KR101196845B1 - Halo-Metalnitridosilicate phosphor and Synthesis method thereof - Google Patents
Halo-Metalnitridosilicate phosphor and Synthesis method thereof Download PDFInfo
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- KR101196845B1 KR101196845B1 KR1020100098914A KR20100098914A KR101196845B1 KR 101196845 B1 KR101196845 B1 KR 101196845B1 KR 1020100098914 A KR1020100098914 A KR 1020100098914A KR 20100098914 A KR20100098914 A KR 20100098914A KR 101196845 B1 KR101196845 B1 KR 101196845B1
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- South Korea
- Prior art keywords
- srco
- phosphor
- halo
- silicon oxynitride
- metal
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- OAICVXFJPJFONN-UHFFFAOYSA-N Phosphorus Chemical compound [P] OAICVXFJPJFONN-UHFFFAOYSA-N 0.000 title claims abstract description 75
- 238000001308 synthesis method Methods 0.000 title 1
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- 239000010703 silicon Substances 0.000 claims abstract description 21
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- 150000003624 transition metals Chemical class 0.000 claims abstract description 11
- 229910052783 alkali metal Inorganic materials 0.000 claims abstract description 10
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- 239000000126 substance Substances 0.000 claims description 4
- 150000002602 lanthanoids Chemical group 0.000 claims description 2
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- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09K—MATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
- C09K11/00—Luminescent, e.g. electroluminescent, chemiluminescent materials
- C09K11/08—Luminescent, e.g. electroluminescent, chemiluminescent materials containing inorganic luminescent materials
- C09K11/77—Luminescent, e.g. electroluminescent, chemiluminescent materials containing inorganic luminescent materials containing rare earth metals
- C09K11/7728—Luminescent, e.g. electroluminescent, chemiluminescent materials containing inorganic luminescent materials containing rare earth metals containing europium
- C09K11/77347—Silicon Nitrides or Silicon Oxynitrides
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L33/00—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L33/48—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by the semiconductor body packages
- H01L33/50—Wavelength conversion elements
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- Chemical & Material Sciences (AREA)
- Inorganic Chemistry (AREA)
- Engineering & Computer Science (AREA)
- Materials Engineering (AREA)
- Organic Chemistry (AREA)
- Luminescent Compositions (AREA)
- Electroluminescent Light Sources (AREA)
Abstract
본 발명은 (할로)금속실리콘산질화물 형광체 및 이의 제조방법에 관한 것으로서, 더욱 상세하게는 SrSi2O2N2:Eu2 + 형광체에 다양한 형태의 알칼리금속, 알칼리토금속, 전이금속 등을 치환 또는 첨가한 (할로)금속실리콘산질화물 형광체 및 이를 상압에서 고상법에 의해 제조하는 방법에 관한 것이다. 본 발명의 (할로)금속실리콘산질화물 형광체는 자외선 또는 청색의 여기원에 의해 황색계 영역에서 발광피크를 가지며, 발광 휘도 및 열적 안정성이 우수하므로 발광다이오드, 레이저다이오드, 면발광 레이저다이오드, 무기 일렉트로루미네센스 소자, 또는 유기 일렉트로루미네센스 소자와 같은 발광 소자에 유용하게 적용할 수 있다.The present invention relates to a (halo) metal silicon oxynitride phosphor and a method for manufacturing the same, and more particularly, to various types of alkali metals, alkaline earth metals, transition metals, etc., to SrSi 2 O 2 N 2 : Eu 2 + phosphors. It relates to a (halo) metal silicon oxynitride phosphor added and a method for producing the same by a solid phase method at normal pressure. The (halo) metal silicon oxynitride phosphor of the present invention has a light emission peak in a yellow region by ultraviolet or blue excitation source, and has excellent light emission luminance and thermal stability, so that a light emitting diode, a laser diode, a surface emitting laser diode, an inorganic electro The present invention can be usefully applied to a light emitting device such as a luminescence device or an organic electroluminescent device.
Description
본 발명은 발광 다이오드, 레이저 다이오드 등의 발광 소자에 적용 가능한 (할로)금속실리콘산질화물 형광체 및 이의 제조방법에 관한 것이다.
The present invention relates to a (halo) metal silicon oxynitride phosphor applicable to light emitting devices such as light emitting diodes, laser diodes and the like and a method of manufacturing the same.
백색 발광 다이오드(Light Emission Diode, LED)는 차세대 발광 소자 중 하나로서, 종래 광원보다 소비전력이 적으며, 높은 발광효율, 고휘도, 빠른 응답속도 등의 장점이 있어 세계적으로 연구가 활발히 진행되고 있다.White light emitting diodes (LEDs) are one of the next generation light emitting devices, which consume less power than conventional light sources, and are actively researched around the world due to advantages such as high luminous efficiency, high brightness, and fast response speed.
백색 발광 다이오드를 제작하는 기술에는 크게 3가지가 있다.There are three major techniques for manufacturing white light emitting diodes.
첫째, 한 패키지에 적색, 청색 및 녹색 발광 다이오드 칩들을 실장하고 각각의 칩을 제어하여 백색 발광 소자를 제작하는 기술, 둘째, 자외선 발광 다이오드 칩에 적색, 청색 및 녹색 발광 특성을 갖는 형광체를 도포하여 백색 발광 소자를 만드는 기술, 및 셋째, 청색 발광 다이오드 칩에 황색 발광 특성을 갖는 형광체를 도포하여 백색 발광 소자를 만드는 기술이다.First, red, blue, and green LED chips are mounted in one package, and each chip is controlled to manufacture a white light emitting device. Second, a UV light emitting diode chip is coated with phosphors having red, blue, and green light emitting characteristics. A technique of making a white light emitting device, and third, a technique of making a white light emitting device by applying a phosphor having yellow light emitting characteristics to a blue light emitting diode chip.
이러한 종래의 기술 중, 적색, 청색 및 녹색 발광 다이오드 칩을 각각 사용한 백색 발광 소자는 동작 전압이 불균일하고 주변 온도에 따라 각각의 칩의 출력이 변하여 색 좌표가 달라지기 때문에 각각의 색을 균일하게 혼합하는 것에 어려움이 있어 순수 백색광을 얻기가 힘들었다. 또한, 각각의 칩 또는 발광 다이오드에 관한 전기적 특성들을 고려한 별도의 동작 회로가 필요하고, 이를 제어해야 하기 때문에 제조과정이 복잡할 뿐 아니라 고휘도 백색광을 구현하기에는 소비전력의 측면에서 비효율적이었다.Among these conventional technologies, the white light emitting device using the red, blue and green LED chips, respectively, uniformly mixes each color because the operating voltage is uneven and the output of each chip changes according to the ambient temperature and the color coordinates are different. It was hard to get pure white light. In addition, since a separate operation circuit considering the electrical characteristics of each chip or light emitting diode is required and controlled, it is not only complicated in the manufacturing process but also inefficient in terms of power consumption to implement high-intensity white light.
상기와 같은 문제점을 보완하기 위하여, 현재 생산업체들은 자외선 발광 다이오드 칩에 적색, 청색 및 녹색 발광 특성을 갖는 형광체들이 일정한 비율로 혼합된 형광체를 도포하거나, 청색 발광 다이오드 칩에 황색 발광 특성을 갖는 형광체를 도포함으로써 백색 발광 소자를 제조하고 있다. 이러한 방법은 상기 적색, 청색 및 녹색 발광 다이오드 칩을 각각 이용하는 방법보다 공정이 단순하고, 경제적인 장점이 있고, 형광체의 발광되는 빛을 이용하여 가변혼색이 가능하기 때문에 색 좌표를 맞추기가 용이하고 다양한 색 구현이 가능한 장점이 있다.In order to solve the above problems, current manufacturers apply phosphors in which red, blue, and green light emitting phosphors are mixed in a constant ratio on an ultraviolet light emitting diode chip, or yellow phosphors on a blue light emitting diode chip. The white light emitting element is manufactured by apply | coating. This method is simpler than the method of using the red, blue, and green LED chips, and has an economical advantage, and is easy to adjust color coordinates because variable mixing is possible using light emitted from a phosphor. Color has the advantage of being possible.
