WO2010143225A1 - Luminescent powder, method for producing same, luminescent element wherein luminescent powder is used, method for producing said luminescent element, and apparatus for producing luminescent powder - Google Patents

Abstract

Luminescent powder (10) is produced with a first process wherein single-crystal silicon is maintained in a super-critical fluid comprising carbon dioxide and a second process wherein laser light, having an intensity which gives rise to laser ablation where nano-size silicon crystals are dispersed from the single-crystal silicon into the super-critical fluid, is directed onto the single-crystal silicon.  As a result the luminescent powder (10) comprises crystalline silicon (1) which has a spherical form, with silicon oxide (2) covering the outside of the crystalline silicon (1).  The diameter of the crystalline silicon (1) is about 2 nm and the thickness of the silicon oxide (2) is about 2 nm.  Hence, the luminescent powder (10) has a spherical form of diameter about 6 nm.

Description

Luminescent powder, method for producing the same, light emitting element using the luminescent powder, method for producing the light emitting element, and apparatus for producing the luminescent powder

The present invention relates to a luminescent powder, a manufacturing method thereof, a light emitting element using the luminescent powder, a manufacturing method of the light emitting element, and a manufacturing apparatus of the luminescent powder.

Conventionally, a silicon oxide film emitting white light is known (Patent Document 1). This silicon oxide film has a structure in which a light emitting layer A that emits blue light, a light emitting layer B that emits green light, and a light emitting layer C that emits red light are stacked.

Each of the light emitting layers A, B, and C is made of silicon oxide and nanosilicon contained in the silicon oxide. The nanosilicon contained in the light emitting layers A, B, and C has different sizes. More specifically, the nanosilicon included in the light emitting layer A has a size of 1.5 to 2.0 nm, and the nanosilicon included in the light emitting layer B has a size of 2.0 to 2.5 nm. The nanosilicon contained in the light emitting layer C has a size of 2.5 to 3.5 nm.

The silicon oxide film is manufactured by a high frequency sputtering method and a heat treatment. More specifically, the silicon oxide film includes an amorphous silicon oxide film a that is the source of the light emitting layer A, an amorphous silicon oxide film b that is the source of the light emitting layer B, and an amorphous silicon oxide film c that is the source of the light emitting layer C. Are sequentially laminated on a substrate by a high frequency sputtering method, and the laminated body is heat-treated.

In this case, the amorphous silicon oxide films a, b, and c contain different amounts of silicon atoms.

As described above, the silicon oxide film is formed by sequentially laminating the amorphous silicon oxide films a, b, and c having different amounts of silicon atoms, and the light-emitting layers A and B containing nano-silicones having different sizes by heat-treating the laminated bodies. , C is manufactured.
JP 2007-63378 A

However, since the nanosilicon described in Patent Document 1 emits light in any one color of blue, green, and red, there is a problem that it is difficult to produce a luminescent powder that emits white light.

Therefore, the present invention has been made to solve such a problem, and an object thereof is to provide a luminescent powder capable of emitting white light.

Another object of the present invention is to provide a method for producing a luminescent powder capable of emitting white light.

Furthermore, another object of the present invention is to provide a light emitting device using a luminescent powder capable of emitting white light.

Furthermore, another object of the present invention is to provide a method for manufacturing a light emitting device using a luminescent powder capable of emitting white light.

Furthermore, another object of the present invention is to provide an apparatus for producing a luminescent powder capable of emitting white light.

According to this invention, the luminescent powder includes a first step of holding single crystal silicon in a supercritical fluid made of carbon dioxide, and laser ablation in which nano-sized crystal silicon jumps out of the single crystal silicon into the supercritical fluid. Is a luminescent powder produced by performing a second step of irradiating a single crystal silicon with a laser beam having an intensity of generating

Preferably, the luminescent powder is produced by further performing a third step of growing nano-sized crystalline silicon that has jumped into the supercritical fluid for a growth time determined by the pressure of the supercritical fluid. It is.

Preferably, in the third step, the nano-sized crystalline silicon grows for a longer time as the pressure of the supercritical fluid is higher, and grows for a shorter time as the pressure of the supercritical fluid is lower.

In addition, according to the present invention, a method for producing a luminescent powder includes a first step of holding single crystal silicon in a supercritical fluid made of carbon dioxide, and a nanosize crystalline silicon from single crystal silicon to a supercritical fluid. A second step of irradiating the single crystal silicon with a laser beam having an intensity that causes laser ablation to jump out.

Preferably, the method for producing a luminescent powder further includes a third step of growing nano-sized crystalline silicon that has jumped into the supercritical fluid for a growth time determined by the pressure of the supercritical fluid.

Preferably, in the third step, the nano-sized crystalline silicon grows for a longer time as the pressure of the supercritical fluid is higher, and grows for a shorter time as the pressure of the supercritical fluid is lower.

Preferably, the first step includes a first sub-step of putting single crystal silicon into the reaction vessel, a pressure valve and a lubricant which are taken out of a siphon type cylinder and sealed with a swelling-resistant material. A second sub-process for supplying the extracted carbon dioxide to the reaction vessel so as to obtain a pressure at which the supercritical fluid is generated using a pump produced by removing the oil and an oil-free pipe; And a third sub-step of heating the reaction vessel to a temperature that is generated.

Furthermore, according to the present invention, the light emitting element includes a light emitting member and first and second electrodes. The first electrode is formed on one surface of the light emitting member. The second electrode is formed on the other surface of the light emitting member. The light emitting member is made of a plurality of light emitting powders. Each of the plurality of luminescent powders comprises the luminescent powder according to any one of claims 1 to 3.

