Abstract: A light emitting photonic crystal having an organic light emitting diode and methods of making the same are disclosed. An organic light emitting diode disposed within a photonic structure having a band-gap, or stop-band, allows the photonic structure to emit light at wavelengths occurring at the edges of the band-gap. Photonic crystal structures that provide this function may include materials having a refractive index that varies.

Abstract: A light emitting device is described. The light emitting device includes a single light emitting photonic crystal having an electroluminescent material disposed in the single light emitting photonic crystal. The single light emitting photonic crystal includes a series of layers of chiral liquid crystalline polymer. The electroluminescent material is localized in one of the layers of chiral liquid crystalline polymer. At least one of the series of layers of chiral liquid crystalline polymer includes a chiral liquid crystalline, charge carrier transporting polymer. The single light emitting photonic crystal further includes a second luminescent material, where energy emanating from the electroluminescent material stimulates the second luminescent material into light emission, and the light emitted by the light emitting device is a mixture of light emitted by the electroluminescent material and light emitted by the second luminescent material.

Abstract: Light emitting photonic crystals that comprise organic light emitting diodes and that are capable of emitting multiple wavelengths of light simultaneously and methods for fabricating the same are disclosed. Disclosed light emitting photonic crystals emit light at wavelengths at the two edges of a stop-band. Methods for adjusting the width of stop-bands of disclosed devices are also disclosed.

Abstract: Disclosed herein is a light emitting device and method of manufacturing such a device comprised of a series of photopolymerizable, chiral liquid crystalline layers that can be solvent cast on a substrate. The mixture of chiral materials in each successive layer may be blended in such a way that each layer has the same chiral pitch. Further the chiral materials in each layer may also be blended so that the ordinary and extraordinary refractive indices in each layer match the other layers such that the complete assembly of layers will optically function as a single relatively thick layer of chiral liquid crystal. The chiral nematic material in each layer can spontaneously adopt a helical structure with a helical pitch. The light emitting layers of the light emitting device can further comprise electroluminescent material that emits light into the band edge light propagation modes of the photonic crystal.

Abstract: Light emitting electrochemical cell devices comprising chiral liquid crystalline materials. The chiral liquid crystalline material mixtures of the devices function as both electrolytes and as light emitting materials. The chiral liquid crystalline material mixtures also form photonic crystal structures creating a photonic stop band. The presence of the photonic stop band enables the light emitting electrochemical cell devices to emit light with improved energy efficiency.

Abstract: A light emitting device is described, including a single light emitting photonic crystal having a stop band and organic electroluminescent emitter material within. The device includes a reflective metal cathode. The organic electroluminescent emitter material includes an organic light emitting material localized in a layer having less than 20% of an optical thickness of the photonic crystal and has a free space emission spectrum overlapping the stop band of the photonic crystal. The photonic crystal emits light at a wavelength corresponding to an edge of the stop band, has a periodically varying refractive index, and includes alternating layers of high index and low index of refraction materials. One of the layers of low index of refraction materials includes a zone containing the organic electroluminescent emitter material with additional sub-layers each having a low index of refraction, and with the organic electroluminescent emitter material adjacent to the reflective metal cathode.

Abstract: A light emitting photonic crystal having an organic light emitting diode and methods of making the same are disclosed. An organic light emitting diode disposed within a photonic structure having a band-gap, or stop-band, allows the photonic structure to emit light at wavelengths occurring at the edges of the band-gap. Photonic crystal structures that provide this function may include materials having a refractive index that varies.

Abstract: A light emitting photonic crystal having an organic light emitting diode and methods of making the same are disclosed. An organic light emitting diode disposed within a photonic structure having a band-gap, or stop-band, allows the photonic structure to emit light at wavelengths occurring at the edges of the band-gap. Photonic crystal structures that provide this function may include materials having a refractive index that varies.

Abstract: Disclosed herein are head-mounted and other display assemblies that utilize organic light emitting diodes as image sources. In the organic light emitting diodes utilized in these display assemblies light is emitted by stimulated emission. As a results of this, the organic light emitting diodes utilized emit light vertically within a narrow cone about axes normal to the planes of the organic light emitting diodes. This narrow cone of emission results in greatly reduced light insertion losses when light transits from the organic light emitting diodes through the display assemblies and as a result increased energy efficiency in the operation of the display assemblies.

Abstract: A photovoltaic device including an interconnecting liquid crystalline polymer network is described. The interconnecting liquid crystalline polymer network is formed using a process including polymerizing a mixture of components with linear or lathe-shaped molecules terminated with two or more crosslinking groups and one or more non-polymerizable liquid crystalline components. The linear or lathe-shaped molecules terminated with two or more crosslinking groups include flexible spacers connecting chromophoric molecular cores to each of the crosslinking groups. The components with linear or lathe-shaped molecules terminated with two or more crosslinking groups make up between twenty and forty percent of said mixture. At least two of the components with linear or lathe-shaped molecules have the same chromophoric core and each of these components make up ten percent or less of said mixture.

Abstract: Disclosed herein are light emitting device that emit highly circularly polarized light. These devices may be used to form a dot-matrix display or an electronic information display comprised of a series of photopolymerizable, chiral liquid crystalline layers that can be solvent cast on a substrate. The mixture of chiral materials in each successive layer may be blended in such a way that each layer has the same chiral pitch and may also be blended so that the ordinary and extraordinary refractive indices in each layer match the other layers such that the complete assembly of layers will optically function as a single relatively thick layer or chiral liquid crystal. The chiral nematic material in each layer can spontaneously adopt a helical structure with a helical pitch. Further disclosed are pixel structures that not only emit light with brightness and chromaticity information, but also depth of focus information as well.

