Polarizing photonic band gap system with reflector
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H01J-005/16
H01J-005/02
출원번호
US-0819158
(2004-04-07)
등록번호
US-7378785
(2008-05-27)
발명자
/ 주소
Chen,Chien Hua
Chaparala,Murali
Bicknell,Robert
출원인 / 주소
Hewlett Packard Development Company, L.P.
인용정보
피인용 횟수 :
0인용 특허 :
5
초록▼
A polarizing photonic band gap system has a photonic crystal emitter. The photonic crystal emitter has a crystal end surface. The photonic crystal emitter is configured to generate electromagnetic energy having a wavelength λ. The system has a polarizer. The polarizer is connected to the photon
A polarizing photonic band gap system has a photonic crystal emitter. The photonic crystal emitter has a crystal end surface. The photonic crystal emitter is configured to generate electromagnetic energy having a wavelength λ. The system has a polarizer. The polarizer is connected to the photonic crystal emitter. The polarizer has a polarizer surface. The polarizer surface is located within a distance of said crystal end surface. The distance is sufficient to quantum mechanically couple the polarizer surface with said crystal end surface at the wavelength λ.
대표청구항▼
What is claimed is: 1. A polarizing photonic band gap system, comprising: a polarizer; a photonic crystal emitter, connected to said polarizer, having a crystal end surface, the photonic crystal emitter configured to generate electromagnetic energy having a wavelength λ, wherein said polarizer
What is claimed is: 1. A polarizing photonic band gap system, comprising: a polarizer; a photonic crystal emitter, connected to said polarizer, having a crystal end surface, the photonic crystal emitter configured to generate electromagnetic energy having a wavelength λ, wherein said polarizer has a polarizer surface located within a distance of said crystal end surface sufficient to quantum mechanically couple with said crystal end surface at said wavelength λ, and wherein said photonic crystal emitter has an opposing crystal end surface opposite to said crystal end surface; and a reflecting material connected to said opposing crystal end surface of the photonic crystal emitter that is configured to reflect the electromagnetic energy emitted from the photonic crystal emitter back into the photonic crystal emitter. 2. The polarizing photonic band gap system as in claim 1, wherein said polarizer surface is located within a distance of approximately λ of said crystal end surface. 3. The polarizing photonic band gap system as in claim 1, wherein said polarizer surface is located a distance of approximately ��λ from said crystal end surface. 4. The polarizing photonic band gap system as in claim 1, wherein said polarizer comprises a wire grid, said wire grid comprising an array of substantially parallel electrically conducting wires, wherein adjacent wires of said conducting wires are spaced apart by a distance of substantially less than λ. 5. The polarizing photonic band gap system as in claim 4, wherein said wire grid is formed on a high-temperature, substantially transparent dielectric material. 6. The polarizing photonic band gap system as in claim 5, wherein said dielectric material comprises at least one of sapphire, aluminum oxide, and silicon dioxide. 7. The polarizing photonic band gap system as in claim 4, wherein said conducting wires are freely suspended over said crystal end surface. 8. The polarizing photonic band gap system as in claim 7, wherein said freely suspended conducting wires are supported at their respective ends on pillars connected to said photonic crystal emitter. 9. The polarizing photonic band gap system as in claim 1, wherein said photonic crystal emitter comprises a metal. 10. The polarizing photonic band gap system as in claim 9, wherein said photonic crystal emitter comprises metal incandescent filaments, whereby said photonic crystal emitter is configured to generate incandescent light by application of a current through said incandescent filaments. 11. The polarizing photonic band gap system as in claim 10, wherein said photonic crystal emitter comprises a plurality of layers of metal incandescent filaments, wherein the filaments in each individual layer are substantially parallel. 12. The polarizing photonic band gap system as in claim 11, wherein the filaments in adjacent layers are substantially perpendicular. 13. The polarizing photonic band gap system as in claim 11, wherein the filaments in adjacent layers are substantially non-perpendicular. 14. The polarizing photonic band gap system as in claim 10, wherein said incandescent filaments comprise tungsten. 15. The polarizing photonic band gap system as in claim 10, wherein said polarizer comprises a wire grid, said wire grid comprising an array of substantially parallel electrically conducting wires, wherein adjacent wires of said conducting wires are spaced apart by a distance of substantially less than λ. 16. The polarizing photonic band gap system as in claim 15, wherein said conducting wires and said incandescent filaments comprise tungsten. 17. The polarizing photonic band gap system as in claim 15, wherein said wire grid is integrally formed with said photonic crystal emitter. 