Preferably, at least one of the first and second electrodes is made of a transparent conductive film.

Preferably, at least one of the first and second electrodes is composed of a plurality of electrode pieces.

Furthermore, according to this invention, the method for manufacturing a light emitting element includes a first step of manufacturing a plurality of light emitting powders, and a light emitting member made of a plurality of light emitting powders by collecting the plurality of light emitting powders. A second step, a third step of bonding the light emitting member to the first electrode formed on the substrate, and a fourth step of forming the second electrode on the light emitting member. The first step includes a first sub-step of holding single crystal silicon in a supercritical fluid made of carbon dioxide, and laser ablation in which nano-sized crystal silicon jumps out of the single crystal silicon into the supercritical fluid. And a second sub-step of irradiating the single crystal silicon with laser light having intensity.

Furthermore, according to this invention, the manufacturing apparatus of luminescent powder is equipped with the reaction container, the generator, and the laser apparatus. The reaction vessel holds single crystal silicon. The generator supplies liquid carbon dioxide to the reaction vessel, and generates a supercritical fluid made of carbon dioxide in the reaction vessel. The laser device irradiates single crystal silicon with laser light having an intensity that causes laser ablation in which nano-sized crystal silicon jumps out of single crystal silicon into a supercritical fluid.

According to the present invention, the luminescent powder is made of luminescent powder produced by laser ablation from single crystal silicon held in a supercritical fluid made of CO ₂ . The luminescent powder emits white fluorescence.

Therefore, according to the present invention, the luminescent powder can emit white light.

It is sectional drawing of the luminescent powder by embodiment of this invention. It is the schematic which shows the structure of the manufacturing apparatus of the luminescent powder by embodiment of this invention. It is process drawing which shows the manufacturing method of the luminescent powder shown in FIG. It is a schematic diagram of the luminescent powder deposited on the substrate. It is an optical microscope image of the several luminescent powder arrange | positioned on the stainless steel board | substrate. It is a figure which shows the analysis result by X-ray small angle scattering. It is a figure which shows the spectrum of a Raman scattering. It is a fluorescence microscope image of the luminescent powder manufactured according to the process shown in FIG. It is another optical microscope image of the several luminescent powder arrange | positioned on the stainless steel board | substrate. It is another fluorescence microscope image of the luminescent powder manufactured according to the process shown in FIG. Fig. 4 is a photoluminescence spectrum of a luminescent powder produced according to the process shown in Fig. 3. It is a figure which shows the pressure dependence of the integrated intensity | strength of an emission spectrum. It is sectional drawing which shows the structure of the light emitting element by embodiment of this invention. It is process drawing which shows the manufacturing method of the light emitting element shown in FIG. It is sectional drawing which shows the structure of the other light emitting element by embodiment of this invention. It is a top view of the electrode seen from the B direction shown in FIG.

Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

FIG. 1 is a cross-sectional view of a luminescent powder according to an embodiment of the present invention. Referring to FIG. 1, luminescent powder 10 according to an embodiment of the present invention includes crystalline silicon 1 and silicon oxide 2. The silicon oxide 2 covers the crystalline silicon 1. Therefore, the luminescent powder 10 has a core / shell structure with the crystalline silicon 1 as a core.

The crystalline silicon 1 is made of single crystal silicon and has a spherical shape. The crystalline silicon 1 has an average particle diameter of about 2 nm. The silicon oxide 2 is made of silicon dioxide (SiO ₂ ) and has an average thickness of about 2 nm. Therefore, the luminescent powder 10 has a spherical shape having a diameter of about 6 nm.

FIG. 2 is a schematic diagram showing a configuration of a luminescent powder manufacturing apparatus according to an embodiment of the present invention. Referring to FIG. 2, the luminescent powder manufacturing apparatus 100 includes a cylinder 20, pipes 21 and 23, a pump 22, a cooler 24, a reaction vessel 25, a laser device 26, a lens 27, and a heater. 28, a thermocouple 29, a temperature detector 30, and a controller 31.

The cylinder 20 is connected to the pump 22 by a pipe 21. The pump 22 is connected to the reaction vessel 25 by a pipe 23. The heater 28 is disposed in contact with the periphery of the reaction vessel 25. This is for heating the supercritical fluid generated in the reaction vessel 25 uniformly. One end of the thermocouple 29 is inserted into the reaction vessel 25 and the other end is connected to the temperature detector 30.

The cylinder 20 has a pressure valve 201 and is a siphon type CO ₂ cylinder. The cylinder 20 stores gaseous carbon dioxide (CO ₂ ). The pipe 21 is an oil-free pipe and supplies CO ₂ stored in the cylinder 20 to the pump 22 via the pressure valve 201. The pressure valve 201 is sealed with a CO ₂ swelling-resistant material (for example, ethylene propylene rubber, nitrile rubber, and chloropyrene rubber).

The pump 22 is manufactured by removing the lubricant. Then, the pump 22 supplies CO ₂ supplied from the cylinder 20 via the pipe 21 into the reaction vessel 25 via the pipe 23. In this case, the pump 22 supplies a supercritical fluid composed of CO ₂ via the CO ₂ piping 23 so that the pressure generated in the reaction vessel 25 within the reaction vessel 25.

The pipe 23 is an oil-free pipe, and supplies CO ₂ from the pump 22 into the reaction vessel 25. Cooler 24, for example, made from the ice, CO ₂ output from the pump 22 to cool the CO ₂ to the temperature at which CO ₂ liquid.

