Visible-wavelength super-refraction in photonic crystal superprisms

Baumberg, Jeremy J.; Netti, M.C.; Perney, N.M.B.; Charlton, Martin D. B.; Zoorob, M.E.; Parker, Geoffrey

doi:10.1063/1.1772521

Cited by 48 publications

(29 citation statements)

References 17 publications

(10 reference statements)

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“…Applications utilizing the photonic band structure include optical time-delay devices, dispersion compensators and superprisms. Superprisms are PC devices that are able to refract incoming light over much greater angles than their conventional glass prism counterparts, with clear applications in wavelength division multiplexing systems (Baumberg et al 2004). If, and when, we are able to produce perfect three-dimensional PC structures, a whole new world is opened up to us.…”

Section: Some Applications Of Photonic Crystalsmentioning

confidence: 99%

Highly engineered mesoporous structures for optical processing

Parker

Charlton

Zoorob³

et al. 2005

Phil. Trans. R. Soc. A.

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Arranging periodic, or quasi-periodic, regions of differing refractive index in one, two, or three dimensions can form a unique class of mesoporous structures. These structures are generally known as photonic crystals, or photonic quasicrystals, and they are the optical analogue of semiconducting materials. Whereas a semiconductor's band structure arises from the interaction of electron or hole waves with an arrangement of ion cores, the photonic crystal band structure results from the interaction of light waves with an arrangement of regions of differing refractive index.What makes photonic crystals highly attractive to the optical engineer is that we can actually place the regions of differing refractive index in a pattern specifically tailored to produce a given optical function, such as an extremely high dispersion, for example. That is, we can define the geometrical arrangement of the dielectric foam to provide us with the form of band structure we require for our optical functionality.In this paper, the optical properties and applications of these highly engineered mesoporous dielectrics will be discussed.

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Section: Some Applications Of Photonic Crystalsmentioning

confidence: 99%

Highly engineered mesoporous structures for optical processing

Parker

Charlton

Zoorob³

et al. 2005

Phil. Trans. R. Soc. A.

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“…Perhaps the best-known propagation effect in PCs is the so-called self-collimation or the disappearance of diffraction [5][6][7][8][9][10], where, due to the flattening of the segments of the spatial dispersion curve the spatial envelope of the Bloch mode propagates without diffractive broadening. The dispersion curve can also present strongly tilted segments, which leads to super-refraction and negative refraction effects [11,12]. It has been recently proposed that the PCs can lead to the modification of the angular spectra of the transmitted beams [13], the effect that could be at the basis of an interesting type of spatial filter.…”

Section: Introductionmentioning

confidence: 99%

Signatures of light-beam spatial filtering in a three-dimensional photonic crystal

et al. 2010

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We report experimental evidence of spatial filtering of light beams by three-dimensional, low-refraction-indexcontrast photonic crystals. The photonic crystals were fabricated in a glass bulk, where the refraction index has been periodically modulated using tightly focused femtosecond laser pulses. We observe filtered areas in the angular distributions of the transmitted radiation, and we interpret the observations by theoretical and numerical study of light propagation in index-modulated material in paraxial model.

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“…The second class of applications include devices such as PC superprisms [3,4] and optical time-delay elements [5,6] which make use of the dispersive properties of PCs. These require low loss transmission through the bulk of the phonic crystal across hundreds or even thousands of lattice periods.…”

Section: Introductionmentioning

confidence: 99%

Realisation of ultra-low loss photonic crystal slab waveguide devices

Charlton¹,

Zoorob²,

Netti³

et al. 2005

Microelectronics Journal

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In this paper we demonstrate low loss transmission both above and below the primary band-gap for a photonic crystal (PC) super-prism device consisting of 600 lattice periods. By modifying the refractive index of the holes, we reduce overall insertion loss to just 4.5 dB across the entire visible spectrum. We show that the remaining loss is predominantly due to impedance mismatch at the boundaries between patterned and unpatterned slab waveguide regions. Experimental loss measurements compare well with finite difference time domain simulations. q

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Visible-wavelength super-refraction in photonic crystal superprisms

Cited by 48 publications

References 17 publications

Highly engineered mesoporous structures for optical processing

Highly engineered mesoporous structures for optical processing

Signatures of light-beam spatial filtering in a three-dimensional photonic crystal

Realisation of ultra-low loss photonic crystal slab waveguide devices

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