18. The polarizing photonic band gap system as in claim 15, wherein said photonic crystal emitter has an opposing crystal end surface opposite to said crystal end surface, wherein said system further comprises a reflecting material connected to said opposing crystal end surface. 19. The polarizing photonic band gap system as in claim 18, wherein said wire grid is located within a distance of approximately λ of said crystal end surface. 20. A display, comprising: the polarizing photonic band gap system as in claim 18 a second polarizer; and a pixel array located between the polarizing photonic band gap system and the second polarizer. 21. The polarizing photonic band gap system as in claim 1, wherein said photonic crystal emitter has an opposing crystal end surface opposite to said crystal end surface, wherein said system further comprises: a second polarizer connected to said photonic crystal emitter and having a second polarizer surface located within a distance of said opposing crystal end surface sufficient to quantum mechanically couple to said opposing crystal end surface at said wavelength λ. 22. The polarizing photonic band gap system as in claim 21, further comprising a reflector configured to reflect light polarized by said second polarizer. 23. The polarizing photonic band gap system as in claim 1, wherein said photonic crystal emitter comprises an opposing crystal end surface opposite to said crystal end surface, wherein said system further comprises a quarterwave plate and a reflecting material connected to said opposing crystal end surface. 24. The polarizing photonic band gap system as in claim 1, wherein the polarizer is connected to said photonic crystal emitter via a high-temperature, substantially transparent dielectric material. 25. The polarizing photonic band gap system as in claim 1, wherein λ is in a visible spectrum. 26. A polarizing photonic band gap system, comprising: a wire grid polarizer, said wire grid comprising an array of substantially parallel electrically conducting wires, wherein adjacent wires of said conducting wires are spaced apart by a distance of substantially less than λ; a photonic crystal emitter, connected to said wire grid polarizer, comprising metal incandescent filaments, whereby said photonic crystal emitter is configured to generate visible incandescent light having a wavelength λ; and a reflecting material connected to an opposing crystal end surface of the photonic crystal emitter wherein the reflecting material is configured to reflect the visible incandescent light emitted by the photonic crystal emitter back into the photonic crystal emitter. 27. The polarizing photonic band gap system as in claim 26, wherein said incandescent filaments and said conducting wires comprise tungsten. 28. The polarizing photonic band gap system as in claim 26, wherein said wire grid is integrally formed with said photonic crystal emitter. 29. The polarizing photonic band gap system as in claim 26, wherein the polarizer is connected to said photonic crystal emitter via a high-temperature, substantially transparent dielectric material. 30. The polarizing photonic band gap system as in claim 26, wherein said conducting wires are freely suspended over said crystal end surface. 31. A display, comprising: the polarizing photonic band gap system as in claim 26; a second polarizer; and a pixel array located between the polarizing photonic band gap system and the second polarizer. 32. A polarizing photonic band gap system, comprising: means for polarizing electromagnetic energy; means for generating electromagnetic energy, connected to said means for polarizing electromagnetic energy, having a wavelength λ in a photonic crystal, the means for generating electromagnetic energy having a crystal end surface; wherein said means for polarizing electromagnetic energy has a polarizer surface located within a distance of said crystal end surface sufficient to quantum mechanically couple with said crystal end surface at said wavelength λ, and wherein said means for generating electromagnetic energy has an opposing crystal end surface opposite to said crystal end surface; and a means for reflecting electromagnetic energy connected to said opposing crystal end surface of said means for generating electromagnetic energy that is configured to reflect the electromagnetic energy emitted from the means for generating electromagnetic energy back into the means for generating electromagnetic energy. 33. The polarizing photonic band gap system as in claim 32, wherein said means for generating electromagnetic energy has an opposing crystal end surface opposite to said crystal end surface, wherein said system further comprises: a second means for polarizing electromagnetic energy connected to said means for generating electromagnetic energy and having a second polarizer surface located within a distance of said opposing crystal end surface sufficient to quantum mechanically couple to said opposing crystal end surface at said wavelength λ.
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