The reaction vessel 25 is sealed with a material having swelling resistance (for example, Teflon (registered trademark), Kalrez, silicon rubber). The reaction vessel 25 has a hollow cylindrical shape and is made of, for example, stainless steel. Moreover, the reaction container 25 has transparent windows, for example, sapphire windows 251 and 252 at both ends in the length direction. The reaction vessel 25 holds a supercritical fluid made of CO ₂ , a silicon lump 40 made of single crystal silicon, and a substrate 50.

The laser device 26 is composed of, for example, an Nd: YAG laser and emits laser light having a wavelength of 532 nm, which is a second harmonic of the Nd: YAG laser. This laser beam is composed of pulsed light having a pulse width of 10 nsec, a repetition frequency of 20 Hz, and a fluence of 19 mJ / cm ² .

The lens 27 condenses the laser light emitted from the laser device 26 and irradiates the silicon lump 40 with the condensed laser light through the sapphire window 252. In this case, the lens 27 condenses the laser light so that the energy per pulse is changed from 19 mJ / pulse to 800 mJ / pulse. The silicon lump 40 is made of, for example, a cube having a side length of 1 cm and has a (111) plane orientation. Further, the substrate 50 is made of, for example, carbon (C) or stainless steel. And the board | substrate 50 is arrange | positioned on the surface opposite to the surface of the silicon lump 40 to which a laser beam is irradiated. This is to obtain a light emitting powder 10 having a small size.

The heater 28 heats the reaction vessel 25 to a temperature at which CO ₂ in the reaction vessel 25 becomes a supercritical fluid in accordance with control from the controller 31. The thermocouple 29 detects an electromotive force due to the temperature of CO ₂ in the reaction vessel 25 and outputs the detected electromotive force to the temperature detector 30.

The temperature detector 30 receives an electromotive force from the thermocouple 29, and detects the temperature T of CO ₂ based on the received electromotive force. Then, the temperature detector 30 outputs the detected temperature T to the controller 31.

The controller 31 receives the temperature T from the temperature detector 30 and, based on the received temperature T, the heater 28 so as to heat the reaction vessel 25 to a temperature Tc at which CO ₂ in the reaction vessel 25 becomes a supercritical fluid. To control.

A method of filling CO ₂ in the reaction vessel 25 in the pressure range of 4.56 MPa to 14.8 MPa will be described. Although not shown in FIG. 2, the manufacturing apparatus 100 includes a pressure gauge for measuring the pressure in the reaction vessel 25 and an on-off valve for releasing CO ₂ in the reaction vessel 25 to the outside. . The cylinder 20, the pipes 21, 23, the pump 22, and the cooling are performed so that the pressure in the reaction vessel 25 becomes higher than the set pressure (= any pressure in the pressure range of 4.56 MPa to 14.8 MPa). CO ₂ is packed into the reaction vessel 25 using the vessel 24. Then, the on-off valve is opened to release CO ₂ to the outside, and the pressure in the reaction vessel 25 is set to the set pressure.

Although not shown in FIG. 2, a high-pressure valve is also used in the path for supplying CO ₂ from the cylinder 20 to the reaction vessel 25. The high-pressure valve (diaphragm type) is connected to the oil-free valve. Become.

In the embodiment of the present invention, the pump 22 supplies CO ₂ into the reaction vessel 25 so that the pressure in the reaction vessel 25 is in the range of 4.56 MPa to 14.8 MPa. The heater 28 heats the reaction container 25 so that the temperature T of CO ₂ in the reaction container 25 is in the range of 40 ° C. to 50 ° C.

The pressure in the reaction vessel 25 is in the range of 4.56 MPa to 14.8 MPa, and the temperature T of CO ₂ in the reaction vessel 25 is not less than the critical temperature of 31 ° C., for example, in the range of 40 ° C. to 50 ° C. If it becomes, the CO ₂ in the reaction vessel 25 becomes a supercritical fluid.

Further, in the manufacturing apparatus 100, the gaseous CO ₂ output from the pump 22 is cooled by the cooler 24 so as to become liquid CO _2. This is because liquid CO ₂ is more gaseous CO 2. _This is because the pressure of CO ₂ in the reaction vessel 25 is easily set to a pressure of 4.56 MPa to 14.8 MPa by the pump 22 because it is easier to pressurize by the pump 22 than ₂ . That is, it is for stably producing a supercritical fluid composed of CO ₂ .

Further, in the manufacturing apparatus 100, as described above, the pump 22 is manufactured by removing the lubricant, since the pipe 21, 23 and the high pressure valve consists of oil-free respective piping and valves, consisting of CO ₂ The supercritical fluid can be stabilized in the reaction vessel 25, and contamination of the manufactured luminescent powder 10 can be suppressed.

Furthermore, in the manufacturing apparatus 100, as described above, since the cylinder 20 is a siphon type CO ₂ cylinder, high-density CO ₂ can be efficiently extracted from the cylinder 20 in a short time.

FIG. 3 is a process diagram showing a manufacturing method of the luminescent powder 10 shown in FIG. Referring to FIG. 3, when the production of luminescent powder 10 is started, silicon lump 40 is installed in reaction vessel 25 (step S1).

The pressure valve 201 supplies gaseous CO ₂ from the cylinder 20 to the pump 22 via the pipe 21, and the pump 22 outputs CO ₂ into the pipe 23. The cooler 24 cools gaseous CO ₂ to liquid CO ₂ . Then, the pump 22 supplies the cooled liquid CO ₂ to the reaction vessel 25 so as to have a pressure at which a supercritical fluid is generated in the reaction vessel 25 (step S2).