Abstract: Disclosed herein are light emitting device that emit highly circularly polarized light. These devices may be used to form a dot-matrix display or an electronic information display comprised of a series of photopolymerizable, chiral liquid crystalline layers that can be solvent cast on a substrate. The mixture of chiral materials in each successive layer may be blended in such a way that each layer has the same chiral pitch and may also be blended so that the ordinary and extraordinary refractive indices in each layer match the other layers such that the complete assembly of layers will optically function as a single relatively thick layer of chiral liquid crystal. The chiral nematic material in each layer can spontaneously adopt a helical structure with a helical pitch. Further disclosed are pixel structures that not only emit light with brightness and chromaticity information, but also depth of focus information as well.

Abstract: A light emitting photonic crystal having an organic light emitting diode and methods of making the same are disclosed. An organic light emitting diode disposed within a photonic structure having a band-gap, or stop-band, allows the photonic structure to emit light at wavelengths occurring at the edges of the band-gap. Photonic crystal structures that provide this function may include materials having a refractive index that varies.

Abstract: Disclosed herein are head-mounted and other display assemblies that utilize organic light emitting diodes as image sources. In the organic light emitting diodes utilized in these display assemblies light is emitted by stimulated emission. As a result of this, the organic light emitting diodes utilized emit light vertically within a narrow cone about axes normal to the planes of the organic light emitting diodes. This narrow cone of emission results in greatly reduced light insertion losses when light transits from the organic light emitting diodes through the display assemblies and as a result increased energy efficiency in the operation of the display assemblies.

Abstract: Disclosed herein is a light emitting device and method of manufacturing such a device comprised of a series of photopolymerizable, chiral liquid crystalline layers that can be solvent cast on a substrate. The mixture of chiral materials in each successive layer may be blended in such a way that each layer has the same chiral pitch. Further the chiral materials in each layer may also be blended so that the ordinary and extraordinary refractive indices in each layer match the other layers such that the complete assembly of layers will optically function as a single relatively thick layer of chiral liquid crystal. The chiral nematic material in each layer can spontaneously adopt a helical structure with a helical pitch. The light emitting layers of the light emitting device can further comprise electroluminescent material that emits light into the band edge light propagation modes of the photonic crystal.

Abstract: A 1, 4 bidentate ligand comprising first and second ligand centres, wherein the first ligand centre is an sp2-hybridised carbon or a nitrogen atom; wherein the second ligand centre is a nitrogen atom in a five- or six-membered aromatic or hetero-aromatic ring, said ring having a substantially linear substituent T1 meta or para to the nitrogen atom; wherein T1 has the formula 1: —Ar1a—Y1b—Ar2—[Y2c—Ar2]d—S—B??(1) and wherein T1 is attached to the ring by X1, wherein X1 is a bond, a methylene group, a substituted methylene group, an oxygen atom or a sulphur atom, wherein each Ar1 and Ar2 are independently selected from the group of C6 to C20 aromatic and C4 to C20 heteroaromatic groups, wherein Y1 and each Y2 is independently an optionally substituted C2 or acetonitrile trans double-bond linking moiety, wherein a is 0, 1, 2 or 3, wherein b is 0, 1 or 2, wherein each c is independently 0, 1 or 2, wherein d is 0, 1, 2, 3 or 4, S is a flexible spacer, and B represents a moiety having one or more cross-linkable

Abstract: An active matrix light emitting display comprising an anode layer comprising a plurality of individual selectively energizable anodes, a cathode layer comprising a plurality of individual selectively energizable cathodes, an emitter layer for emitting light when energized disposed between the anode layer and the cathode layer, and a photoluminescent layer comprising a plurality of various color photoluminescent pixels, wherein a selected anode and a selected cathode are energizable to photoexcite a selected color pixel. A light emitting device comprising, a light emitting photonic crystal having organic electroluminescent emitter material disposed within the photonic crystal, and a photoluminescent material disposed upon a surface of the light emitting photonic crystal, such that light emitted by the light emitting photonic crystal causes photoexcitation within the photoluminescent material.

Abstract: A light emitting photonic crystal having an organic light emitting diode and methods of making the same are disclosed. An organic light emitting diode disposed within a photonic structure having a band-gap, or stop-band, allows the photonic structure to emit light at wavelengths occurring at the edges of the band-gap. Photonic crystal structures that provide this function may include materials having a refractive index that varies.

Abstract: Disclosed herein is a light emitting device and method of manufacturing such a device comprised of a series of photopolymerizable, chiral liquid crystalline layers that can be solvent cast on a substrate. The mixture of chiral materials in each successive layer may be blended in such a way that each layer has the same chiral pitch. Further the chiral materials in each layer may also be blended so that the ordinary and extraordinary refractive indices in each layer match the other layers such that the complete assembly of layers will optically function as a single relatively thick layer of chiral liquid crystal. The chiral nematic material in each layer can spontaneously adopt a helical structure with a helical pitch. The light emitting layers of the light emitting device can further comprise electroluminescent material that emits light into the band edge light propagation modes of the photonic crystal.

Abstract: Light emitting photonic crystals that comprise organic light emitting diodes and that are capable of emitting multiple wavelengths of light simultaneously and methods for fabricating the same are disclosed. Disclosed light emitting photonic crystals emit light at wavelengths at the two edges of a stop-band. Methods for adjusting the width of stop-bands of disclosed devices are also disclosed.