Abstract: A light source device is provided. The light source device comprises a semiconductor light-emitting element; and a wavelength conversion member for converting a wavelength of a light emitted from the semiconductor light-emitting element. The semiconductor light-emitting element has a light-emitting peak wavelength of not less than 380 nanometers and not more than 420 nanometers. The light emitted from the semiconductor light-emitting element has a light energy density of not less than 0.2 kW/cm2. The wavelength conversion member contains at least one fluorescent substance selected from the group consisting of a (Sr1-x,Bax)3MgSi2O8:Eu2+ (0?x?1) fluorescent substance, a (Y1-y,Gdy)3(Al1-z,Gaz)5O12:Ce3+ (0?y?1, 0?z?1) fluorescent substance, and an Eu3+-activated fluorescent substance. The light source device has a high output and a high light-emitting efficiency.

Abstract: A red phosphor material includes an essential component represented by a formula of A2-2xRxEuySmzLnx-y-zM2O8 as a main component, where A represents at least one selected from Ca and Sr; R represents at least one selected from Li, Na, and K; Ln represents at least one selected from La, Gd, and Y; M represents at least one selected from W and Mo; and x, y, and z are numerical values that satisfy 0.2?x?0.7, 0.2?y+z?0.6, 0.005?z?0.04, and x?y?z?0. A light-emitting device includes an excitation light source and the red phosphor material that absorbs excitation light emitted by the excitation light source and emits red light.

Abstract: A red phosphor material comprising an essential component represented by a formula of ALn1-x-yEuxSmyM2O8 as a main component, where A represents at least one selected from Li, Na, and K; Ln represents at least one selected from La and Gd; M represents at least one selected from W and Mo; and x and y are numerical values that satisfy 0.1?x+y?0.7 and 0.005?y?0.08. A light-emitting device includes an excitation light source and the red phosphor material that absorbs excitation light emitted by the excitation light source and emits red light.

Abstract: A phosphor material according to an embodiment of the present disclosure contains a major component represented by the formula A2-v-w-x-yBvLnwEuxSmyM2-zDzO8, where A is one or more elements selected from the group consisting of alkaline-earth metal elements; B is one or more elements selected from the group consisting of alkali metal elements; Ln is one or more elements selected from the group consisting of rare-earth elements other than Eu and Sm; M is one or more elements selected from the group consisting of W and Mo; D is one or more elements selected from the group consisting of Nb and Ta; and v, w, x, y, and z satisfy the inequalities 0?v?0.5, 0.15?x+y?0.7, 0?y?0.05, and 0<z?1.7 and the equation w+x+y=v+z.

Abstract: A fluorescent material forms fluorescent particles and is represented by a general formula of xAO.y1EuO.y2EuO3/2.MgO.zSiO2, wherein, in the general formula, A is at least one selected from Ca, Sr, and Ba; x satisfies 2.80?x?3.00; y1+y2 satisfies 0.01?y1+y2?0.20; and z satisfies 1.90?z?2.10; and regarding a divalent Eu ratio defined as a content ratio of divalent Eu to all Eu elements, the fluorescent particles have a divalent Eu ratio of 50 mol % or less as measured by X-ray photoelectron spectroscopy, and the fluorescent particles have a divalent Eu ratio of 97 mol % or more as measured by X-ray absorption near-edge structure analysis. A light-emitting device includes a fluorescent layer containing the fluorescent material.

Abstract: A phosphor material according to an embodiment of the present disclosure contains a major component represented by the formula A2-v-w-x-yBvLnwEuxSmyM2-zDzO8, where A is one or more elements selected from the group consisting of alkaline-earth metal elements; B is one or more elements selected from the group consisting of alkali metal elements; Ln is one or more elements selected from the group consisting of rare-earth elements other than Eu and Sm; M is one or more elements selected from the group consisting of W and Mo; D is one or more elements selected from the group consisting of Nb and Ta; and v, w, x, y, and z satisfy the inequalities 0?v?0.5, 0.15?x+y?0.7, 0?y?0.05, and 0<z?1.7 and the equation w+x+y=v+z.