Thereafter, the thermocouple 29 detects an electromotive force due to the temperature of CO ₂ in the reaction vessel 25 and outputs the detected electromotive force to the temperature detector 30. The temperature detector 30 detects the temperature T of CO ₂ in the reaction vessel 25 based on the electromotive force received from the thermocouple 29 and outputs the detected temperature T to the controller 31.

The controller 31 controls the heater 28 so that the temperature T received from the temperature detector 30 becomes the temperature Tc at which a supercritical fluid made of CO ₂ is generated. Then, the heater 28 heats the reaction vessel 25 so that the temperature T becomes the temperature Tc (step S3).

Subsequently, the laser device 26 irradiates the silicon block 40 with a laser beam having an intensity (= 800 mJ / pulse) at which laser ablation occurs (step S4). In this case, the laser beam irradiation time is about 5 to 10 minutes. Further, the laser device 26 irradiates the silicon lump 40 with laser light for about 40 seconds, and then irradiates the silicon lump 40 with laser light for about 40 seconds after shifting the irradiation position by several mm. repeat. Further, the irradiation position of the laser beam in the silicon lump 40 may be changed by fixing the incident position of the laser beam incident on the reaction vessel 25 and rotating or moving the silicon lump 40 as a target. Thus, by irradiating the silicon lump 40 with the laser light while changing the irradiation place of the laser light, many light emitting powders 10 can be manufactured about four times.

As a result, laser ablation occurs, and nano-sized crystalline silicon jumps out of the silicon mass 40 into the supercritical fluid (= CO ₂ ).

When the laser beam irradiation time is 10 minutes, the laser device 26 stops the laser beam irradiation (step S5).

Thereafter, nano products are grown in the reaction vessel 25 for the growth time determined by the pressure in the reaction vessel 25 (step S6). Due to this growth, crystalline silicon that has jumped into the supercritical fluid is cooled by supercritical CO ₂ at the nanosecond to picosecond term scale immediately after laser light irradiation, and emits light while moving downward in the supercritical fluid. The luminescent powder 10 is deposited on the substrate 50. During these periods, the reaction vessel 25 is controlled by the controller 31 so as to have the same temperature.

The growth time is 4 to 10 minutes when the pressure in the reaction vessel 25 is 4.56 MPa, and 1 hour when the pressure in the reaction vessel 25 is 11.0 MPa. When the internal pressure is 14.8 MPa, it is 2 hours. These times were determined based on the calculated time for 100 nm particles to sink by 1 cm.

Thus, the growth time is set to a longer time as the pressure of the supercritical fluid made of CO ₂ is higher, and is set to a shorter time as the pressure of the supercritical fluid made of CO ₂ is lower.

Then, when the growth time has elapsed, the production of the luminescent powder 10 is finished.

As described above, in the embodiment of the present invention, after the irradiation with the laser beam is stopped, the growth time determined by the pressure of the supercritical fluid is generated by the CO ₂ in the reaction vessel 25 and the laser ablation. The crystalline silicon is cooled and the luminescent powder 10 is deposited on the substrate 50.

In the process shown in FIG. 3, it has been described that the laser device 26 condenses the laser light by the lens 27 and irradiates the silicon lump 40 with the laser light having an intensity of 800 mJ / pulse. In the embodiment, the laser device 26 is not limited to this, and the laser device 26 uses laser light having an intensity of 200 mJ / pulse or more, which is a critical intensity at which laser ablation occurs in which nano-sized crystalline silicon jumps out of the silicon mass 40 into the supercritical fluid. What is necessary is just to irradiate the silicon lump 40 via 27.

FIG. 4 is a schematic diagram of the luminescent powder 10 deposited on the substrate 50. FIG. 4 is an enlarged view of a part of the plurality of luminescent powders 10 deposited on the substrate 50.

Referring to FIG. 4, the luminescent powder 10 is deposited on the substrate 50 so as to form a network structure (shaded portion in FIG. 4).

FIG. 5 is an optical microscope image of a plurality of luminescent powders arranged on a stainless steel substrate. FIG. 5 is an optical microscope image (bright field image) when a plurality of luminescent powders 10 constituting the network structure shown in FIG. 4 are collected and arranged on a stainless steel substrate. The bright field image was measured with a microscope with a high-sensitivity color CCD camera at normal temperature and normal pressure by irradiating a halogen lamp with epi-illumination.

Referring to FIG. 5, it can be seen that a plurality of minute grains are shown.

A plurality of luminescent powders 10 forming a network structure were collected and analyzed by EPMA (Electron Probe Micro Analyzer).

As a result of analyzing the aggregate of the plurality of luminescent powders 10 by EPMA, silicon (Si) and oxygen (O) were detected at a composition ratio of about 1: 2. Thus, the surface side of the light emitting powder 10 was found to be composed of SiO _2.

Further, as a result of measuring photoluminescence of an assembly of a plurality of luminescent powders 10 immersed in HF, Si luminescence was detected. Therefore, it has been found that the central portion of the luminescent powder 10 is made of Si. The hydrofluoric acid treatment of the luminescent powder 10 was performed by immersing the luminescent powder 10 in 30% HF for several hours.

This EPMA analysis and photoluminescence measurement results demonstrated that the luminescent powder 10 has a core / shell structure with Si as the core and SiO ₂ as the shell as described above.