대한민국 등록특허 제 10-0456430 호, 제 10-0628884 호, 제 10-0448416 호 등에서는 주로 460 nm 영역에서 청색으로 발광하는 갈륨나이트라이드(GaN) LED칩과 황색으로 발광하는 YAG : Ce3+ (Yttrium Aluminum Garnet) 형광체를 이용하여 백색을 구현하고자 하였다. 그러나, YAG계의 발광 형광체는 발광 파장의 특성상 적색 영역의 발광강도가 상대적으로 약해 우수한 연색 특성을 얻기가 어려우며 색 온도에 민감하므로, 조명 및 LCD 칼라 배경 광원으로는 적합하지 못한 문제가 있다. 또한, 녹색 발광 실리케이트계 형광체를 이용하여 발광 소자를 구현할 수도 있는데, 보통 Eu2+ 이온을 활성제로 사용하고 A2SiO4:Eu2+의 화학식을 갖는 녹색 형광체가 사용된다.(상기 화학식의 "A"는 "Sr", "Ba", "Ca", "Mg" 등의 2종 이상의 화합물을 의미한다.) 그러나, 종래의 녹색 발광 형광체의 경우 열처리 과정에서 잔유물이 많이 생성되고 형광 입자가 불규칙한 크기로 합성되는 등 불균일한 모폴로지(Mophology)로 인하여 휘도가 저하되는 문제점이 있으며, 종래 사용되는 화합물의 종류, 열처리 환경에서 이온이 도핑되는 경우 역시 휘도가 저하되는 문제점이 있다.In Korean Patent Nos. 10-0456430, 10-0628884, 10-0448416, etc., gallium nitride (GaN) LED chips emitting mainly blue in the 460 nm region and YAG: Ce 3+ (emitting in yellow) Yttrium Aluminum Garnet) phosphor was used to implement white color. However, YAG-based light-emitting phosphors have a relatively weak emission intensity in the red region due to the characteristics of the emission wavelength, so that it is difficult to obtain excellent color rendering characteristics and is sensitive to color temperature, which is not suitable for lighting and LCD color background light sources. In addition, a light emitting device may be implemented using a green light-emitting silicate-based phosphor. Usually, a green phosphor using Eu 2+ ions as an activator and having a chemical formula of A 2 SiO 4 : Eu 2+ is used. A "means two or more compounds such as" Sr "," Ba "," Ca "," Mg ", etc.) However, in the case of the conventional green light emitting phosphor, a large amount of residues are generated during the heat treatment and the fluorescent particles are irregular. There is a problem that the brightness is lowered due to non-uniform morphology (morphology), such as synthesized in size, there is a problem that the brightness is also lowered when the ion is doped in the type of compound, heat treatment environment used conventionally.
대한민국 공개특허 제 10-2005-0062623 호 등에서는 근자외선에서 가시광의 단파장측 영역의 광에 의해 여기되어 청록색에서 황색계 영역에 발광 피크를 가지는 SrSi2O2N2:Eu2+ 형광체의 합성방법에 대해 개시하고 있다. 그러나 일반적인 SrSi2O2N2:Eu2+ 형광체는 발광휘도 및 열적 안정성 면에서 불충분하여 실용적인 LED에 적용하기 어려운 문제가 있었다.
In Korean Patent Application Publication No. 10-2005-0062623 et al., A method for synthesizing a SrSi 2 O 2 N 2 : Eu 2+ phosphor excited by light in a short wavelength region of visible light in near ultraviolet light and having an emission peak in a cyan to yellow region Is disclosed. However, the general SrSi 2 O 2 N 2 : Eu 2+ phosphor is insufficient in light emission luminance and thermal stability, which makes it difficult to apply to practical LEDs.
이에 본 발명자들은 상기와 같은 문제점을 해결하고자 노력한 결과, 기존의 SrSi2O2N2:Eu2+ 형광체에 다양한 형태의 알칼리금속, 알칼리토금속, 전이금속 등을 치환 또는 첨가하면 SrSi2O2N2:Eu2 + 형광체가 가지는 본래 구조의 변형 없이도 발광 휘도 및 열적 안정성을 향상시킨 (할로)금속실리콘산질화물 형광체를 제조할 수 있음을 알게 되어 본 발명을 완성하게 되었다.Accordingly, the present inventors have attempted to solve the problems described above, when SrSi 2 O 2 N is substituted or added to various types of alkali metals, alkaline earth metals, transition metals, etc. to the existing SrSi 2 O 2 N 2 : Eu 2 + phosphor 2: Eu 2 + phosphor has been discovered that can produce a modified original structure (halo), metal silicon oxynitride phosphors with improved emission luminance and thermal stability without the need of having thereby completing the present invention.
따라서, 본 발명은 자외선 또는 청색의 여기원에 의해 황색계 영역에서 발광피크를 갖는, 발광 휘도 및 열적 안정성을 향상시킨 (할로)금속실리콘산질화물 형광체 및 이를 제조하는 방법의 제공에 그 목적이 있다.
Accordingly, an object of the present invention is to provide a (halo) metal-silicon oxynitride phosphor having a light emission peak in a yellow region by ultraviolet or blue excitation source, and improving the light emission luminance and thermal stability, and a method of manufacturing the same. .
본 발명은 하기 화학식 1로 표시되는 (할로)금속실리콘산질화물 형광체를 그 특징으로 한다.The present invention is characterized by the (halo) metal silicon oxynitride phosphor represented by the following formula (1).
[화학식 1][Formula 1]
SrpAaBbCcSi2OxNyXz:Eu2 + d Sr p A a B b C c Si 2 O x N y X z : Eu 2 + d
상기 화학식 1에서, A는 알칼리금속이고, B는 알칼리토금속이며, C는 +3의 산화수를 갖는 전이금속 또는 란타늄족 금속이고, X는 할로겐 원소이며, 0≤a≤0.5, 0≤b≤0.5, 0≤c≤0.5, 0.01≤d≤0.5, 0<p≤1-d, 1.5≤x≤2, 1.666≤y≤2, 0≤z≤1이고, 단 a, b, c 및 z 는 동시에 0이 될 수 없고, B가 스트론튬일 때 a, c 및 z는 동시에 0이 될 수 없으며, 9≤2x+3y≤10 이다.In Formula 1, A is an alkali metal, B is an alkaline earth metal, C is a transition metal or lanthanum group metal having an oxidation number of +3, X is a halogen element, 0≤a≤0.5, 0≤b≤0.5 , 0≤c≤0.5, 0.01≤d≤0.5, 0 <p≤1-d, 1.5≤x≤2, 1.666≤y≤2, 0≤z≤1, provided that a, b, c and z are simultaneously It cannot be zero, and when B is strontium, a, c and z cannot be zero at the same time, and 9 ≦ 2x + 3y ≦ 10.
