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    • 2. 发明申请
    • OPTICAL MATERIALS, OPTICAL, COMPONENTS, DEVICES, AND METHODS
    • 光学材料,光学,部件,器件和方法
    • WO2010129350A2
    • 2010-11-11
    • PCT/US2010/032799
    • 2010-04-28
    • QD VISION, INC.MODI, RohitLANDREMAN, PatrickLINTON, John, R.SQUIRES, Emily, M.
    • MODI, RohitLANDREMAN, PatrickLINTON, John, R.SQUIRES, Emily, M.
    • C09K11/00
    • H01L33/005B82Y10/00B82Y20/00B82Y40/00C09K11/02C09K11/883G02B5/206G02B5/207H01L33/06H01L33/105H01L33/20H01L33/22Y10S977/774Y10S977/901Y10S977/95Y10T428/1317Y10T428/25
    • An optical material comprising quantum confined semiconductor nanoparticles having an improved solid state photoluminescent efficiency is disclosed. Also disclosed is an optical component including an optical material comprising quantum confined semiconductor nanoparticfes having an improved solid state photoluminescent efficiency. Further disclosed are methods for treating an optical material comprising quantum confined semiconductor nanoparticles. Further disclosed are methods for treating an optical component including an optical material comprising quantum confined semiconductor nanoparticles. One method comprises exposing the optical material to a light flux and heat for a period of time sufficient to increase the solid state photoluminescent quantum efficiency of the optical material by at least 10% of its pre-exposure solid state photoluminescent quantum efficiency value. Another method comprises exposing an optical component comprising quantum confined semiconductor nanoparticles to a light flux and heat for a period of time sufficient to increase the solid state photoluminescent quantum efficiency of the optical material by at least 10% of its pre-exposure solid state photoluminescent quantum efficiency value. Additional methods are disclosed, as are optical materials and optical components obtained by such methods. Devices including optical materials and/or optical components are also disclosed.
    • 公开了包含具有改进的固态光致发光效率的量子限制半导体纳米颗粒的光学材料。 还公开了一种光学部件,其包括具有改进的固态光致发光效率的量子有限半导体纳米颗粒的光学材料。 还公开了用于处理包含量子限制半导体纳米颗粒的光学材料的方法。 还公开了用于处理包括包含量子限制半导体纳米颗粒的光学材料的光学部件的方法。 一种方法包括将光学材料暴露于光通量和加热足以使光学材料的固态光致发光量子效率增加其预曝光固态光致发光量子效率值的至少10%的时间。 另一种方法包括将包含量子限制半导体纳米颗粒的光学部件暴露于光通量和加热一段足以使光学材料的固态光致发光量子效率增加至少10%的其预曝光固态光致发光量子 效率值。 公开了另外的方法,以及通过这些方法获得的光学材料和光学部件。 还公开了包括光学材料和/或光学部件的装置。
    • 3. 发明申请
    • OPTICAL MATERIALS, OPTICAL, COMPONENTS, DEVICES, AND METHODS
    • 光学材料,光学,部件,器件和方法
    • WO2010129350A3
    • 2011-03-31
    • PCT/US2010032799
    • 2010-04-28
    • QD VISION INCMODI ROHITLANDREMAN PATRICKLINTON JOHN RSQUIRES EMILY M
    • MODI ROHITLANDREMAN PATRICKLINTON JOHN RSQUIRES EMILY M
    • C09K11/00
    • C09K11/883B82Y10/00B82Y20/00B82Y40/00C09K11/02G02B5/206G02B5/207H01L33/005H01L33/06H01L33/105H01L33/20H01L33/22Y10S977/774Y10S977/901Y10S977/95Y10T428/1317Y10T428/25
    • An optical material comprising quantum confined semiconductor nanoparticles having an improved solid state photoluminescent efficiency is disclosed. Also disclosed is an optical component including an optical material comprising quantum confined semiconductor nanoparticfes having an improved solid state photoluminescent efficiency. Further disclosed are methods for treating an optical material comprising quantum confined semiconductor nanoparticles. Further disclosed are methods for treating an optical component including an optical material comprising quantum confined semiconductor nanoparticles. One method comprises exposing the optical material to a light flux and heat for a period of time sufficient to increase the solid state photoluminescent quantum efficiency of the optical material by at least 10% of its pre-exposure solid state photoluminescent quantum efficiency value. Another method comprises exposing an optical component comprising quantum confined semiconductor nanoparticles to a light flux and heat for a period of time sufficient to increase the solid state photoluminescent quantum efficiency of the optical material by at least 10% of its pre-exposure solid state photoluminescent quantum efficiency value. Additional methods are disclosed, as are optical materials and optical components obtained by such methods. Devices including optical materials and/or optical components are also disclosed.
