5,812 research outputs found
The Julius Knight season, Thursday and Friday, May 7th and 8th, 1908 : A royal divorce.
At head of title: His Majesty's Theatre, Auckland.; "Under the direction of - J.C. Williamson."; "Play produced by Julius Knight."; Includes a cast of characters, a synopsis of scenery and incidents and credits.; Also available in an electronic version via the Internet at: http://nla.gov.au/nla.aus-vn1630302.Royal divorc
The Julius Knight season, Wednesday, April 29, '08 : The prisoner of Zenda, Edward Rose's adaptation of Anthony Hope's powerful story.
At head of title: His Majesty's Theatre, Auckland.; "Under the direction of - J.C. Williamson."; "Play produced by Julius Knight."; Includes a cast of characters, a synopsis of scenery and incidents and credits.; Also available in an electronic version via the Internet at: http://nla.gov.au/nla.aus-vn1630295.Prisoner of Zend
The marriage record of Knight, Charles L. and Wall, Daisy
Marriage license for Charles L. Knight and Daisy Wall. J.C. Jau was the officiant
Two-dimensional photonic crystal material in fibre form
Photonic crystals are formed of periodically structured dielectric material, the pitch or period of the structure being of the order of the optical wavelength. A novel property of photonic crystal materials is they can be designed so as to exhibit photonic bandgaps, i.e. frequency ranges in which there are no propagating modes in the material. Some interesting consequences of such photonic band gaps occur for waves propagating out-of-plane in two-dimensionally materials. One possibility is to fabricate low-loss waveguides which guide soley by Bragg reflection. This could be done by using a 2-D structure which is effectively infinite in the third dimension, and which exhibits a bandgap in its transmission characteristics for waves which have a certain wavevector component beta =k along the structure. By purposefully introducing some kind of defect which is embedded in the crystal structure we can create a spatially localized region where such a wave can exist - a "defect state" appears in the band structure of the material. Light in this defect state would be unable to leak away from the defect through the crystal material, but would travel along the defect with propagation constant beta
Hybrid Photonic Crystal Fiber
We present a hybrid photonic crystal fiber in which a guided mode is confined simultaneously by modified total internal reflection from an array of air holes and antiresonant reflection from a line of high-index inclusions. Experimental results demonstrate that this fiber shares properties of both index-guided and photonic bandgap structures. © 2006 Optical Society of America.142926931Knight, J.C., Photonic crystal fibres (2003) Nature, 424, pp. 847-851Birks, T.A., Knight, J.C., Russell, P.S.J., Endlessly single-mode photonic crystal fiber (1997) Opt. Lett., 22, pp. 961-963Ortigosa-Blanch, Knight, J.C., Wadsworth, W.J., Arriaga, J., Mangam, B.J., Birks, T.A., Russell, P.S.J., Highly birefringent photonic crystal fibers (2000) Opt. Lett., 25, pp. 1325-1327Wadsworth, W.J., Ortigosa-Blanch, A., Knight, J.C., Birks, T.A., Man, T.-P.M., Russell, P.St.J., Supercontinuum generation in photonic crystal fibers and optical fiber tapers: A novel light source (2002) J. Opt. Soc. Am. B, 19, pp. 2148-2155Knight, J.C., Birks, T.A., Cregan, R.F., Russell, P.S.J., De Sandro, P.D., Large mode area photonic crystal fibre (1998) Electron. Lett., 34, pp. 1347-1348Reeves, W.H., Knight, J.C., Russell, P.St.J., Roberts, P.J., Demonstration of ultra-flattened dispersion in photonic crystal fibers (2002) Opt. Express, 10, pp. 609-613Knight, J.C., Arriaga, J., Birks, T.A., Ortigosa-Blanch, Wadsworth, W.J., Russell, P.S.J., Anomalous dispersion in photonic crystal fibers (2000) IEEE Photon. Technol. Lett., 12, pp. 807-809Luan, F., George, A.K., Hedley, T.D., Pearce, G.J., Bird, D.M., Knight, J.C., Russell, P.St.J., All-solid photonic bandgap fiber (2004) Opt. Lett., 29, pp. 1-4Argyros, A., Birks, T.A., Leon-Saval, S.G., Cordeiro, C.M.B., Luan, F., Russell, P.St.J., Photonic bandgap with an index step of one percent (2004) Opt. Express, 13, pp. 1540-1550Bouwmans, G., Bigot, L., Quiquempois, Y., Lopez, F., Provino, L., Douay, M., Fabrication and characterization of an all-solid 2D photonic bandgap fiber with a low-loss region (<20dB/km) around 1550 nm (2005) Opt. Express, 13, pp. 8452-8459Litchinitser, N.M., Dunn, S.C., Steinvurzel, P.E., Eggleton, B.J., White, T.P., McPhedran, R.C., De Sterke, C.M., Application