또한 본 발명은Also,
알칼리금속(A) 전구체, 알칼리토금속(B) 전구체, 산화수가 +3인 전이금속 또는 란타늄족 금속(C) 전구체, 유로피움(Eu) 전구체 및 실리콘(Si) 전구체를 상기 화학식 1의 화학양론비에 맞게 칭량하여 혼합하는 제 1 단계;An alkali metal (A) precursor, an alkaline earth metal (B) precursor, a transition metal having a oxidation number of +3, or a lanthanide group metal (C) precursor, an europium (Eu) precursor, and a silicon (Si) precursor are selected from the stoichiometric ratio A first step of weighing and mixing to fit;
상기 1 단계의 혼합물을 100 ~ 150℃ 오븐에서 건조하는 제 2 단계;A second step of drying the mixture of the first step in an oven at 100 to 150 ° C;
상기 2 단계의 건조된 혼합물을 수소와 질소의 혼합가스 하에서 1000 ~ 1450℃로 열처리하여 형광체를 제조하는 제 3 단계;A third step of manufacturing the phosphor by heat-treating the dried mixture of the second step at 1000 to 1450 ° C. under a mixed gas of hydrogen and nitrogen;
를 포함하는 상기 화학식 1로 표시되는 (할로)금속실리콘산질화물 형광체의 제조방법을 그 특징으로 한다.
Characterized in that the method for producing a (halo) metal silicon oxynitride phosphor represented by the formula (1) comprising a.
본 발명의 (할로)금속실리콘산질화물 형광체는 365 ~ 480 nm 파장의 자외선 또는 청색의 여기원에 의해 525 ~ 590 nm 파장의 황색계 영역에서 발광피크를 가지며, 발광 휘도 및 열적 안정성이 우수하므로 발광다이오드, 레이저다이오드, 면발광 레이저다이오드, 무기 일렉트로루미네센스 소자, 또는 유기 일렉트로루미네센스 소자와 같은 발광 소자에 유용하게 적용할 수 있다. 또한, 본 발명의 (할로)금속실리콘산질화물 형광체는 기존의 고상법을 이용하여 SrSi2O2N2:Eu2 + 형광체가 가지는 구조의 변형 없이 상압에서 제조할 수 있다.
The (halo) metal silicon oxynitride phosphor of the present invention has a light emission peak in a yellow region of 525 to 590 nm wavelength by ultraviolet or blue excitation source of 365 to 480 nm wavelength, and emits light because of excellent light emission luminance and thermal stability. The present invention can be usefully applied to light emitting devices such as diodes, laser diodes, surface emitting laser diodes, inorganic electroluminescent devices, or organic electroluminescent devices. In addition, the (halo) metal silicon oxynitride phosphor of the present invention can be prepared at normal pressure without modification of the structure of the SrSi 2 O 2 N 2 : Eu 2 + phosphor by using a conventional solid phase method.
도 1은 25℃에서 460 nm의 여기광을 이용하여 측정한 형광체의 발광 스펙트럼이다.
도 2는 25℃부터 25℃씩 승온 시키면서 200℃까지 측정한 형광체의 발광 스펙트럼의 휘도를 비교한 그래프이다.
도 3은 제조된 형광체의 X-선 회절분석(X-ray Diffraction) 결과이다.
도 4는 본 발명에서 제조된 SrSi2O2N2:Eu2 + 형광체를 460 nm로 발광하는 다이오드에 실리콘 수지와 혼합하여 제작한 1W 백색 LED 칩의 발광스펙트럼이다.1 is an emission spectrum of a phosphor measured using excitation light at 460 nm at 25 ° C.
2 is a graph comparing luminance of emission spectra of phosphors measured up to 200 ° C. while increasing the temperature from 25 ° C. to 25 ° C. each.
3 is an X-ray diffraction result of the prepared phosphor.
4 is a light emission spectrum of a 1W white LED chip manufactured by mixing a SrSi 2 O 2 N 2 : Eu 2 + phosphor prepared in the present invention with a silicone resin in a diode emitting light at 460 nm.
이하에서는 본 발명을 더욱 자세하게 설명하겠다.Hereinafter, the present invention will be described in more detail.
본 발명은 SrSi2O2N2:Eu2 + 형광체에 알칼리금속, 알칼리토금속, 전이금속 등을 치환 또는 첨가한 하기 화학식 1로 표시되는 (할로)금속실리콘산질화물 형광체에 관한 것이다.The present invention relates to a (halo) metal silicon oxynitride phosphor represented by the following Chemical Formula 1 in which an alkali metal, an alkaline earth metal, a transition metal, or the like is substituted or added to an SrSi 2 O 2 N 2 : Eu 2 + phosphor.
[화학식 1][Formula 1]
SrpAaBbCcSi2OxNyXz:Eu2 + d Sr p A a B b C c Si 2 O x N y X z : Eu 2 + d
상기 화학식 1에서, A는 알칼리금속이고, B는 알칼리토금속이며, C는 +3의 산화수를 갖는 전이금속 또는 란타늄족 금속이고, X는 할로겐 원소이며, 0≤a≤0.5, 0≤b≤0.5, 0≤c≤0.5, 0.01≤d≤0.5, 0<p≤1-d, 1.5≤x≤2, 1.666≤y≤2, 0≤z≤1이고, 단 a, b, c 및 z 는 동시에 0이 될 수 없고, B가 스트론튬일 때 a, c 및 z는 동시에 0이 될 수 없으며, 9≤2x+3y≤10 이다.In Formula 1, A is an alkali metal, B is an alkaline earth metal, C is a transition metal or lanthanum group metal having an oxidation number of +3, X is a halogen element, 0≤a≤0.5, 0≤b≤0.5 , 0≤c≤0.5, 0.01≤d≤0.5, 0 <p≤1-d, 1.5≤x≤2, 1.666≤y≤2, 0≤z≤1, provided that a, b, c and z are simultaneously It cannot be zero, and when B is strontium, a, c and z cannot be zero at the same time, and 9 ≦ 2x + 3y ≦ 10.
상기 알칼리금속은 바람직하기로는 리튬(Li), 나트륨(Na) 및 칼륨(K) 중에서 선택한 1종 이상을 선택하는 것이 좋으며, 상기 알칼리토금속으로는 마그네슘(Mg), 칼슘(Ca), 스트론튬(Sr) 및 바륨(Ba) 중에서 선택한 1종 이상을 선택하는 것이 좋다. 또한, 상기 C 성분인 +3의 산화수를 갖는 전이금속 또는 란타늄족 금속은 스칸듐(Sc), 이트륨(Y) 및 란타늄(La) 중에서 선택한 1종 이상을 선택하는 것이 좋다. 할로겐원소인 X 성분은 플루오르(F), 염소(Cl), 브롬(Br) 및 요오드(I) 중에서 선택한 1종 이상을 선택할 수 있으며, 바람직하기로는 플루오르를 사용하는 것이 좋다. 상기 a 값이 0.5를 초과하면 형광체의 용융이 있을 수 있고, b 값이 0.5를 초과하면 구조의 변형과 함께 휘도가 감소되는 결과가 있을 수 있으며, c 값이 0.5를 초과하면 형광체의 용융이 있을 수 있다. 또한, d 값이 상기 범위를 벗어나면 발광휘도의 감소와 발광파장의 변화를 동시에 가질 수 있으며, x 값 및 y 값이 상기 범위를 벗어나면 구조의 변형과 광학적 특성의 변화가 있을 수 있다. 또한, 상기 z 값이 1을 초과하면 형광체의 수축이 있을 수 있다.The alkali metal is preferably selected from at least one selected from lithium (Li), sodium (Na) and potassium (K), and the alkaline earth metal may be magnesium (Mg), calcium (Ca) or strontium (Sr). ) And barium (Ba) is preferably selected one or more selected. In addition, the transition metal or lanthanum group metal having an oxidation number of +3, which is the C component, may be selected from one or more selected from scandium (Sc), yttrium (Y), and lanthanum (La). As the X component, which is a halogen element, one or more selected from fluorine (F), chlorine (Cl), bromine (Br), and iodine (I) may be selected. Preferably, fluorine is used. If the value of a exceeds 0.5, there may be melting of the phosphor. If the value of b exceeds 0.5, the luminance may decrease with deformation of the structure. If the value of c exceeds 0.5, there may be melting of the phosphor. Can be. In addition, when the d value is out of the range, the emission luminance may be decreased and the emission wavelength may be changed at the same time. When the x value and the y value are out of the range, the structure may be deformed and the optical characteristic may be changed. In addition, when the z value exceeds 1, there may be shrinkage of the phosphor.