Abstract: An oxychloride phosphor of the present disclosure includes divalent Eu arranged as an augmenting agent, at part of locations. The locations correspond to site of at least two kinds of predetermined substances included in a host crystal. A rate of the number of the divalent Eu with respect to the sum of the number of moles of the predetermined substance and the number of moles of the divalent Eu is less than 2%. When the predetermined substance is represented by A, the oxychloride phosphor is represented by a general formula of xAO.yEuO.SiO2.zCl. In this formula, A represents Sr and Ca, or Sr, Ca, and Mg, y indicates a value of not less than 0.002 and not more than 0.02, x+y indicates a value of more than 1.00 and not more than 1.30, and z indicates a value of not less than 0.20 and not more than 0.70.

Abstract: A light source device is provided. The light source device comprises a semiconductor light-emitting element; and a wavelength conversion member for converting a wavelength of a light emitted from the semiconductor light-emitting element. The semiconductor light-emitting element has a light-emitting peak wavelength of not less than 380 nanometers and not more than 420 nanometers. The light emitted from the semiconductor light-emitting element has a light energy density of not less than 0.2 kW/cm2. The wavelength conversion member contains at least one fluorescent substance selected from the group consisting of a (Sr1-x,Bax)3MgSi2O8:Eu2+ (0?x?1) fluorescent substance, a (Y1-y,Gdy)3(Al1-z,Gaz)5O12:Ce3+ (0?y<1, 0?z<1) fluorescent substance, and an Eu3+-activated fluorescent substance. The light source device has a high output and a high light-emitting efficiency.

Abstract: The present invention provides an oxynitride silicate fluorescent substance capable of output a light having a high luminance even when irradiated by an exciting light having a high energy density. The present invention is a yellow fluorescent substance represented by a chemical formula (Ba1-x-y-z,Srx)aSibOcNd:Eu2+y,Y3+z (0.9?a?1.1, 1.9?b?2.1, 1.9?c?2.1, 1.9?d?2.1, 0?x?1, 0<y<0.01, and 0?z<0.01).

Abstract: The present invention provides a new phosphor with a controllable emission wavelength without using a number of rare and expensive raw materials in forming the composition. The phosphor includes a compound including a fluorescent ion and having a garnet structure including a rare earth element, aluminum, and oxygen. The compound has such a composition that a combination of the rare earth element and the aluminum of the compound is partially replaced with a combination of alkaline earth metal and zirconium (Zr) or alkaline earth metal and hafnium (Hf).

Abstract: Provided is a high-efficiency light-emitting device. Further, provided is a light-emitting device with high efficiency and less variation in the color temperature of emitted white light in the case of configuring, for example, a white light-emitting device combining a blue LED and a phosphor layer. The light-emitting device includes a phosphor layer that emits light having a predetermined wavelength, and the phosphor layer contains at least one selected from the group consisting of a phosphor represented by a general formula: aYO3/2.(3?a)CeO3/2.bAlO3/2.cGaO3/2.fWO3 (2.80?a?2.99, 3.00?b?5.00, 0?c?2.00, 0.003?f?0.020, where 4.00?b+c?5.00), and a phosphor represented by a general formula: aYO3/2.(3?a)CeO3/2.bAlO3/2.cGaO3/2.gK2WO4 (2.80?a?2.99, 3.00?b?5.00, 0?c?2.00, 0.003?g?0.015, where 4.00?b+c?5.00).

Abstract: The present disclosure provides a (Ba1?z,Srz)3MgSi2O8:Eu2+ based phosphor with high emission quantum efficiency. Specifically, the present disclosure provides a blue light emitting phosphor including: a (Ba1?z,Srz)3MgSi2O8 based crystal where z satisfies 0?z<1 and a (Ba1?z,Srz)MgSiO4 based crystal where z satisfies 0?z<1 as a host crystal; and Eu2+ as a luminescent center.

Abstract: A plasma display panel having a short decay time, high luminance, and high efficiency is provided. The plasma display panel includes a green phosphor layer that emits visible light when excited with vacuum ultraviolet rays. The green phosphor layer contains a green phosphor represented by the general formula aBaO.(2-a)EuO.bMgO.cSiO2.fCaCl2 (where 1.800?a?1.980, 0.950?b?1.050, 1.900?c?2.100, and 0.001?f?0.020).