Next, the aggregate of the plurality of luminescent powders 10 was analyzed by X-ray small angle scattering (SAXS: Small Angle X-ray Scattering).

FIG. 6 is a diagram showing an analysis result by small-angle X-ray scattering. X-ray small angle scattering was measured using CuKα rays having a wavelength of 1.5 mm.

In FIG. 6, the horizontal axis represents size, and the vertical axis represents abundance. Curve k1 shows the analysis result by X-ray small angle scattering of the luminescent powder 10 manufactured by setting the pressure of the supercritical fluid made of CO ₂ to 4.56 MPa. Furthermore, a curve k2 shows the analysis result by X-ray small angle scattering of the luminescent powder 10 manufactured by setting the pressure of the supercritical fluid made of CO ₂ to 10.4 MPa. Furthermore, the curve k3 shows a typical spectrum of X-ray small angle scattering.

Referring to FIG. 6, by setting the light emitting powder 10 was prepared by setting the pressure of the supercritical fluid consisting CO ₂ to 4.56MPa, and the pressure of the supercritical fluid consisting CO ₂ to 10.4MPa production Both of the luminescent powders 10 have a size in the range of about 0.5 nm to about 100 nm and are most distributed in a size of about 6 nm (see curves k1 and k2).

Combining this size distribution with the X-ray small angle scattering analysis results described above, it was found that the luminescent powder 10 was composed of Si having a diameter of about 2 nm and SiO ₂ having a thickness of about 2 nm. .

FIG. 7 is a diagram showing a spectrum of Raman scattering. In FIG. 7, the horizontal axis represents Raman shift, and the vertical axis represents intensity. A curve k4 shows the Raman scattering spectrum of the luminescent powder 10 produced by setting the pressure of the supercritical fluid made of CO ₂ to 4.56 MPa. Furthermore, the curve k5 shows the spectrum of Raman scattering of the luminescent powder 10 produced by setting the pressure of the supercritical fluid made of CO ₂ to 10.4 MPa. Furthermore, the curve k6 shows the spectrum of Raman scattering of the luminescent powder 10 produced by setting the pressure of the supercritical fluid made of CO ₂ to 14.8 MPa. Furthermore, the curve k7 shows the spectrum of Raman scattering of single crystal silicon. Furthermore, the curve k8 shows the spectrum of Raman scattering of amorphous silicon.

Referring to FIG. 7, in the luminescent powder 10, a sharp peak of Raman shift was observed at 520 cm ⁻¹ regardless of the pressure of the supercritical fluid (consisting of CO ₂ ) at the time of manufacture (see curves k4 to k6). ). This is the same as the peak of Raman shift (520 cm ⁻¹ ) of single crystal silicon (see curve k7), which is completely different from the Raman shift of amorphous silicon (see curve k8).

Therefore, it was found that the luminescent powder 10 had a core made of single crystal silicon.

FIG. 8 is a fluorescence microscope image of the luminescent powder 10 produced according to the process shown in FIG. In addition, the excitation wavelength of the luminescent powder 10 when a fluorescent microscope image is taken is 325 nm, and the intensity of the excitation light is 20 mW. Moreover, the fluorescence microscope image was image | photographed under normal temperature and normal pressure.

Referring to FIG. 8, it is understood that the luminescent powder 10 emits white light blue as a whole and emits white light in the region indicated by the arrow A.

FIG. 9 is another optical microscope image of a plurality of luminescent powders arranged on a stainless steel substrate. The optical microscope image was taken under the same shooting conditions as those of the optical microscope image shown in FIG. Referring to FIG. 9, a product composed of a plurality of luminescent powders 10 is generated. And a product has a projection part.

FIG. 10 is another fluorescence microscopic image of the luminescent powder 10 manufactured according to the process shown in FIG. In addition, the excitation wavelength of the luminescent powder 10 when a fluorescent microscope image is taken is 325 nm, and the intensity of the excitation light is 20 mW. Moreover, the fluorescence microscope image was image | photographed under normal temperature and normal pressure.

Referring to FIG. 10, the same region as shown in FIG. 9 emits light in white or light blue. The region shown in FIGS. 9 and 10 is wider than the region shown in FIGS. 5 and 8 and has a size of several hundred μm.

Therefore, it was confirmed that the aggregate of the plurality of luminescent powders 10 totally emitted light in the region of several hundred μm.

Thus, it was demonstrated that the luminescent powder 10 produced by laser ablation from the silicon mass 40 in a supercritical fluid made of CO ₂ emits light blue or white light.

FIG. 11 is a photoluminescence spectrum of the luminescent powder 10 produced according to the process shown in FIG. In FIG. 11, the horizontal axis represents wavelength (or energy), and the vertical axis represents intensity.

The excitation wavelength of the luminescent powder 10 when measuring photoluminescence is 325 nm, and the intensity of the excitation light is 2 mW. In the photoluminescence measurement, a laser beam having a wavelength of 325 nm is irradiated onto the sample by epi-illumination (the intensity of the excitation light immediately before the sample is several tens of μW), and light emitted from the sample is collected by an ultraviolet-compatible objective lens. Then, the wavelength was dispersed by a single-type spectrometer, and the spectrum was measured by a CCD camera. As for the spectrum, an instrument function is obtained based on an intensity-corrected light source compliant with the National Institute of Standards and Technology (NIST), and the spectral sensitivity characteristic is calibrated using the device function. The measurement was performed at normal temperature and normal pressure.