또한, 본 발명은 알칼리금속 전구체, 알칼리토금속 전구체, 산화수가 +3인 전이금속 또는 란타늄족 금속 전구체, 유로피움 전구체, 및 실리콘 전구체를 상기 화학식 1의 화학양론비에 맞게 칭량하여 혼합하는 제 1 단계; 상기 1 단계의 혼합물을 100 ~ 150℃ 오븐에서 건조하는 제 2 단계; 상기 2 단계의 건조된 혼합물을 수소와 질소의 혼합가스 하에서 1000 ~ 1450℃로 열처리하여 형광체를 제조하는 제 3 단계; 를 포함하는 상기 화학식 1로 표시되는 (할로)금속실리콘산질화물 형광체의 제조방법에 관한 것이다.In addition, the present invention is a first step of weighing and mixing an alkali metal precursor, an alkaline earth metal precursor, a transition metal or lanthanum group metal precursor having an oxidation number of +3, a europium precursor, and a silicon precursor in accordance with the stoichiometric ratio of Chemical Formula 1 above ; A second step of drying the mixture of the first step in an oven at 100 to 150 ° C; A third step of manufacturing the phosphor by heat-treating the dried mixture of the second step at 1000 to 1450 ° C. under a mixed gas of hydrogen and nitrogen; It relates to a method for producing a (halo) metal silicon oxynitride phosphor represented by the formula (1) comprising a.
전구체를 혼합하는 상기 제 1 단계에서, 알칼리금속 전구체, 알칼리토금속 전구체, 산화수가 +3인 전이금속 또는 란타늄족 금속 전구체, 유로피움 전구체, 실리콘 전구체는 각각의 산화물, 탄산화물, 할로겐화물 및 질화물 중에서 선택한 1종 이상을 사용하는 것이 바람직하다. 상기 전구체들을 혼합하는 방법으로는 당 분야에서 일반적으로 사용되는 방법으로, 특별히 한정하지 않으나, 예를 들어, 막자유발, 습식볼밀 또는 건식볼밀 등의 혼합방법을 이용할 수 있다. 또한, 혼합과정에서 용매의 사용없이 분말 상태로 혼합할 수도 있고, 용매를 사용하여 슬러리 상태로 혼합할 수도 있다. 용매를 사용하는 경우 증류수, 탄소수가 1 ~ 4 인 저급 알콜 또는 아세톤 등을 사용할 수 있다.In the first step of mixing the precursor, an alkali metal precursor, an alkaline earth metal precursor, a transition metal or lanthanum group metal precursor having an oxidation number of +3, a europium precursor, and a silicon precursor are selected from the respective oxides, carbonates, halides and nitrides. It is preferable to use one or more selected. As a method of mixing the precursors, a method generally used in the art is not particularly limited, and, for example, a mixing method such as membrane free ball generation, a wet ball mill, or a dry ball mill may be used. In addition, the mixing process may be mixed in a powder state without using a solvent, or may be mixed in a slurry state using a solvent. When using a solvent, distilled water, lower alcohol having 1 to 4 carbon atoms or acetone can be used.
상기 제 2 단계는 제 1 단계에서 얻어지는 혼합물을 건조하는 단계로서, 혼합물 중에 포함된 수분 및 용매의 제거를 수행한다. 건조온도는 100 ~ 150℃가 바람직한데, 온도가 너무 낮으면 건조시간이 증가하여 좋지 못하며, 반대로 온도가 너무 높으면 수분이나 용매가 전구체와 반응하여 부산물을 생성하는 문제가 있을 수 있다.The second step is to dry the mixture obtained in the first step, and to remove the water and the solvent contained in the mixture. The drying temperature is preferably 100 ~ 150 ℃, if the temperature is too low, the drying time is not good increase, on the contrary, if the temperature is too high, there may be a problem that the water or solvent reacts with the precursor to produce by-products.
상기 제 3 단계는 열처리 단계로서, 수소와 질소의 혼합가스 환원 분위기에서 소성을 통해 유로피움의 산화수를 +3에서 +2로 환원시킴으로써 형광체를 제조하게 된다. 이때, 수소와 질소의 혼합가스는 수소 5 ~ 25 부피% 및 질소 75 ~ 95 부피%를 포함하는 것을 사용하는 것이 바람직한데, 수소의 함량이 너무 적으면 유로피움의 환원이 충분치 않아 목적하는 발광 파장을 발현시키지 못할 수 있으며, 반대로 수소의 함량이 너무 많으면 폭발의 위험 등 안전상 문제가 있으므로 상기 범위를 선택하는 것이 좋다. 또한, 열처리 온도는 1000 ~ 1450℃가 바람직한데, 온도가 너무 낮으면 형광체 결정이 온전히 생성되지 않아 발광효율이 감소하는 문제가 있을 수 있으며, 온도가 너무 높으면 형광체 결정 구조의 변화가 일어나 휘도가 저하되는 문제가 있을 수 있다.The third step is a heat treatment step, thereby producing a phosphor by reducing the oxidation water of europium from +3 to +2 through firing in a mixed gas reduction atmosphere of hydrogen and nitrogen. At this time, the mixed gas of hydrogen and nitrogen is preferably used containing 5 to 25% by volume of hydrogen and 75 to 95% by volume of nitrogen, if the content of hydrogen is too small, the reduction of europium is not enough to the desired emission wavelength It may not be able to express, on the contrary, if the content of hydrogen is too high, there is a safety problem, such as the risk of explosion, it is better to select the above range. In addition, the heat treatment temperature is preferably 1000 ~ 1450 ℃, if the temperature is too low, there is a problem that the luminous efficiency is reduced because the phosphor crystal is not generated completely, if the temperature is too high, the change in the phosphor crystal structure occurs to reduce the brightness There may be a problem.
상기 방법에 의해 얻어진 형광체는 볼 밀 또는 제트 밀을 사용하여 분쇄될 수 있으며, 분쇄 및 열처리는 2회 이상 반복될 수도 있다. 필요하다면, 제조된 형광체를 세정할 수도 있다. 때로는, 할로겐원소의 함유량은 세정에 의해 제어될 수 있다. 세정 후 할로겐원소의 함유량의 변동을 초래하는 조작을 수행하는 경우, 변동 후의 함유량이 상술된 몰비를 만족하는 형광체는 본 발명의 형광체에 포함되는 것으로 간주된다. 소성 후 형광체 내의 할로겐원소의 양은 세정 등의 조작에 의해 감소하지만, 그 후, 그 양은 거의 변하지 않고 안정하게 된다.The phosphor obtained by the above method can be pulverized using a ball mill or a jet mill, and the pulverization and heat treatment may be repeated two or more times. If necessary, the prepared phosphor may be cleaned. Sometimes, the content of halogen element can be controlled by washing. When performing an operation that causes a change in the content of the halogen element after washing, the phosphor whose content after the change satisfies the above-described molar ratio is considered to be included in the phosphor of the present invention. The amount of halogen elements in the phosphor after firing is reduced by an operation such as washing, but after that the amount is almost unchanged and stabilized.
