High Transmission through Sharp Bends in Photonic Crystal Waveguides

Mekis, Attila; Chen, J. C.; Kurland, I.; Fan, Shanhui; Villeneuve, Pierre R.; Joannopoulos, John D.

doi:10.1103/physrevlett.77.3787

Cited by 1,619 publications

(894 citation statements)

References 7 publications

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“…Excellent performance can even be obtained using materials with low dielectric constant (i.e., ε r < 3.0) that are usually less expensive and more commonly available than more exotic dielectrics with higher permittivity. Alternative techniques for spatial control of waves within a lattice include structures produced by transformation optics [45], waveguides [46,47], graded-index devices [48][49][50], introduction of defects [43], and graded photonic crystals [51][52][53][54][55]. Spatially-variant self-collimation is unique because it spatially varies the orientation of the unit cells within an otherwise monolithic and uniform lattice.…”

Section: Introductionmentioning

confidence: 99%

3d Printed Lattices With Spatially Variant Self-Collimation

Rumpf¹,

Pazos²,

Garcia³

et al. 2013

PIER

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Abstract-In this work, results are given for controlling waves arbitrarily inside a lattice with spatially variant self-collimation. To demonstrate the concept, an unguided beam was made to flow around a 90 • bend without scattering due to the bend or the spatial variance. Control of the field was achieved by spatially varying the orientation of the unit cells throughout a self-collimating photonic crystal, but in a manner that almost completely eliminated deformations to the size and shape of the unit cells. The device was all-dielectric, monolithic, and made from an ordinary dielectric with low relative permittivity (ε r = 2.45). It was manufactured by fused deposition modeling, a form of 3D printing, and its performance confirmed experimentally at around 15 GHz.

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Section: Introductionmentioning

confidence: 99%

3d Printed Lattices With Spatially Variant Self-Collimation

Rumpf¹,

Pazos²,

Garcia³

et al. 2013

PIER

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“…2). [20] Furthermore, various defect designs have been proposed and, in some cases, realized for low-loss waveguides containing sharp bends, [8] channel drop filters, [21,22] and T-shaped branches. [23] By introducing active materials (e.g., quantum wells or dots) in the design of the PhC the possibility of using point defects as resonant cavities for lasing action has also been demonstrated.…”

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confidence: 99%

Introducing Defects in 3D Photonic Crystals: State of the Art

2006

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Public Reporting burden for this collection of information is estimated to average 1 hour per response, including the time for reviewing instructions, searching existing data sources, gathering and maintaining the data needed, and completing and reviewing the collection of information. Send comment regarding this burden estimates or any other aspect of this collection of information, including suggestions for reducing this burden, to Washington Headquarters Services, Directorate for information Operations and Reports, 1215 Jefferson Davis Highway, Suite 1204, Arlington, VA 22202-4302, and to the Office of Management and Budget, Paperwork Reduction Project (0704-0188,) Washington, DC 20503. AGENCY USE ONLY ( Leave Blank)2. REPORT DATE Advanced Materials, 18, 2665-2678 (2006). 3D photonic crystals (PhCs) and photonic bandgap (PBG) materials have attracted considerable scientific and technological interest. In order to provide functionality to PhCs, the introduction of controlled defects is necessary; the importance of defects in PhCs is comparable to that of dopants in semiconductors. Over the past few years, significant advances have been achieved through a diverse set of fabrication techniques. While for some routes to 3D PhCs, such as conventional lithography, the incorporation of defects is relatively straightforward; other methods, for example, selfassembly of colloidal crystals (CCs) or holography, require new external methods for defect incorporation. In this review, we will cover the state of the art in the design and fabrication of defects within 3D PhCs. The figure displays a fluorescence laser scanning confocal microscopy image of a y-splitter defect formed through two-photon polymerization within a CC. SUBJECT TERMS 15. NUMBER OF PAGES 1416. PRICE CODE SECURITY CLASSIFICATION OR REPORT UNCLASSIFIED SECURITY CLASSIFICATION ON THIS PAGE UNCLASSIFIED SECURITY CLASSIFICATION OF ABSTRACT UNCLASSIFIED LIMITATION OF ABSTRACT UL IntroductionPhotonic crystals (PhCs) are materials that possess spatial periodicity in their dielectric constant on the order of the wavelength (k) of light. These materials can strongly modulate light [1] and, with sufficient dielectric contrast and an appropriate geometry, may exhibit a photonic bandgap (PBG). This concept was first proposed in 1975 by Bykov [2] but remained relatively unknown until the seminal work of Yablonovitch [3] and John. [4] In a rough analogy to semiconductors, which possess an electronic bandgap, a PBG material prohibits the existence of photons with energies in the PBG. PhCs are naturally classified by the dimensionality of their periodicity, and in order to rigorously prevent the propagation of PBG frequencies in all directions, a 3D PhC with an omnidirectional, or complete PBG (cPBG) is required. cPBG materials have been fabricated and well characterized for operation at microwave and radio frequencies, however, operation in the visible and IR requires the characteristic length scales of these structures to be scaled down by several orders of magnitude...

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“…there is nowhere else for it to go to. Sharp bends and large-angle Y-junctions have been computationally`demonstrateda with virtually no excess losses [120,121]. These are impressive results that certainly point in the right direction.…”

Section: Photonic Vlsimentioning

confidence: 53%

Photonic crystals in the optical regime â past, present and future

Krauss

Rue

1999

Progress in Quantum Electronics

442

141

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During the last decade, photonic crystals, also known as photonic microstructures or photonic bandgap structures, have matured from an intellectual curiosity concerning electromagnetic waves to a "eld with real applications in both the microwave and optical regime. In this review, we shall focus on progress and the prospects for semiconductor structures that mainly involve guided modes interacting with periodic structures, but we also evaluate alternative material systems and fabrication methods, e.g. those based on self-organisation. We shall go from basic concepts, via a discussion of the state of the art, to device applications. Naturally, the discussion of the applications will be more speculative, but we attempt to evaluate the real prospects o!ered by photonic crystals at optical frequencies while considering practical limitations. In doing so, we identify a variety of areas such as the combination of quantum dot light emitters with photonic crystals that seem particularly promising. We discuss the prospects for enhanced light}matter interactions in photonic crystals and the related material and design issues. Overall, the aim of this review is to introduce the reader to the concepts of photonic crystals, describe the state of the art and attempt to answer the question of what uses these peculiar structures may have.

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High Transmission through Sharp Bends in Photonic Crystal Waveguides

Cited by 1,619 publications

References 7 publications

3d Printed Lattices With Spatially Variant Self-Collimation

3d Printed Lattices With Spatially Variant Self-Collimation

Introducing Defects in 3D Photonic Crystals: State of the Art

Photonic crystals in the optical regime â past, present and future

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High Transmission through Sharp Bends in Photonic Crystal Waveguides

Cited by 1,619 publications

References 7 publications

3d Printed Lattices With Spatially Variant Self-Collimation

3d Printed Lattices With Spatially Variant Self-Collimation

Introducing Defects in 3D Photonic Crystals: State of the Art

Photonic crystals in the optical regime â past, present and future

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Product

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Photonic crystals in the optical regime â past, present and future