Further, FIG. 11, to set the pressure of the supercritical fluid consisting CO ₂ to 7.5 MPa, and the temperature of the supercritical fluid consisting CO ₂ to 322.4K (= 49.4 ℃) emitting powder 10 is a spectrum of photoluminescence measured after 4 days have passed after the produced luminescent powder 10 is taken out into the atmosphere.

Referring to FIG. 11, it was found that the luminescent powder 10 had an emission spectrum in a wavelength range of 350 nm or more. That is, it has an emission spectrum in a wavelength range including the wavelengths of blue, green and red, which are the three primary colors.

This emission spectrum supports that the fluorescence microscope image shown in FIG. 8 is white.

FIG. 12 is a diagram showing the pressure dependence of the integrated intensity of the emission spectrum. In FIG. 12, the horizontal axis represents the pressure of the supercritical fluid at the time of manufacturing the luminescent powder 10, and the vertical axis represents the integrated intensity. Curve k9 shows the pressure dependence of the integrated intensity of the emission spectrum 40 minutes after producing the luminescent powder 10, and curve k10 shows the emission spectrum two days after producing the luminescent powder 10. The pressure dependence of the integrated intensity is shown, and the curve k11 shows the pressure dependence of the integrated intensity of the emission spectrum two months after the luminescent powder 10 is manufactured.

Referring to FIG. 12, the integrated intensity of the emission spectrum after 40 minutes from the production of the luminescent powder 10 is substantially constant with respect to the pressure of the supercritical fluid (see curve k9).

On the other hand, the integrated intensity of the emission spectrum after 2 days from the production of the luminescent powder 10 and the integrated intensity of the emission spectrum after 2 months from the production of the luminescent powder 10 are 4.56 MPa to 14.8 MPa. In the pressure range increases as the pressure of the supercritical fluid increases (see curves k10 and k11).

The luminous powder 10 after two months from the production of the luminous powder 10 has a maximum luminous intensity (integrated intensity) of about 100 times (see curves k9 and k11).

Therefore, the emission intensity can be controlled by controlling the pressure of the supercritical fluid when the luminescent powder 10 is manufactured.

Also, at each pressure, the emission intensity (integrated intensity) of the luminescent powder 10 becomes stronger as the elapsed time after the luminescent powder 10 is manufactured becomes longer (see curves k9 to k11).

Therefore, it has been found that the luminescent powder 10 manufactured according to the process shown in FIG. 3 does not deteriorate with the elapsed time since it was manufactured.

In the process shown in FIG. 3 described above, steps S1 to S3 constitute a “first process” for holding single crystal silicon in a supercritical fluid made of carbon dioxide.

Further, in step S4 described above, by irradiating the silicon lump 40 made of single crystal silicon with laser light having an intensity that causes laser ablation, the nano-sized crystalline silicon jumps out of the silicon lump 40 into the supercritical fluid. Step S4 constitutes a “second step” of irradiating the single crystal silicon with a laser beam having an intensity that causes laser ablation in which nano-sized crystal silicon jumps out of the single crystal silicon into the supercritical fluid.

Then, the crystalline silicon jumps out of the silicon lump 40 into the supercritical fluid by laser ablation, and the luminescent powder 10 is manufactured if the jumped crystalline silicon is cooled for an arbitrary time. Even if the sample is taken out before the time elapses, the luminescent powder 10 can be obtained. Therefore, the luminescent powder according to the embodiment of the present invention only needs to be manufactured by the first and second steps described above.

FIG. 13 is a cross-sectional view showing the configuration of the light emitting device according to the embodiment of the present invention. Referring to FIG. 13, a light emitting device 200 according to an embodiment of the present invention includes a transparent substrate 210, a transparent conductive film 220, a conductive polymer 230, a light emitting member 240, and an electrode 250.

The transparent substrate 210 is made of a film or glass. The transparent conductive film 220 is made of any material for flexible displays such as ITO (Indium Tin Oxide), SnO ₂ , ZnO, and organic EL (Electro Luminescence), and is formed around the transparent substrate 210.

The conductive polymer 230 is made of any one of polyacetylene, polyparaphenylene, polyaniline, polythiophene, and polyparaphenylene vinylene. The conductive polymer 230 is disposed between the transparent conductive film 220 and the light emitting member 240 in contact with the transparent conductive film 220 and the light emitting member 240.

In order to increase the carrier mobility and effectively use the voltage applied to the electrode, the conductive polymer 230 is made of a material having a low relative dielectric constant.

The light emitting member 240 is composed of a plurality of laminated light emitting powders 10. The light emitting member 240 is disposed between the conductive polymer 230 and the electrode 250 in contact with the conductive polymer 230 and the electrode 250.

The electrode 250 is made of, for example, gold (Au), and is formed on the light emitting member 240 in contact with the light emitting member 240. Further, the electrode 250 may be made of an alloy material (Ca / Ag) and an Mg-based metal, or may be made of a nano metal aggregate.

In the light emitting element 200, when a voltage is applied between the transparent conductive film 220 and the electrode 250, electrons and holes are injected into the light emitting powder 10 of the light emitting member 240 and the light emitting member 240 emits light. In this case, electrons and holes are injected into the crystalline silicon 1 through the silicon oxide (SiO ₂ ) 2 having a thickness of about 2 nm of the luminescent powder 10. Further, in the region where the two luminescent powders 10 are in contact, electrons and holes tunnel through the silicon oxide (SiO ₂ ) 2 having a thickness of about 2 nm of the luminescent powder 10 and from one luminescent powder 10 to the other. The luminescent powder 10 flows. Therefore, even if the luminescent powder 10 is laminated, electrons and holes can be injected into the laminated luminescent powder 10.