구체적으로는 세정은 금속 화합물의 혼합물을 소성한 후 얻어진 소성된 제품을 산과 접촉시키는 것을 포함하며, 이러한 경우에, 결과의 형광체는 더욱 향상된 휘도를 가지며, 이것은 바람직하다. 또한, 소성된 제품을 산과 접촉시킴으로써, 100℃에서의 휘도가 때때로 증가하며, 형광체의 온도 특성이 개선되기도 한다. 소성된 제품을 산과 접촉시키는 방법은 산에 침지시키는 방법, 교반을 수행하면서 소성된 제품을 산에 침지시키는 방법 및 습식 볼밀에 의해 소성된 제품을 산과 혼합하는 방법을 포함한다. 이용가능한 산으로는 아세트산 및 옥살산 등의 유기산 또는 염산, 질산 및 황산 등의 무기산을 들 수 있으며, 산의 수소 이온 농도는 그 취급상 관점에서 0.001 ~ 2 mol/L 을 선택하는 것이 바람직하다. 소성된 제품과 접촉하고 있는 산의 온도는 실온(약 25 ℃)이며, 필요하다면, 30 ~ 80℃로 가열될 수도 있다. 소성된 제품과 산이 접촉되는 시간은 통상 1초 내지 약 10시간이다.Specifically, the cleaning involves contacting the fired product obtained after firing the mixture of metal compounds with an acid, in which case the resulting phosphor has a further improved brightness, which is desirable. In addition, by contacting the calcined product with an acid, the luminance at 100 ° C. sometimes increases, and the temperature characteristic of the phosphor is also improved. Methods of contacting a calcined product with an acid include a method of immersing the calcined product in an acid while performing stirring, and a method of mixing the calcined product with an acid by a wet ball mill. Examples of the available acid include organic acids such as acetic acid and oxalic acid or inorganic acids such as hydrochloric acid, nitric acid and sulfuric acid, and the hydrogen ion concentration of the acid is preferably selected from 0.001 to 2 mol / L from the viewpoint of its handling. The temperature of the acid in contact with the fired product is room temperature (about 25 ° C.), and if desired, may be heated to 30 to 80 ° C. The time for contact of the calcined product with the acid is usually from 1 second to about 10 hours.
본 발명에 따른 (할로)금속실리콘산질화물 형광체는 기존의 SrSi2O2N2:Eu2 + 형광체의 문제점으로 지적되던 발광 휘도 및 열적 안정성을 크게 향상시킨 것으로, 발광다이오드, 레이저다이오드, 면발광 레이저다이오드, 무기 일렉트로루미네센스 소자, 또는 유기 일렉트로루미네센스 소자와 같은 발광 소자에 유용하게 적용할 수 있다. 또한, 본 발명의 (할로)금속실리콘산질화물 형광체의 제조방법에 의하면 SrSi2O2N2:Eu2+ 형광체의 구조 변형 없이, 고상법을 이용하여 상압에서 물성 좋은 형광체를 제조할 수 있다.
The (halo) metal-silicon oxynitride phosphors according to the present invention have greatly improved luminescence brightness and thermal stability, which has been pointed out as a problem of the conventional SrSi 2 O 2 N 2 : Eu 2 + phosphors, and includes a light emitting diode, a laser diode, and a surface light emitting diode. It can be usefully applied to a light emitting device such as a laser diode, an inorganic electroluminescent device, or an organic electroluminescent device. In addition, according to the method for producing a (halo) metal silicon oxynitride phosphor of the present invention, it is possible to produce a phosphor having good physical properties at atmospheric pressure by using a solid phase method without modifying the structure of the SrSi 2 O 2 N 2 : Eu 2+ phosphor.
이하 본 발명을 실시예에 의거하여 더욱 상세히 설명하겠는바, 본 발명이 다음 실시예에 의해 한정되는 것은 아니다.Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited by the following Examples.
[실시예][Example]
비교예Comparative example 1 ~ 2 및 1 and 2 and 실시예Example 1 ~ 167 : 형광체의 제조 1 to 167: preparation of phosphor
질화규소(Si3N4) 및 각 금속의 전구체를 하기 표 1과 같은 조성에 맞추어 칭량하고 50 ml의 에탄올에 넣어 볼밀을 이용하여 1시간 동안 혼합하였다. 이후 상기 혼합물을 100℃ 건조기에서 6시간 동안 건조시켜 에탄올을 완전히 휘발시켰다. 용매가 완전히 건조된 상기 혼합 재료는 알루미나 도가니에 넣어 1150 ℃에서 3 시간 동안 열처리하였다. 이때, 수소 50 cc/min 및 질소 150 cc/min이 혼합된 혼합가스를 공급함으로써 환원분위기에서 열처리가 되도록 한 후, 형광체 입자의 크기가 20 ㎛ 이하가 되도록 분쇄하여 형광체 분말을 제조하였다.Silicon nitride (Si 3 N 4 ) and precursors of each metal were weighed according to the composition shown in Table 1 below, and placed in 50 ml of ethanol and mixed for 1 hour using a ball mill. The mixture was then dried in a 100 ° C. dryer for 6 hours to completely volatilize the ethanol. The mixed material in which the solvent was completely dried was placed in an alumina crucible and heat-treated at 1150 ° C. for 3 hours. At this time, by supplying a mixed gas mixed with 50 cc / min of hydrogen and 150 cc / min of nitrogen to the heat treatment in a reducing atmosphere, the phosphor particles were ground to a size of 20 ㎛ or less to prepare a phosphor powder.
(g)Active agent
(g)
1Comparative Example
One
SrO (0.0872)SrCO 3 (1.0811)
SrO (0.0872)
2Comparative Example
2
SrO (0.2277)SrCO 3 (1.0487)
SrO (0.2277)
1Example
One
2Example
2
3Example
3
4Example
4
MgO (0.0349)SrCO 3 (1.1107)
MgO (0.0349)
5Example
5
CaO (0.0482)SrCO 3 (1.1032)
CaO (0.0482)
6Example
6
CaF2(0.0664)SrCO 3 (1.0929)
CaF 2 (0.0664)
7Example
7
CaCO3(0.0844)SrCO 3 (1.0827)
CaCO 3 (0.0844)
8Example
8
SrF2(0.1048)SrCO 3 (1.0712)
SrF 2 (0.1048)
9Example
9
BaF2(0.1433)SrCO 3 (1.0494)
BaF 2 (0.1433)
10Example
10
BaCO3(0.1598)SrCO 3 (1.0401)
BaCO 3 (0.1598)
11Example
11
12Example
12
13Example
13
14Example
14
15Example
15
16Example
16
MgO (0.0952)SrCO 3 (1.1271)
MgO (0.0952)
17Example
17
CaO (0.1300)SrCO 3 (1.1065)
CaO (0.1300)
18Example
18
CaF2(0.1765)SrCO 3 (1.0709)
CaF 2 (0.1765)
19Example
19
CaCO3(0.2208)SrCO 3 (1.0528)
CaCO 3 (0.2208)
20Example
20
SrF2(0.2695)SrCO 3 (1.0240)
SrF 2 (0.2695)