    • 公开了包含具有改进的固态光致发光效率的量子限制半导体纳米颗粒的光学材料。 还公开了一种光学部件,其包括具有改进的固态光致发光效率的量子有限半导体纳米颗粒的光学材料。 还公开了用于处理包含量子限制半导体纳米颗粒的光学材料的方法。 还公开了用于处理包括包含量子限制半导体纳米颗粒的光学材料的光学部件的方法。 一种方法包括将光学材料暴露于光通量和加热足以使光学材料的固态光致发光量子效率增加其预曝光固态光致发光量子效率值的至少10%的时间。 另一种方法包括将包含量子限制半导体纳米颗粒的光学部件暴露于光通量和加热一段足以使光学材料的固态光致发光量子效率增加至少10%的其预曝光固态光致发光量子 效率值。 公开了另外的方法,以及通过这些方法获得的光学材料和光学部件。 还公开了包括光学材料和/或光学部件的装置。
    • 4. 发明申请
    • OPTICAL MATERIALS, OPTICAL COMPONENTS, AND METHODS
    • 光学材料,光学元件和方法
    • WO2010129374A3
    • 2010-11-11
    • PCT/US2010/032859
    • 2010-04-28
    • QD VISION, INC.MODI, RohitLANDREMAN, PatrickLINTON, John, R.SQUIRES, Emily, M.
    • MODI, RohitLANDREMAN, PatrickLINTON, John, R.SQUIRES, Emily, M.
    • B82B3/00G02B5/00C09K11/00C08L101/00
    • An optical material comprising quantum confined semiconductor nanoparticles, wherein at least a portion of the nanoparticles are in a charge neutral state is disclosed. Also disclosed is an optical component including an optical materia] comprising quantum confined semiconductor nanoparticles, wherein at least a portion of the nanoparticles are in a charge neutral state. Further disclosed is an optical material obtainable by at least partially encapsulating an optical material comprising quantum confined semiconductor nanoparticles and irradiating the at least partially encapsulated optical material with a light flux for a period of time sufficient to neutralize the charge on at least a portion of the nanoparticles. Further enclosed is an optical component obtainable by at least partially encapsulating an optical component including an optical material comprising quantum confined semiconductor nanoparticles and irradiating the at least partially encapsulated optical material with a light flux for a period of time sufficient to neutralize the charge on at least a portion of the nanoparticles. Methods are also disclosed.
    • 包括量子约束半导体纳米粒子的光学材料,其中至少一部分纳米粒子处于电荷中性状态。 还公开了包括光学材料的光学部件,其包括量子限制的半导体纳米颗粒,其中至少一部分纳米颗粒处于电荷中性状态。 还公开了一种光学材料,其可通过至少部分地包封包含量子限制的半导体纳米粒子的光学材料并用光通量照射该至少部分包封的光学材料足以中和至少一部分 纳米粒子。 进一步封装的是可通过至少部分地包封包括光学材料的光学组件来获得的光学组件,所述光学组件包含量子限制的半导体纳米粒子并且用光通量照射所述至少部分封装的光学材料达足以至少中和电荷的时间段 一部分纳米颗粒。 还公开了方法。
    • 6. 发明申请
    • LIGHTING DEVICES, AN OPTICAL COMPONENT FOR A LIGHTING DEVICE, AND METHODS
    • 照明装置,用于照明装置的光学部件及方法
    • WO2011020098A1
    • 2011-02-17
    • PCT/US2010/045624
    • 2010-08-16
    • QD VISION, INC.LINTON, John, R.SQUIRES, Emily, M.MODI, Rohit
    • LINTON, John, R.SQUIRES, Emily, M.MODI, Rohit
    • H01L33/00
    • H01L33/50C09K11/025C09K11/883H01L33/504H01L33/58H05B33/14Y02B20/181
    • A white-light emitting lighting device comprising one or more light emitting light sources (preferably solid state semiconductor light emitting diodes) that emit off-white light during operation, wherein the off-white light includes a spectral output including at least one spectral component in a first spectral region from about 360 nm to about 475 nm, at least one spectral component in a second spectral region from about 475 nm to about 575 nm, and at least one deficiency in at least one other spectral region, and an optical component that is positioned to receive at least a portion of the off-white light generated by the one or more light sources, the optical component comprising an optical material for converting at least a portion of the off-white light to one or more predetermined wavelengths, at least one of which has a wavelength in at least one deficient spectral region.
    • 一种白光发射照明装置,包括在操作期间发出灰白光的一个或多个发光光源(优选为固态半导体发光二极管),其中所述灰白色光包括光谱输出,所述光谱输出包括至少一个光谱分量 约360nm至约475nm的第一光谱区域,在约475nm至约575nm的第二光谱区域中的至少一个光谱分量,以及至少一个其它光谱区域中的至少一个缺陷,以及光学部件, 定位成接收由一个或多个光源产生的灰白色光的至少一部分,光学部件包括用于将至少一部分灰白色光转换成一个或多个预定波长的光学材料,在 其中至少一个具有至少一个缺陷光谱区域中的波长。