Abstract: It is an object to provide phosphors with high luminance. It also is an object to provide phosphors with less decrease in luminance due to a reduction in particle diameter. A first phosphor is represented by a general formula: aYO3/2.(3?a)CeO3/2.bAlO3/2.cGaO32.fWO3(2.80?a?2.99, 3.00?b?5.00, 0?c?2.00, 0.003?f?0.020, where 4.00?b+c?5.00). A second phosphor is represented by a general formula: aYO3/2.(3?a)CeO3/2.bAlO3/2.cGaO3/2.gK2WO4(2.80?a?2.99, 3.00?b?5.00, 0?c?2.00, 0.003?g?0.015, where 4.00?b+c?5.00).

Abstract: The present invention provides a new phosphor with a controllable emission wavelength without using a number of rare and expensive raw materials in forming the composition. The phosphor includes a compound including a fluorescent ion and having a garnet structure including a rare earth element, aluminum, and oxygen. The compound has such a composition that a combination of the rare earth element and the aluminum of the compound is partially replaced with a combination of alkaline earth metal and zirconium (Zr) or alkaline earth metal and hafnium (Hf).

Abstract: A plasma display panel having a short decay time, high luminance, and high efficiency is provided. The plasma display panel includes a green phosphor layer that emits visible light when excited with vacuum ultraviolet rays. The green phosphor layer contains a green phosphor represented by the general formula aBaO·(2-a)EuO·bMgO·cSiO2·fCaCl2 (where 1.800?a?1.980, 0.950?b?1.050, 1.900?c?2.100, and 0.001<f<0.020).

Abstract: The blue phosphor of the present invention is represented by the general formula aBaO.bSrO.(1?a?b)EuO.cMgO.dAlO3/2.eWO3, where 0.70?a?0.95, 0?b?0.15, 0.95?c?1.15, 9.00?d?11.00, 0.001?e?0.200, and a+b?0.97 are satisfied. In the blue phosphor of the present invention, two peaks whose tops are located in a range of diffraction angle 2?=13.0 to 13.6 degrees and one peak whose top is located in a range of diffraction angle 2?=14.6 to 14.8 degrees are present in an X-ray diffraction pattern obtained by measurement on the blue phosphor using an X-ray with a wavelength of 0.774 ?.

Abstract: Provided is a high-efficiency plasma display panel having short decay time and high luminance and color purity. The plasma display panel includes a green phosphor layer emitting visible light when excited with vacuum ultraviolet rays, in which the green phosphor layer is formed of a green phosphor containing 30% by weight or more and 60% by weight or less of a phosphor represented by a general formula: dZnO.(2?d)MnO.eSiO2 (1.80?d?1.90, 1.00?e?1.02) and one of a phosphor represented by a general formula: aYO3/2.(3?a)CeO3/2.bAlO3/2.cGaO3/2.fWO3 (2.80?a?2.99, 3.00?b?5.00, 0?c?2.00, 0.003?f?0.020, where 4.00?b+c?5.00) and a phosphor represented by a general formula: aYO3/2.(3?a)CeO3/2.bAlO3/2.cGaO3/2.gK2WO4 (2.80?a?2.99, 3.00?b?5.00, 0?c?2.00, 0.003?g?0.015, where 4.00?b+c?5.00).

Abstract: The present invention provides a blue phosphor having high luminance and showing less luminance degradation during driving of a light-emitting device. The present invention is a blue phosphor that includes: an alkaline earth metal aluminate represented by a general formula aBaO.bSrO.(1?a?b)EuO.cMgO.dAlO3/2, where 0.70?a?0.95, 0?b?0.15, 0.95?c?1.15, 9.00?d?11.00, and a+b?0.97 are satisfied; and 0.008 mol to 0.800 mol of MWO4 with respect to 1 mol of the aluminate, where M is at least one element selected from a group consisting of Ba, Sr, and Ca.

Abstract: The present invention provides a blue phosphor that exhibits high luminance and shows less luminance degradation during driving of a light-emitting device. The present invention is a blue phosphor represented by the general formula aBaO.bSrO.(1?a?b)EuO.cMgO.dAlO3/2.eWO3, where 0.70?a?0.95, 0?b?0.15, 0.95?c?1.15, 9.00?d?11.00, 0.001?e?0.100, and a+b?0.97 are satisfied. In this blue phosphor, two peaks whose tops are located in a range of diffraction angle 2?=13.0 to 13.6 degrees are present in an X-ray diffraction pattern obtained by measurement on the blue phosphor using an X-ray with a wavelength of 0.774 ?.