Finite-geometry models of electric field noise from patch potentials in ion traps

We model electric field noise from fluctuating patch potentials on conducting surfaces by taking into account the finite geometry of the ion trap electrodes to gain insight into the origin of anomalous heating in ion traps. The scaling of anomalous heating rates with surface distance d is obtained f...

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Veröffentlicht in:	Physical review. A, Atomic, molecular, and optical physics Atomic, molecular, and optical physics, 2011-11, Vol.84 (5), Article 053425
Hauptverfasser:	Low, Guang Hao, Herskind, Peter F., Chuang, Isaac L.
Format:	Artikel
Sprache:	eng
Schlagworte:	ATOMIC AND MOLECULAR PHYSICS EIGENFUNCTIONS ELECTRIC FIELDS GAIN GREEN FUNCTION HEATING RATE LAPLACE EQUATION NOISE POTENTIALS SURFACES TRAPS
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container_title	Physical review. A, Atomic, molecular, and optical physics
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creator	Low, Guang Hao Herskind, Peter F. Chuang, Isaac L.
description	We model electric field noise from fluctuating patch potentials on conducting surfaces by taking into account the finite geometry of the ion trap electrodes to gain insight into the origin of anomalous heating in ion traps. The scaling of anomalous heating rates with surface distance d is obtained for several generic geometries of relevance to current ion trap designs, ranging from planar to spheroidal electrodes. The influence of patch size is studied both by solving Laplace's equation in terms of the appropriate Green's function as well as through an eigenfunction expansion. Scaling with surface distance is found to be highly dependent on the choice of geometry and the relative scale between the spatial extent of the electrode, the ion-electrode distance, and the patch size. Our model generally supports the d{sup -4} dependence currently found by most experiments and models, but also predicts geometry-driven deviations from this trend.
doi_str_mv	10.1103/PhysRevA.84.053425
format	Article
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A, Atomic, molecular, and optical physics</title><description>We model electric field noise from fluctuating patch potentials on conducting surfaces by taking into account the finite geometry of the ion trap electrodes to gain insight into the origin of anomalous heating in ion traps. The scaling of anomalous heating rates with surface distance d is obtained for several generic geometries of relevance to current ion trap designs, ranging from planar to spheroidal electrodes. The influence of patch size is studied both by solving Laplace's equation in terms of the appropriate Green's function as well as through an eigenfunction expansion. Scaling with surface distance is found to be highly dependent on the choice of geometry and the relative scale between the spatial extent of the electrode, the ion-electrode distance, and the patch size. 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subjects	ATOMIC AND MOLECULAR PHYSICS EIGENFUNCTIONS ELECTRIC FIELDS GAIN GREEN FUNCTION HEATING RATE LAPLACE EQUATION NOISE POTENTIALS SURFACES TRAPS
title	Finite-geometry models of electric field noise from patch potentials in ion traps
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