3d Printed Lattices With Spatially Variant Self-Collimation

Rumpf, Raymond C.; Pazos, Javier; Garcia, Chance; Ochoa, Luis; Wicker, Ryan B.

doi:10.2528/pier13030507

Cited by 58 publications

(51 citation statements)

References 65 publications

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“…No coordinate transform was needed and TO was circumvented in this manner. The first demonstration of a self-collimating SVPC was at microwave frequencies [56]. This device, shown in figure 2a, operated at around 15 GHz and flowed an unguided beam around a sharp 90 • bend.…”

Section: Spatially Variant Photonic Crystalsmentioning

confidence: 99%

Spatially variant periodic structures in electromagnetics

Rumpf

Pazos

Digaum

et al. 2015

Phil. Trans. R. Soc. A.

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Section: Spatially Variant Photonic Crystalsmentioning

confidence: 99%

Spatially variant periodic structures in electromagnetics

Rumpf

Pazos

Digaum

et al. 2015

Phil. Trans. R. Soc. A.

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“…Ideally, EBG devices are 3D periodic arrays of geometric structures that prevent the propagation of EM waves for a given frequency band at all incident angles independent of polarization. In practice, however, partial bandgaps are observed which cover limited incident angles [16].…”

Section: Progress History Of Engineered Em Materialsmentioning

confidence: 99%

“…Prototyping processes can be classified into two classes: (i) Subtractive manufacturing: used in traditional fabrication and involves removal of material by methods such as drilling on a macroscale and lithography on a micro/nano scale; (ii) Additive manufacturing: newer technology where a 3D object can be made based on a predefined digital model [24,60]. Examples include 3D printing on a macro-scale [16,57] and ink-jet deposition of nanoscale structures [31,56].…”

Section: Rapid Prototyping Of Electromagnetic Media Devicesmentioning

confidence: 99%

Rapid Prototyping across the Spectrum: RF to Optical 3D Electromagnetic Structures

Allen¹,

Allen²,

Wenner³

2015

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“…As an example, we take a spatially varying square lattice which changes in the lattice orientation parameter as per the azimuthal angle. This lattice is important as it has been shown to guide light through a 90° bend 4,16 by self-collimation phenomena 19 and could be a very useful photonic element. To understand the phase mask synthesis process, we start with the case of a multiple beam interference wave-field where all the beams are spread symmetrically along the surface of a cone making same 3 tilt angle with the normal.…”

mentioning

confidence: 99%

Optical generation of a spatially variant two-dimensional lattice structure by using a phase only spatial light modulator

Kumar

Joseph

2014

Applied Physics Letters

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We propose a simple and straightforward method to generate a spatially variant lattice structures by optical interference lithography method. Using this method, it is possible to independently vary the orientation and period of the two-dimensional lattice. The method consists of two steps which are: numerical synthesis of corresponding phase mask by employing a two-dimensional integrated gradient calculations and experimental implementation of synthesized phase mask by making use of a phase only spatial light modulator in an optical 4f Fourier filtering setup. As a working example, we provide the experimental fabrication of a spatially variant square lattice structure which has the possibility to guide a Gaussian beam through a 90° bend by photonic crystal self-collimation phenomena. The method is digitally reconfigurable, is completely scalable and could be extended to other kind of lattices as well.Photonic crystals are the ultimate structured materials with the ability to control the flow of light 1 which leads to so many applications. But perfectly periodic photonic crystals have limited functionality and it becomes essential to have more degrees of freedom in photonic crystal design to make way for more devices. More degrees of freedom could be added by spatially varying some of the properties of photonic crystal i.e. lattice orientation, lattice spacing and fill-factor 2-4 etc. A single step, low cost, large area fabrication of periodic (or quasi periodic) photonic crystal structures is possible by the method of interference lithography 5,6 and few recent advances with phase only spatial light modulator (SLM) assisted interference lithography has enabled the fabrication of some unconventional photonic crystal structures. These structures include embedding of defect sites 7-9 , creation of line defects 10 , dual lattice structures 11 and gradient structures 12,13 .

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3d Printed Lattices With Spatially Variant Self-Collimation

Cited by 58 publications

References 65 publications

Spatially variant periodic structures in electromagnetics

Spatially variant periodic structures in electromagnetics

Rapid Prototyping across the Spectrum: RF to Optical 3D Electromagnetic Structures

Optical generation of a spatially variant two-dimensional lattice structure by using a phase only spatial light modulator

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