Mode confinement in photonic quasicrystal point-defect cavities for particle accelerators

Gennaro, Emiliano Di; Savo, Salvatore; Andreone, A.; Galdi, Vincenzo; Castaldi, G.; Pierro, V.; Masullo, M.R.

doi:10.1063/1.2999581

Cited by 21 publications

(22 citation statements)

References 15 publications

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“…Like photonic crystals, PQC's can demonstrate directive emission, 5 mode confinement, 6 and superlensing. 7 A one-dimensional photonic band gap has been observed in dielectric multilayers stacked according to a Fibonacci series. 8 Dielectrics arranged according to quasiperiodic geometries such as octagonal (8-fold), decagonal (10-fold), and dodecagonal (12-fold) are shown to have a two-dimensional PBG.…”

Section: Introductionmentioning

confidence: 99%

Isotropic properties of the photonic band gap in quasicrystals with low-index contrast

et al. 2011

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We report on the formation and development of the photonic band gap in two-dimensional 8-, 10-, and 12-fold symmetry quasicrystalline lattices of low-index contrast. Finite-size structures made of dielectric cylindrical rods were studied and measured in the microwave region, and their properties were compared with a conventional hexagonal crystal. Band-gap characteristics were investigated by changing the direction of propagation of the incident beam inside the crystal. Various angles of incidence from 0 • to 30 • were used to investigate the isotropic nature of the band gap. The arbitrarily high rotational symmetry of aperiodically ordered structures could be practically exploited to manufacture isotropic band-gap materials, which are perfectly suitable for hosting waveguides or cavities.

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Section: Introductionmentioning

confidence: 99%

Isotropic properties of the photonic band gap in quasicrystals with low-index contrast

et al. 2011

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“…This radiative damping decreases the Q factor of the dipole modes, making the wake damp faster. This kind of PBG structure has been extensively researched theoretically and experimentally [23][24][25]. A 17 GHz six-cell traveling-wave PBG accelerator structure has previously been designed, simulated, and tested at the MIT Plasma Science and Fusion Center (PSFC) [8,9].…”

Section: Introductionmentioning

confidence: 99%

Calculation of wakefields in a 17 GHz beam-driven photonic band-gap accelerator structure

Munroe

Shapiro

et al. 2013

Phys. Rev. ST Accel. Beams

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We present the theoretical analysis and computer simulation of the wakefields in a 17 GHz photonic band-gap (PBG) structure for accelerator applications. Using the commercial code CST PARTICLE STUDIO, the fundamental accelerating mode and dipole modes are excited by passing an 18 MeV electron beam through a seven-cell traveling-wave PBG structure. The characteristics of the longitudinal and transverse wakefields, wake potential spectrum, dipole mode distribution, and their quality factors are calculated and analyzed theoretically. Unlike in conventional disk-loaded waveguide (DLW) structures, three dipole modes (TM 11 -like, TM 12 -like, and TM 13 -like) are excited in the PBG structure with comparable initial amplitudes. These modes are separated by less than 4 GHz in frequency and are damped quickly due to low radiative Q factors. Simulations verify that a PBG structure provides wakefield damping relative to a DLW structure. Simulations were done with both single-bunch excitation to determine the frequency spectrum of the wakefields and multibunch excitation to compare to wakefield measurements taken at MIT using a 17 GHz bunch train. These simulation results will guide the design of next-generation highgradient accelerator PBG structures.

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“…Recent advances in the study of photonic structures for accelerator applications include research on hybrid structures consisting of metallic and dielectric components [10,11]; research on quasicrystals [12]; research on disordered photonic structures [13]; research on truncated, optimized photonic structures [14]; and theoretical research on wakefields [15].…”

Section: Introductionmentioning

confidence: 99%

X-band photonic band-gap accelerator structure breakdown experiment

Marsh

Shapiro

Temkin

et al. 2011

Phys. Rev. ST Accel. Beams

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In order to understand the performance of photonic band-gap (PBG) structures under realistic high gradient, high power, high repetition rate operation, a PBG accelerator structure was designed and tested at X band (11.424 GHz). The structure consisted of a single test cell with matching cells before and after the structure. The design followed principles previously established in testing a series of conventional pillbox structures. The PBG structure was tested at an accelerating gradient of 65 MV=m yielding a breakdown rate of two breakdowns per hour at 60 Hz. An accelerating gradient above 110 MV=m was demonstrated at a higher breakdown rate. Significant pulsed heating occurred on the surface of the inner rods of the PBG structure, with a temperature rise of 85 K estimated when operating in 100 ns pulses at a gradient of 100 MV=m and a surface magnetic field of 890 kA=m. A temperature rise of up to 250 K was estimated for some shots. The iris surfaces, the location of peak electric field, surprisingly had no damage, but the inner rods, the location of the peak magnetic fields and a large temperature rise, had significant damage. Breakdown in accelerator structures is generally understood in terms of electric field effects. These PBG structure results highlight the unexpected role of magnetic fields in breakdown. The hypothesis is presented that the moderate level electric field on the inner rods, about 14 MV=m, is enhanced at small tips and projections caused by pulsed heating, leading to breakdown. Future PBG structures should be built to minimize pulsed surface heating and temperature rise.

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Mode confinement in photonic quasicrystal point-defect cavities for particle accelerators

Cited by 21 publications

References 15 publications

Isotropic properties of the photonic band gap in quasicrystals with low-index contrast

Isotropic properties of the photonic band gap in quasicrystals with low-index contrast

Calculation of wakefields in a 17 GHz beam-driven photonic band-gap accelerator structure

X-band photonic band-gap accelerator structure breakdown experiment

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