The light emitting element 200 emits white light when a voltage of 3.82 V is applied between the transparent conductive film 220 and the electrode 250, and a voltage of 3.3 V is generated between the transparent conductive film 220 and the electrode 250. When the voltage is applied to the transparent conductive film 220, the light is emitted in blue, and when a voltage of 2.7 V is applied between the transparent conductive film 220 and the electrode 250, the light is emitted in green, and a voltage of 2.41 V is applied to the transparent conductive film 220 and the electrode. When it is applied to 250, it emits red light.

Note that these voltage values are minimum voltage values, and shift to the high voltage side when the energy gap at the interface between the crystalline silicon 1 and the silicon oxide 2 acts.

Thus, by controlling the voltage applied between the transparent conductive film 220 and the electrode 250, the light emitting element 200 can emit light in different colors.

FIG. 14 is a process diagram showing a method of manufacturing the light emitting device 200 shown in FIG. Referring to FIG. 14, when the manufacture of light emitting element 200 is started, a plurality of light emitting powders 10 are manufactured according to the process shown in FIG. 3 (step S11).

Then, a plurality of luminescent powders 10 are collected and a light emitting member 240 made of the plurality of luminescent powders 10 is manufactured (step S12).

Subsequently, the light emitting member 240 is bonded to the transparent conductive film 220 by the conductive polymer 230 (step S13).

Then, the electrode 250 is formed on the light emitting member 240 by any of sputtering, vapor deposition, and ink jet method (step S14). Thereby, the light emitting element 200 is completed.

In the light emitting element 200, the electrode 250 may be made of a transparent conductive film such as ITO.

The light emitting element 200 may include an n-type or p-type silicon wafer having a carrier concentration of 10 ²⁰ cm ⁻³ or more instead of the transparent substrate 210 and the transparent conductive film 220. instead of the membrane 220, the carrier concentration with a is ¹⁰ 20 ^{cm -3} or more n-type or p-type silicon wafer, and, in place of the electrode 250, the carrier concentration is ¹⁰ 20 ^{cm -3} or more pn-type or n-type The silicon wafer may be provided. In this case, the emitted light is emitted in the lateral direction of the light emitting element 200.

FIG. 15 is a cross-sectional view showing the configuration of another light emitting device according to the embodiment of the present invention. The light emitting device according to the embodiment of the present invention may be a light emitting device 200A shown in FIG.

Referring to FIG. 15, a light emitting element 200A is the same as light emitting element 200 except that electrode 250 of light emitting element 200 shown in FIG.

The electrode 260 is made of, for example, Au, and is formed on the light emitting member 240 in contact with the light emitting member 240.

FIG. 16 is a plan view of the electrode 260 viewed from the direction B shown in FIG. Referring to FIG. 16, electrode 260 includes electrode pieces 261-264.

Different voltages are applied to the electrode pieces 261 to 264. For example, a voltage of 3.82 V is applied to the electrode piece 261, a voltage of 3.3 V is applied to the electrode piece 262, a voltage of 2.7 V is applied to the electrode piece 263, and the voltage of the electrode piece 264 is 2 A voltage of .41V is applied.

As a result, the region of the light emitting member 240 in contact with the electrode piece 261 emits white light, the region of the light emitting member 240 in contact with the electrode piece 262 emits blue light, and the region of the light emitting member 240 in contact with the electrode piece 263 is green. The region of the light emitting member 240 that emits light and contacts the electrode piece 264 emits red light.

Thus, the light emitting element 200A is a light emitting element that simultaneously emits white light, blue light, green light, and red light.

The light emitting element 200A is manufactured according to a process of adding a step of patterning the electrode 260 into electrode pieces 261 to 264 by photolithography after step S14 shown in FIG.

Further, in the light emitting element 200A, the electrode 250 may be made of a transparent conductive film such as ITO.

Further, the light emitting element 200A may include an n-type or p-type silicon wafer having a carrier concentration of 10 ²⁰ cm ⁻³ or more, instead of the transparent substrate 210 and the transparent conductive film 220. In this case, the emitted light is emitted in the lateral direction of the light emitting element 200A.

Furthermore, in the light emitting element 200A, the transparent conductive film 220 may be patterned in the same manner as the electrode 260. In general, in the light emitting element 200A, at least one of the two electrodes disposed on both sides of the light emitting member 240 may be patterned into a plurality of electrode pieces.

The light emitting elements 200 and 200A described above are applied to lighting devices and display devices. The luminescence lifetime of silicon nanomaterials is assumed to be on the order of microseconds (in some cases on the order of nanoseconds or picoseconds), considering its size. Therefore, by using the switching circuit, the light emission / flashing becomes quick and the electric follow-up property is good. As a result, the light emitting elements 200 and 200A are more suitable for a moving image display than a liquid crystal display device.

Further, the luminescent powder 10 can be applied to an element for photoluminescence (PL). In the conventional fluorescent lamp, mercury is enclosed, and rare earth elements such as eurobium (Eu) and terbium (Tb) are excited by ultraviolet light of the enclosed mercury, and light of three primary colors is mixed to form a white fluorescent lamp. Therefore, when the above-described luminescent powder 10 is used in a fluorescent lamp, it can be used as a substitute for rare earth elements and a white fluorescent lamp can be realized by ultraviolet irradiation. The luminescent powder 10 can also be applied to a plasma display.

