavelength filter unit in a single resonator.

The wavelength variable light source unit 22 is based on an output wavelength control in which light of a specific wavelength is selected by injection of a corresponding electric signal for each mode locking frequency depending on a resonance distance for each wavelength of light resonated in a single resonator.

It is preferable that the wavelength converting part 23 composed of the nanostructure is based on synthesized Selenium Qdots or synthesized Selenium nanoparticles, but it is not limited thereto and nano structures using other materials can be used.

FIG. 4 shows the results of linear fitting of the visible spectrum of the emitted visible light excited in the near-infrared region at various wavelengths of the Selenium Fe-Cu quantum dots according to the present invention (left graph) and the center wavelength of the visible visible light near the center wavelength of near- .

When excited in the near IR region at various wavelengths in selenium and iron chelate quantum dots, the wavelength of the visible light depends also on the excitation wavelength and is converted linearly.

FIG. 5 shows the results of linear fitting of the visible spectrum of the emitted visible light excited in the near-infrared region at various wavelengths of the selenium nanoparticles according to the present invention (left graph) and the center wavelength of visible visible light (right graph) with respect to the center wavelength of near- .

When the selenium nanoparticles are excited in the near infrared region at various wavelengths, the wavelength of the visible light depends on the excitation wavelength and is converted linearly.

And the light emitting portion 24 is preferably based on a single nanostructure pixelization.

The variable multi-color display device using the wavelength converting nanostructure light emitting source according to the present invention collects a plurality of wavelength converting nanostructure light emitting sources and emits different colors by different electric signals applied to each of the wavelength converting nanostructure light emitting sources, To represent the image information.

An example of a manufacturing process of the wavelength converting nanostructure light emitting source according to the present invention will now be described.

FIG. 3 is a process flow chart for producing Selenium Fe-Cu quantum dots constituting the wavelength converting nanostructure light emitting source according to the present invention.

Quantum dots having the characteristic of converting the excitation light in the near infrared region of wavelengths of 700 nm or more to the emission light of the wavelength range of 350 nm to 700 nm are capable of converting various wavelengths without changing the size according to the wavelength, It can be implemented as a family of quantum dots. It has the characteristics of environment-friendly, low-cost raw materials that do not contain heavy metals such as Cd (cadmium) / lead (Pb) and rare earths.

(Fe (ClO 4) 2 .xH ₂ O), glutathione, dimethyl sulfoxide (DMSO), and the like can be used as materials for the production of quantum dots constituting the wavelength conversion nanostructure light emitting source according to the present invention. ) And sodium selenite are used.

Here, as a solution of sodium selenite, for example, 0.414 g (2.4 mmol) of sodium selenite is dissolved in 5 mL of distilled water.

All of the syntheses for the production of the quantum dots constituting the light source of the wavelength converting nanostructure according to the present invention use a Schlrckle line device.

After placing three round neck flasks in a heating mantle (EMA 1000 / CEB1, Barnstead / Electrothermal, Britain), one neck is connected to the condenser and the other two are sealed with membranes and the temperature is controlled by the mantle heating system .

For analysis, high-resolution transmission electron microscopy (HR-TEM) photographs and energy dispersive spectroscopy (EDS) are performed using a JEOL (JEM-3010, Boston, USA) operating at a speed of 200 kV.

As shown in FIG. 3, in order to synthesize a water-soluble Selenium Fe Qd point, a hydrated iron perchlorate (Fe (ClO 4) 2 .xH ₂ O), glutathione, and dimethyl sulfoxide (DMSO) And the mixture is put into a neck flask (S301).

For example 0.066 g (0.26 mmol) of hydrated perchlorate, iron (Fe (ClO4) 2 and xH ₂ O) and 0.32 g (1.04 mmol) of glutathione (glutathione), 40 mL of dimethyl-sulfonic epoxy compound of (Dimethyl sulfoxide (DMSO) ) Into a triangular flask.

Thereafter, the vacuum and nitrogen implantation steps are repeated to prevent oxidation of iron ions (S302).

Next, the temperature is raised to 90 DEG C with fast stuttering, and 10 minutes later, a solution of sodium selenite is injected into the reaction solution with a syringe (S303)

Then, the temperature of the reaction solution was raised to 140 DEG C and the reaction was carried out in a nitrogen atmosphere for 20 hours (S304)

Then, the reaction solution is cooled to room temperature and is centrifuged using isopropanol to purify the quantum dots (S305).

Then, it is dried in a vacuum oven for powder for optical and chemical analysis, and then dispersed in distilled water (S306).

Such a process is an example of producing selenium and tellurium quantum dots, but it is not limited thereto.

And selenium in order to synthesize nano-particles without addition of selenium hwacheol hydrated iron perchlorate in the quantum dot synthesis (Fe (ClO4) 2 and xH ₂ O), a different synthesis procedure is carried out in the same manner.

That is, preferably synthesized by using glutathione, dimethyl sulfoxide (DMSO) and sodium selenite in order to synthesize selenium nanoparticles.

The wavelength converting nanostructure light source according to the present invention and the variable multicolor display device using the same according to the present invention described above emit light of various colors from the same particle by changing the excitation energy based on the characteristic that the emission wavelength varies according to the excitation wavelength .

The present invention is not limited to adjusting the band gap by adjusting the size, but by changing the excitation wavelength, it is possible to change the wavelength of the excitation light source and the excitation light source of the environmentally friendly selenium hexafluoride which emit different colors from the same particle, ) Of selenium nanoparticles are used to emit light of various colors from the same particle when the excitation energy is varied.

As described above, it will be understood that the present invention is implemented in a modified form without departing from the essential characteristics of the present invention.