21Example
21
BaF2(0.3571)SrCO 3 (0.9722)
BaF 2 (0.3571)
22Example
22
BaCO3(0.3931)SrCO 3 (0.9508)
BaCO 3 (0.3931)
23Example
23
24Example
24
25Example
25
Na2CO3(0.0449)Li 2 CO 3 (0.0313)
Na 2 CO 3 (0.0449)
26Example
26
K2CO3(0.0581)Li 2 CO 3 (0.0311)
K 2 CO 3 (0.0581)
27Example
27
MgO (0.0744)SrCO 3 (0.9803)
MgO (0.0744)
28Example
28
CaO (0.1020)SrCO 3 (0.9663)
CaO (0.1020)
29Example
29
CaF2(0.1392)SrCO 3 (0.9473)
CaF 2 (0.1392)
30Example
30
CaCO3(0.1750)SrCO 3 (0.9291)
CaCO 3 (0.1750)
31Example
31
SrO (0.1806)SrCO 3 (0.9296)
SrO (0.1806)
32Example
32
SrF2(0.2148)SrCO 3 (0.9088)
SrF 2 (0.2148)
33Example
33
BaF2(0.2876)SrCO 3 (0.8718)
BaF 2 (0.2876)
34Example
34
BaCO3(0.3180)SrCO 3 (0.8563)
BaCO 3 (0.3180)
35Example
35
36Example
36
37Example
37
K2CO3(0.0577)Na 2 CO 3 (0.0443)
K 2 CO 3 (0.0577)
38Example
38
MgO (0.0738)SrCO 3 (0.9731)
MgO (0.0738)
39Example
39
CaO (0.1012)SrCO 3 (0.9593)
CaO (0.1012)
40Example
40
CaF2(0.1382)SrCO 3 (0.9406)
CaF 2 (0.1382)
41Example
41
CaCO3(0.1738)SrCO 3 (0.9226)
CaCO 3 (0.1738)
42Example
42
SrO (0.1793)SrCO 3 (0.9198)
SrO (0.1793)
43Example
43
SrF2(0.2133)SrCO 3 (0.9026)
SrF 2 (0.2133)
44Example
44
BaF2(0.2857)SrCO 3 (0.8661)
BaF 2 (0.2857)
45Example
45
BaCO3(0.3159)SrCO 3 (0.8508)
BaCO 3 (0.3159)
46Example
46
47Example
47
48Example
48
MgO (0.0733)SrCO 3 (0.9660)
MgO (0.0733)
49Example
49
CaO (0.1005)SrCO 3 (0.9524)
CaO (0.1005)
50Example
50
CaF2(0.1372)SrCO 3 (0.9339)
CaF 2 (0.1372)
51Example
51
CaCO3(0.1725)SrCO 3 (0.9162)
CaCO 3 (0.1725)
52Example
52
SrO (0.1781)SrCO 3 (0.9134)
SrO (0.1781)
53Example
53
SrF2(0.2199)SrCO 3 (0.8965)
SrF 2 (0.2199)
54Example
54
BaF2(0.2838)SrCO 3 (0.8604)
BaF 2 (0.2838)
55Example
55
BaCO3(0.3139)SrCO 3 (0.8454)
BaCO 3 (0.3139)
56Example
56
57Example
57
58Example
58
MgO (0.0747)
CaO (0.0260)SrCO 3 (0.9844)
MgO (0.0747)
CaO (0.0260)
59Example
59
MgO (0.0743)
CaF2(0.0360)SrCO 3 (0.9794)
MgO (0.0743)
CaF 2 (0.0360)
60Example
60
MgO (0.0739)
CaCO3(0.0459)SrCO 3 (0.9774)
MgO (0.0739)
CaCO 3 (0.0459)
61Example
61
MgO (0.0739)
SrO (0.0475)SrCO 3 (0.9737)
MgO (0.0739)
SrO (0.0475)
62Example
62
MgO (0.0735)
SrF2(0.0572)SrCO 3 (0.9688)
MgO (0.0735)
SrF 2 (0.0572)
63Example
63
MgO (0.0727)
BaF2(0.0790)SrCO 3 (0.9579)
MgO (0.0727)
BaF 2 (0.0790)
64Example
64
MgO (0.0723)
BaCO3(0.0885)SrCO 3 (0.9532)
MgO (0.0723)
BaCO 3 (0.0885)
65Example
65
MgO (0.0741)SrCO 3 (1.0046)
MgO (0.0741)
66Example
66
MgO (0.0738)SrCO 3 (1.0006)
MgO (0.0738)
67Example
67
CaO (0.0491)
SrO (0.0907)SrCO 3 (0.9952)
CaO (0.0491)
SrO (0.0907)
68Example
68
CaO (0.0486)
SrF2(0.1089)SrCO 3 (0.9857)
CaO (0.0486)
SrF 2 (0.1089)
69Example
69
CaO (0.0476)
BaF2(0.1488)SrCO 3 (0.9649)
CaO (0.0476)
BaF 2 (0.1488)
70Example
70
CaO (0.0472)
BaCO3(0.1660)SrCO 3 (0.9560)
CaO (0.0472)
BaCO 3 (0.1660)
71Example
71
CaO (0.0488)SrCO 3 (1.0793)
CaO (0.0488)
72Example
72
CaO (0.0486)SrCO 3 (1.0752)
CaO (0.0486)
73Example
73
CaF2(0.0677)
SrO (0.0889)SrCO 3 (0.9857)
CaF 2 (0.0677)
SrO (0.0889)
74Example
74
CaF2(0.0671)
SrF2(0.1079)SrCO 3 (0.9764)
CaF 2 (0.0671)
SrF 2 (0.1079)
75Example
75
CaF2(0.0657)
BaF2(0.1474)SrCO 3 (0.9560)
CaF 2 (0.0657)
BaF 2 (0.1474)
76Example
76
CaF2(0.0651)
BaCO3(0.1644)SrCO 3 (0.9472)
CaF 2 (0.0651)
BaCO 3 (0.1644)
77Example
77
CaF2(0.0673)SrCO 3 (1.0691)
CaF 2 (0.0673)
78Example
78
CaF2(0.0671)SrCO 3 (1.0650)
CaF 2 (0.0671)
79Example
79
CaCO3(0.0860)
SrO (0.0890)SrCO 3 (0.9764)
CaCO 3 (0.0860)
SrO (0.0890)
80Example
80
CaCO3(0.0852)
SrF2(0.1069)SrCO 3 (0.9673)
CaCO 3 (0.0852)
SrF 2 (0.1069)
81Example
81
CaCO3(0.0834)
BaF2(0.1461)SrCO 3 (0.9472)
CaCO 3 (0.0834)
BaF 2 (0.1461)
82Example
82
CaCO3(0.0826)
BaCO3(0.1629)SrCO 3 (0.9386)
CaCO 3 (0.0826)
BaCO 3 (0.1629)
83Example
83
CaCO3(0.0855)SrCO 3 (1.0590)
CaCO 3 (0.0855)
84Example
84
CaCO3(0.0852)SrCO 3 (1.0550)
CaCO 3 (0.0852)
85Example
85
SrF2(0.1036)
BaF2(0.1446)SrCO 3 (0.9372)
SrF 2 (0.1036)
BaF 2 (0.1446)
86Example
86
SrF2(0.1026)
BaCO3(0.1612)SrCO 3 (0.9288)
SrF 2 (0.1026)
BaCO 3 (0.1612)
87Example
87
SrF2(0.1061)SrCO 3 (1.0476)
SrF 2 (0.1061)
88Example
88
SrF2(0.1057)SrCO 3 (1.0437)
SrF 2 (0.1057)
89Example
89
BaF2(0.1451)SrCO 3 (1.0260)
BaF 2 (0.1451)
90Example
90
BaF2(0.1445)SrCO 3 (1.0223)
BaF 2 (0.1445)
91Example
91
BaCO3(0.1618)SrCO 3 (1.0168)
BaCO 3 (0.1618)
92Example
92
BaCO3(0.1612)SrCO 3 (1.0131)
BaCO 3 (0.1612)
93Example
93
Y2O3(0.0095)Sc 2 O 3 (0.0058)
Y 2 O 3 (0.0095)
94Example
94
Na2CO3(0.0422)Li 2 CO 3 (0.0294)
Na 2 CO 3 (0.0422)
95Example
95
K2CO3(0.0547)Li 2 CO 3 (0.0293)
K 2 CO 3 (0.0547)
96Example
96
MgO (0.0635)SrCO 3 (1.1286)
MgO (0.0635)
97Example
97
CaO (0.0873)SrCO 3 (1.1148)
CaO (0.0873)
98Example
98
CaF2(0.1195)SrCO 3 (1.0960)
CaF 2 (0.1195)
99Example
99
CaCO3(0.1507)SrCO 3 (1.0779)
CaCO 3 (0.1507)
100Example
100
SrO (0.1556)SrCO 3 (1.0750)
SrO (0.1556)
101Example
101
SrF2(0.1855)SrCO 3 (1.0575)
SrF 2 (0.1855)
102Example
102
BaF2(0.2498)SrCO 3 (1.0201)
BaF 2 (0.2498)
103Example
103
BaCO3(0.2768)SrCO 3 (1.0043)