In the device structure, the luminescent powder 10 is mixed with the ultraviolet transmissive polymer by mixing the luminescent powder 10 with the ultraviolet transmissive polymer together with the solvent, coating the solution on the inner wall of the glass, and then removing the solvent. The structure is solidified on the glass surface. The glass to be solidified may be any material as long as it is a transparent material, and the shape may be either a flat surface or a curved surface. Then, light is emitted from the inside by mercury discharge or rare gas discharge.

In the above description, it has been described that the reaction vessel 25 holds the silicon lump 40. However, in the embodiment of the present invention, the reaction vessel 25 may hold a silicon wafer. In this case, the silicon wafer is held in the reaction vessel 25 so that the surface thereof is substantially perpendicular to the laser beam.

In the embodiment of the present invention, the pump 22, the cooler 24, the heater 28, the thermocouple 29, the temperature detector 30 and the controller 31 generate a supercritical fluid made of CO ₂ in the reaction vessel 25. Configure the “generator”.

The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and is intended to include meanings equivalent to the scope of claims for patent and all modifications within the scope.

The present invention is applied to a luminescent powder capable of emitting white light. The present invention is also applied to a method for producing a luminescent powder capable of emitting white light. Furthermore, the present invention is applied to a light emitting element using a luminescent powder capable of emitting white light. Furthermore, the present invention is applied to a method for manufacturing a light-emitting element using a luminescent powder capable of emitting white light. Further, the present invention is applied to an apparatus for producing a luminescent powder capable of emitting white light.

Claims (12)

1. A first step of holding single crystal silicon (40) in a supercritical fluid comprising carbon dioxide;
   A second step of irradiating the single crystal silicon (40) with a laser beam having an intensity that causes laser ablation in which the nano-sized crystal silicon (1) jumps out of the single crystal silicon (40) into the supercritical fluid; Luminescent powder produced by execution.
2. 2. The method according to claim 1, further comprising performing a third step of growing the nano-sized crystalline silicon (1) jumping into the supercritical fluid for a growth time determined by the pressure of the supercritical fluid. The luminescent powder described.
3. In the third step, the nano-sized crystalline silicon (1) grows for a longer time as the pressure of the supercritical fluid is higher, and grows for a shorter time as the pressure of the supercritical fluid is lower. The luminescent powder according to claim 2.
4. A first step of holding single crystal silicon (40) in a supercritical fluid comprising carbon dioxide;
   A second step of irradiating the single crystal silicon (40) with a laser beam having an intensity that causes laser ablation in which the nano-sized crystal silicon (1) jumps out of the single crystal silicon (40) into the supercritical fluid; A method for producing a luminescent powder.
5. The luminescent powder according to claim 4, further comprising a third step of growing the nano-sized crystalline silicon (1) jumping into the supercritical fluid for a growth time determined by the pressure of the supercritical fluid. Manufacturing method.
6. In the third step, the nano-sized crystalline silicon (1) grows for a longer time as the pressure of the supercritical fluid is higher, and grows for a shorter time as the pressure of the supercritical fluid is lower. The method for producing a luminescent powder according to claim 5.
7. The first step includes
   A first sub-step of placing said single crystal silicon (40) into a reaction vessel (25);
   The carbon dioxide is taken out of the siphon type cylinder, the pressure valve (201) sealed with a material having swelling resistance, the pump (20) prepared by removing the lubricant, and the oil-free pipes (21, 23) A second sub-step of supplying the extracted carbon dioxide to the reaction vessel (25) so that the pressure at which the supercritical fluid is generated using
   The method for producing a luminescent powder according to claim 4, further comprising a third sub-step of heating the reaction vessel (25) so as to reach a temperature at which the supercritical fluid is generated.
8. A light emitting member (240);
   A first electrode (220) formed on one surface of the light emitting member (240);
   A second electrode (250) formed on the other surface of the light emitting member (240),
   The light emitting member (240) is composed of a plurality of light emitting powders (10),
   Each of these light emitting powders (10) is a light emitting element which consists of luminescent powder of any one of Claims 1-3.
9. The light emitting device according to claim 8, wherein at least one of the first and second electrodes is made of a transparent conductive film.
10. The light emitting device according to claim 8, wherein at least one of the first and second electrodes is composed of a plurality of electrode pieces (261 to 264).
11. A first step of producing a plurality of luminescent powders (10);
    A second step of collecting the plurality of luminescent powders (10) to produce a light emitting member (240) comprising the plurality of luminescent powders (10);
    A third step of bonding the light emitting member (240) to the first electrode (220) formed on the substrate (210);
    And a fourth step of forming a second electrode (250) on the light emitting member (240),
    The first step includes
    A first sub-step of holding single crystal silicon (40) in a supercritical fluid consisting of carbon dioxide;
    A second sub-step of irradiating the single crystal silicon (40) with a laser beam having an intensity that causes laser ablation in which nano-sized crystal silicon (1) jumps out of the single crystal silicon (40) into the supercritical fluid; A method for manufacturing a light emitting device, comprising:
12. A reaction vessel (25) holding single crystal silicon (40);
    A generator (22, 24, 28, 29, 30, 31) for supplying liquid carbon dioxide to the reaction vessel (25) and generating a supercritical fluid composed of the carbon dioxide in the reaction vessel (25); ,
    A laser device (26) for irradiating the single crystal silicon (40) with laser light having an intensity that causes laser ablation in which nano-sized crystalline silicon (1) jumps out of the single crystal silicon (40) into the supercritical fluid; A luminescent powder production apparatus comprising:

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