It is therefore to be understood that the specified embodiments are to be considered in an illustrative rather than a restrictive sense and that the scope of the invention is indicated by the appended claims rather than by the foregoing description and that all such differences falling within the scope of equivalents thereof are intended to be embraced therein It should be interpreted.

10. Light source unit 11. Wavelength conversion unit
12. Light-

Claims (20)

A wavelength variable light source part for controlling a wavelength of light emitted depending on an electric signal applied;
A wavelength converter including a nanostructure that receives near-infrared light transmitted from the wavelength tunable light source unit as excitation light and converts the near-infrared light into emitted light of visible light;
And a light emitting unit for transmitting light of wavelengths of visible light transmitted from the wavelength converting unit to the outside,
The light emitting unit is based on pixelization of a single nano structure, and emits different colors of light by giving different excitation energies to the same particles,
Wherein the wavelength of visible light obtained from the light emitting portion depends on an electrical signal applied to the tunable light source portion. The wavelength tunable light source according to claim 1,
Wherein the wavelength-converted nanostructure light source is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied to light of a plurality of wavelengths corresponding to a plurality of resonators. The wavelength tunable light source according to claim 1,
Wherein the wavelength tunable nanostructure is based on an output wavelength control in which light of a specific wavelength is selected by an electrical signal applied to a wavelength filter unit inside a single resonator. The wavelength tunable light source according to claim 1,
Wherein the wavelength tunable nano structure light emission source is based on an output wavelength control in which light of a specific wavelength is selected by injection of a corresponding electric signal for each mode locking frequency depending on a resonance distance for each wavelength of light resonating in a single resonator . The wavelength converting nanostructure light source according to claim 1, wherein the wavelength converting unit is based on a synthesized nanostructure. The wavelength converting nanostructure light emitting source according to claim 1, wherein the wavelength converting unit is based on synthesized Selenium Fe Qo point. The method according to claim 6, wherein, in order to synthesize the selenium metal quantum dots,
Characterized in that the synthesized using hydrated perchlorate of iron (Fe (ClO4) 2 and xH ₂ O), glutathione (glutathione), dimethyl sulfonic Foxy cargo (Dimethyl sulfoxide (DMSO)), sodium selenite (Sodium selenite) Wavelength conversion nanostructure luminescence source. The wavelength converting nanostructure light emitting source according to claim 1, wherein the wavelength converting unit is based on synthesized selenium nanoparticles. 9. The method for producing selenium nanoparticles according to claim 8,
Wherein the wavelength conversion nanostructure light emitting source is selected from the group consisting of glutathione, dimethyl sulfoxide (DMSO), and sodium selenite. delete A driver for applying an electric signal to control the wavelength of light emitted from the light source;
A wavelength variable light source unit for outputting near-infrared light by controlling a wavelength of light emitted depending on an electric signal applied from the driving unit;
A control unit for selecting a position of the light emitting unit corresponding to the output wavelength of the wavelength variable light source unit and outputting electric signal information to be transmitted to the driving unit;
A wavelength converter including a nanostructure that receives near-infrared light transmitted from the wavelength tunable light source unit as excitation light and converts the near-infrared light into emitted light of visible light;
And a light emitting unit for transmitting light of wavelengths of visible light transmitted from the wavelength converting unit to the outside,
The wavelength of visible light obtained from the light emitting portion depends on an electric signal applied to the wavelength variable light source portion and a plurality of wavelength conversion nanostructure light emitting sources are collected to emit different colors by different electric signals applied to each of the wavelength conversion nanostructure light emitting sources, And the image information is represented by a function of a pixel. The variable multi-color display device using the wavelength converting nanostructure light emitting source. 12. The wavelength variable light source according to claim 11,
Wherein the wavelength converter is based on an output wavelength control in which light of a specific wavelength is selected by an electrical signal applied from light of a plurality of wavelengths corresponding to a plurality of resonators. 12. The wavelength variable light source according to claim 11,
Wherein the wavelength conversion unit is based on an output wavelength control in which light of a specific wavelength is selected by an electric signal applied to a wavelength filter unit in a single resonator. 12. The wavelength variable light source according to claim 11,
Wherein the wavelength tunable nano structure light emission source is based on an output wavelength control in which light of a specific wavelength is selected by injection of a corresponding electric signal for each mode locking frequency depending on a resonance distance for each wavelength of light resonating in a single resonator A variable multi-color display device using the same. 12. The variable-power multi-color display device according to claim 11, wherein the wavelength converter is based on a synthesized nanostructure. 12. The variable-power multi-color display device of claim 11, wherein the wavelength conversion unit is based on synthesized Selenium QrT quantum dots. 17. The method according to claim 16, wherein, in order to synthesize the selenium metal quantum dots,
Characterized in that the synthesized using hydrated perchlorate of iron (Fe (ClO4) 2 and xH ₂ O), glutathione (glutathione), dimethyl sulfonic Foxy cargo (Dimethyl sulfoxide (DMSO)), sodium selenite (Sodium selenite) A variable multi - color display device using a wavelength conversion nanostructure light emitting source. 12. The variable-power multi-color display device according to claim 11, wherein the wavelength conversion unit is based on synthesized selenium nanoparticles. 19. The method according to claim 18, wherein, in order to synthesize selenium nanoparticles,
Wherein the compound is synthesized using glutathione, dimethyl sulfoxide (DMSO), and sodium selenite. 2. The variable-type multi-color display device according to claim 1, 12. The nanostructure light emitting device according to claim 11, wherein the light emitting unit is based on a single nanostructure pixelization, and emits different colors of light by different excitation energies of the same particles. Multi-color display device.

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