BaCO 3 (0.2768)
104Example
104
105Example
105
106Example
106
K2CO3(0.0544)Na 2 CO 3 (0.0417)
K 2 CO 3 (0.0544)
107Example
107
MgO (0.0631)SrCO 3 (1.1215)
MgO (0.0631)
108Example
108
CaO (0.0868)SrCO 3 (1.1079)
CaO (0.0868)
109Example
109
CaF2(0.1188)SrCO 3 (1.0893)
CaF 2 (0.1188)
110Example
110
CaCO3(0.1498)SrCO 3 (1.0714)
CaCO 3 (0.1498)
111Example
111
SrO (0.1546)SrCO 3 (1.0686)
SrO (0.1546)
112Example
112
SrF2(0.1844)SrCO 3 (1.0513)
SrF 2 (0.1844)
113Example
113
BaF2(0.2484)SrCO 3 (1.0143)
BaF 2 (0.2484)
114Example
114
BaCO3(0.2753)SrCO 3 (0.9987)
BaCO 3 (0.2753)
115Example
115
116Example
116
117Example
117
MgO (0.0627)SrCO 3 (1.1145)
MgO (0.0627)
118Example
118
CaO (0.0862)SrCO 3 (1.1010)
CaO (0.0862)
119Example
119
CaF2(0.1181)SrCO 3 (1.0827)
CaF 2 (0.1181)
120Example
120
CaCO3(0.1489)SrCO 3 (1.0650)
CaCO 3 (0.1489)
121Example
121
SrO (0.1537)SrCO 3 (1.0622)
SrO (0.1537)
122Example
122
SrF2(0.1834)SrCO 3 (1.0451)
SrF 2 (0.1834)
123Example
123
BaF2(0.2470)SrCO 3 (1.0085)
BaF 2 (0.2470)
124Example
124
BaCO3(0.2737)SrCO 3 (1.0931)
BaCO 3 (0.2737)
125Example
125
126Example
126
127Example
127
MgO (0.0638)
CaO (0.0222)SrCO 3 (1.0326)
MgO (0.0638)
CaO (0.0222)
128Example
128
MgO (0.0635)
CaF2(0.0307)SrCO 3 (1.1277)
MgO (0.0635)
CaF 2 (0.0307)
129Example
129
MgO (0.0632)
CaCO3(0.0392)SrCO 3 (1.1228)
MgO (0.0632)
CaCO 3 (0.0392)
130Example
130
MgO (0.0632)
SrO (0.0406)SrCO 3 (1.1221)
MgO (0.0632)
SrO (0.0406)
131Example
131
MgO (0.0629)
SrF2(0.0490)SrCO 3 (1.1172)
MgO (0.0629)
SrF 2 (0.0490)
132Example
132
MgO (0.0623)
BaF2(0.0677)SrCO 3 (1.1065)
MgO (0.0623)
BaF 2 (0.0677)
133Example
133
MgO (0.0620)
BaCO3(0.0759)SrCO 3 (1.1018)
MgO (0.0620)
BaCO 3 (0.0759)
134Example
134
MgO (0.0641)SrCO 3 (1.1370)
MgO (0.0641)
135Example
135
MgO (0.0639)SrCO 3 (1.1351)
MgO (0.0639)
136Example
136
CaO (0.0435)
SrO (0.0803)SrCO 3 (1.1102)
CaO (0.0435)
SrO (0.0803)
137Example
137
CaO (0.0431)
SrF2(0.0966)SrCO 3 (1.1008)
CaO (0.0431)
SrF 2 (0.0966)
138Example
138
CaO (0.0423)
BaF2(0.1323)SrCO 3 (1.0802)
CaO (0.0423)
BaF 2 (0.1323)
139Example
139
CaO (0.0420)
BaCO3(0.1476)SrCO 3 (1.0713)
CaO (0.0420)
BaCO 3 (0.1476)
140Example
140
CaO (0.0450)SrCO 3 (1.1503)
CaO (0.0450)
141Example
141
CaO (0.0449)SrCO 3 (1.1462)
CaO (0.0449)
142Example
142
CaF2(0.0600)
SrO (0.0797)SrCO 3 (1.1008)
CaF 2 (0.0600)
SrO (0.0797)
143Example
143
CaF2(0.0595)
SrF2(0.0958)SrCO 3 (1.0916)
CaF 2 (0.0595)
SrF 2 (0.0958)
144Example
144
CaF2(0.0584)
BaF2(0.1312)SrCO 3 (1.0713)
CaF 2 (0.0584)
BaF 2 (0.1312)
145Example
145
CaF2(0.0579)
BaCO3(0.1464)SrCO 3 (1.0625)
CaF 2 (0.0579)
BaCO 3 (0.1464)
146Example
146
CaF2(0.0622)SrCO 3 (1.1402)
CaF 2 (0.0622)
147Example
147
CaF2(0.0619)SrCO 3 (1.1362)
CaF 2 (0.0619)
148Example
148
CaCO3(0.0763)
SrO (0.0790)SrCO 3 (1.0916)
CaCO 3 (0.0763)
SrO (0.0790)
149Example
149
CaCO3(0.0757)
SrF2(0.0950)SrCO 3 (1.0825)
CaCO 3 (0.0757)
SrF 2 (0.0950)
150Example
150
CaCO3(0.0743)
BaF2(0.1301)SrCO 3 (1.0625)
CaCO 3 (0.0743)
BaF 2 (0.1301)
151Example
151
CaCO3(0.0737)
BaCO3(0.1452)SrCO 3 (1.0539)
CaCO 3 (0.0737)
BaCO 3 (0.1452)
152Example
152
CaCO3(0.0790)SrCO 3 (1.1303)
CaCO 3 (0.0790)
153Example
153
CaCO3(0.0787)SrCO 3 (1.1264)
CaCO 3 (0.0787)
154Example
154
SrF2(0.0923)
BaF2(0.1289)SrCO 3 (1.0526)
SrF 2 (0.0923)
BaF 2 (0.1289)
155Example
155
SrF2(0.0916)
BaCO3(0.1439)SrCO 3 (1.0441)
SrF 2 (0.0916)
BaCO 3 (0.1439)
156Example
156
SrF2(0.0982)SrCO 3 (1.1190)
SrF 2 (0.0982)
157Example
157
SrF2(0.0978)SrCO 3 (1.1152)
SrF 2 (0.0978)
158Example
158
BaF2(0.1344)SrCO 3 (1.0977)
BaF 2 (0.1344)
159Example
159
BaF2(0.1339)SrCO 3 (1.0940)
BaF 2 (0.1339)
160Example
160
BaCO3(0.1500)SrCO 3 (1.0885)
BaCO 3 (0.1500)
161Example
161
BaCO3(0.1495)SrCO 3 (1.0849)
BaCO 3 (0.1495)
162Example
162
Y2O3(0.0184)Sc 2 O 3 (0.0056)
Y 2 O 3 (0.0184)
163Example
163
CaCO3(0.4586)SrCO 3 (0.6359)
CaCO 3 (0.4586)
164Example
164
BaCO3(0.7395)SrCO 3 (0.5200)
BaCO 3 (0.7395)
165Example
165
MgO (0.0700)
BaCO3(0.3425)SrCO 3 (0.7302)
MgO (0.0700)
BaCO 3 (0.3425)
166Example
166
CaCO3(0.1651)
BaCO3(0.3256)SrCO 3 (0.6942)
CaCO 3 (0.1651)
BaCO 3 (0.3256)
167Example
167
BaCO3(0.5977)SrCO 3 (0.6371)
BaCO 3 (0.5977)
시험예Test Example 1 : 형광체의 광학특성 분석 1: Optical Characteristic Analysis of Phosphor
제조된 형광체의 460 nm 여기 파장에서의 발광 파장 스펙트럼 및 휘도를 PSI社 광발광(Photoluminescence) 장비를 사용하여 측정하였다. 표 2의 상대휘도는 비교예 1에서 제조한 형광체의 휘도를 100% 로 하여 상대값을 측정하였으며, 표 3의 상대휘도는 각 형광체의 25℃에서의 휘도를 100% 로 하여 200℃에서의 상대값을 측정하였다. 결과는 하기 표 2 ~ 3 및 도 1 ~ 2와 같다.The emission wavelength spectrum and luminance at the 460 nm excitation wavelength of the prepared phosphor were measured using PSI Photoluminescence equipment. Relative luminance of Table 2 was measured relative value by the luminance of the phosphor prepared in Comparative Example 1 100%, the relative luminance of Table 3 is the relative luminance at 200 ° C 100% of the luminance at 25 ℃ of each phosphor The value was measured. The results are shown in Tables 2 to 3 and FIGS.