of an ARROW model for designing tunable photonic devices (2004) Opt. Express, 12, pp. 1540-1550Litchinitser, N.M., Abeeluck, A.K., Headley, C., Eggleton, B.J., Antiresonant reflecting photonic crystal optical waveguides (2002) Opt. Lett., 27, pp. 1592-1594Litchinitser, N.M., Dunn, S.C., Usner, B., Eggleton, B.J., White, T.P., McPhedran, R.C., De Sterke, C.M., Resonances in microstructured optical waveguides (2003) Opt. Express, 11, pp. 1243-1251Arismar Cerqueira Jr., S., Nobrega, K.Z., Hernandez-Figueroa, H.E., Di Pasquale, F., A powerful tool based on finite element method for designing photonic crystal devices (2004) Proceedings of International Conference on Telecommunications, pp. 287-295Clarricoats, P.J.B., Chan, K.B., Electromagnetic-wave propagation along radially inhomogeneous dielectric cylinders (1970) Electron. Lett., 6, pp. 694-695Cregan, R.F., Mangan, B.J., Knight, J.C., Birks, T.A., Russell, P.St.J., Roberts, P.J., Allan, D.C., Single-mode photonic band gap guidance of light in air (1999) Science, 285, pp. 1537-1539Jasapara, J., Her, T.H., Bise, R., Windeler, R., Di Giovanni, D.J., Group-velocity measurements in a photonic bandgap fiber (2003) J. Opt. Soc. Am. B, 20, pp. 1611-161
rac-N-{6-[Bromo(hydroxy)methyl]-2-pyridyl}pivalamide
The title compound, C(11)H(15)BrN(2)O(2), contains an amide group which is close to coplanar with the adjacent pyridine ring, the dihedral angle between the planes being 9.0 (5)degrees. The molecular packing reveals a mutual hydrogen-bond interaction between centrosymmetrically related hydroxyl O atoms. Further hydrogen bonding involving O-H center dot center dot center dot Br and N-H center dot center dot center dot Br interactions also appears to consolidate the packing
Pure silica single-mode fibre with hexagonal photonic crystal cladding
Pure silica fibres supporting guided modes were first investigated in the 1970's, the aim being to achieve low transmission losses. The huge success of chemical vapour deposition in producing extremely low loss fibre has largely superseded this early technology. We have recently revisited it in the context of photonic crystals, and report here the realisation of a new kind of pure silica microstructured optical fibre which supports a robust single mode. Photonic crystals are periodically microstructured materials with a pitch on the scale of the optical wavelength. They have recently been the subject of much interest because of their unusual optical properties, including their ability to support a full photonic band gap. Several research teams have reported fabricating two-dimensional photonic crystal material out of glasses using selective etching processes. However, such a fabrication process results in samples of at most a few millimetres in the third dimension. The photonic crystal fibre described here is formed by creating a hexagonal silica/air preform (including a deliberate defect to guide light) on a macroscopic scale and then reducing its size by several orders of magnitude by pulling it into an optical fibre (see Fig 1)
All-silica single-mode optical fiber with photonic crystal cladding
We report the fabrication of a new type of optical waveguide: the photonic crystal fiber. It consists of a pure silica core surrounded by a silica-air photonic crystal material with a hexagonal symmetry. The fiber supports a single robust low-loss guided mode over a very broad spectral range of at least 458-1550 nm. Also see errata - http://eprints.soton.ac.uk/78010
The marriage record of Moody, John B. and Knight, Grace P
Marriage license for John B. Moody and Grace P. Knight. J.C. Lace was the officiant
Properties of photonic crystal fiber and the effective index model
We report on the waveguiding properties of a new type of low-loss optical waveguide. The photonic crystal fiber can be engineered to support only the fundamental guided mode at every wavelength within the transparency window of silica. Experimentally, a robust single mode has been observed over a wavelength range from 337nm to beyond 1550nm (restricted only by available wavelength sources). By studying the number of guided modes for fibers with different parameters and the use of an effective index model we are able to quantify the requirements for monomode operation. The requirements are independent of the scale of the fiber for sufficiently short wavelengths. Further support for the predictions of the effective index model is given by the variation of the spot size with wavelength
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