Origin and reduction of wakefields in photonic crystal accelerator cavities

Origin and reduction of wakefields in photonic crystal accelerator cavities

Photonic crystal (PhC) defect cavities that support an accelerating mode tend to trap unwanted higher-order modes (HOMs) corresponding to zero-group-velocity PhC lattice modes at frequencies near the top of bandgaps. The effect is explained quite generally by photonic band and perturbation theoretic...

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Veröffentlicht in:Physical review special topics. PRST-AB. Accelerators and beams 2014-05, Vol.17 (5), p.051301, Article 051301
Hauptverfasser: Bauer, Carl A., Werner, Gregory R., Cary, John R.
Format: Artikel
Sprache:eng
Schlagworte:
Crystal defects
Damping
Energy gap
Holes
Lattice vibration
Perturbation
Photonic crystals
Sapphire
Waveguides
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Zusammenfassung:Photonic crystal (PhC) defect cavities that support an accelerating mode tend to trap unwanted higher-order modes (HOMs) corresponding to zero-group-velocity PhC lattice modes at frequencies near the top of bandgaps. The effect is explained quite generally by photonic band and perturbation theoretical arguments. Transverse wakefields resulting from this effect are observed (via simulation) in a 12 GHz hybrid dielectric PhC accelerating cavity based on a triangular lattice of sapphire rods. These wakefields are, on average, an order of magnitude higher than those in the 12 GHz waveguide-damped Compact Linear Collider copper cavities. The avoidance of translational symmetry (and, thus, the bandgap concept) can dramatically improve HOM damping in PhC-based structures.
ISSN:1098-4402
1098-4402
2469-9888
DOI:10.1103/PhysRevSTAB.17.051301