상기 표 2 및 도 1에서 보이는 바와 같이 본 발명의 (할로)금속실리콘산질화물 형광체는 460 nm 의 여기파장에서 533 ~ 560 nm 의 발광특성을 나타내었으며, 휘도는 기존의 SrSi2O2N2:Eu2 + 형광체와 동등 이상의 수치를 나타내었다. 특히 실시예 135에서 제조된 Sr0 .97Mg0 .2Y0 .02Si2O2N2:Eu2 + 0.03 형광체는 약 40% 상승한 휘도값을 보였다. 또한, 상기 표 3 및 도 2에서 보이는 바와 같이 본 발명의 형광체는 열적안정성이 우수하여 200℃에서의 휘도 감소폭이 기존의 형광체 보다 작은 수치를 나타내었다. 발광 휘도의 상승폭과 200℃에서의 휘도 감소폭을 동시에 고려할 경우, 75%의 휘도가 상승하는 효과가 나타났다.
As shown in Table 2 and FIG. 1, the (halo) metal silicon oxynitride phosphors of the present invention exhibited luminescence properties of 533 to 560 nm at an excitation wavelength of 460 nm, and luminance of the conventional SrSi 2 O 2 N 2 : Eu + 2 is shown a numerical value equal to or more phosphor. In particular, the Sr 0 .97 prepared in Example 135 Mg 0 .2 Y 0 .02 Si 2 O 2 N 2:
시험예 2 : 형광체의 구조적 특성 평가Test Example 2 Evaluation of Structural Properties of Phosphor
제조된 형광체의 X-선 회절분석(X-ray Diffraction) 시험을 실시하고 그 결과를 도 3에 나타내었다.An X-ray diffraction test of the prepared phosphor was performed and the results are shown in FIG. 3.
도 3에 보이는 바와 같이 SrSi2O2N2:Eu2 + 형광체에 금속을 치환 또는 첨가하더라도 본래의 구조를 잘 유지하고 있음을 알 수 있다.
As shown in FIG. 3, it can be seen that the original structure is well maintained even when a metal is substituted or added to the SrSi 2 O 2 N 2 : Eu 2 + phosphor.
시험예 3 : 백색 LED의 성능 평가Test Example 3 Performance Evaluation of White LEDs
실시예 135에서 제조한 형광체를 청색 발광 다이오드(발광파장 460 nm)에 도포하여 백색 LED를 제조하고, 이의 성능을 평가하였다.The phosphor prepared in Example 135 was applied to a blue light emitting diode (light emitting wavelength 460 nm) to prepare a white LED, and the performance thereof was evaluated.
도 4에서 보이는 것처럼 제조된 Sr0 .97Mg0 .2Y0 .02Si2O2N2:Eu2 + 0.03 형광체는 넓은 반치폭(FWHM)을 가지고 있어 적색 형광체와 혼합하여 백색 LED를 제작할 경우, 녹색에서 적색 영역에 이르는 넓은 발광 특성을 보여주고 있음을 알 수 있다. 연색성이 우수한 백색 LED를 제조하기 위해서는 가시광 영역을 넓게 보완할 수 있는 발광 특성이 필수적이고, 이에 따라 넓은 반치폭이 요구된다. 현재 LED 시장에서 사용되고 있는 실리케이트 형광체의 경우 우수한 발광 휘도를 가지고 있지만 열적안정성이나 온습도 환경 등에서의 신뢰성의 문제가 있지만, 본 발명의 (할로)금속실리콘산질화물 형광체는 실리케이트 형광체보다 우수한 특성을 가진다. 또한 상용 β-SiAlON과 비교하여 면적 대비 동등한 휘도를 나타낼 만큼의 반치폭을 보여주고 있다. 이것은 본 발명의 형광체가 β-SiAlON 형광체보다 조명용 LED 분야에서는 더 유용한 특성을 가지고 있음을 말한다. 또한 실시예 169에서 제조한 백색 LED는 연색지수(color rendering index, CRI) 90.5 Ra, 상관색온도(correlated color temperature, CCT)는 5500 K, 발광효율 58 lm/W를 나타내었다.Also the Sr 0 .97 Mg 0 .2 Y 0 .02 Si 2 O 2
Claims (6)
[화학식 1]
SrpAaBbCcSi2OxNyXz:Eu2+ d
상기 화학식 1에서,
A는 알칼리금속이고, B는 알칼리토금속이며, C는 +3의 산화수를 갖는 전이금속 또는 란타늄족 금속이고, X는 할로겐 원소이며, 0≤a≤0.5, 0≤b≤0.5, 0≤c≤0.5, 0.01≤d≤0.5, 0<p≤1-d, 1.5≤x≤2, 1.666≤y≤2, 0≤z≤1이고,
단 a, b, c 및 z 는 동시에 0이 될 수 없고, b가 0<b≤0.5일 때 c는 0<c≤0.5이며, 9≤2x+3y≤10 이다.
(Halo) metal silicon oxynitride phosphor represented by the following formula (1):
[Formula 1]
Sr p A a B b C c Si 2 O x N y X z : Eu 2+ d
In Chemical Formula 1,
A is an alkali metal, B is an alkaline earth metal, C is a transition metal or lanthanide group metal having an oxidation number of +3, X is a halogen element, 0 ≦ a ≦ 0.5, 0 ≦ b ≦ 0.5, and 0 ≦ c ≦ 0.5, 0.01≤d≤0.5, 0 <p≤1-d, 1.5≤x≤2, 1.666≤y≤2, 0≤z≤1,
However, a, b, c and z cannot be 0 at the same time. When b is 0 <b≤0.5, c is 0 <c≤0.5 and 9≤2x + 3y≤10.
The (halo) metal silicon oxynitride phosphor according to claim 1, wherein the transition metal is scandium or yttrium.
The (halo) metal silicon oxynitride phosphor according to claim 1, wherein the phosphor has a light emission wavelength of 525 to 590 nm at an excitation wavelength of 365 to 480 nm.
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WO2015072766A1 (en) | 2013-11-13 | 2015-05-21 | 엘지이노텍(주) | Blue-green phosphor, and light-emitting device package and lighting apparatus comprising same |
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