Particle acceleration using top-illuminated nanophotonic dielectric structures

R. Shiloh; T. Chlouba; P. Yousefi; P. Hommelhoff

doi:https://doi.org/10.1364/OE.420235

Particle acceleration using top-illuminated nanophotonic dielectric structures

R. Shiloh, T. Chlouba, P. Yousefi, P. Hommelhoff

Research output: Contribution to journal › Article › peer-review

Abstract

In dielectric laser acceleration, nanostructures etched into silicon are used to convert free-space ultrashort laser pulses, incident from the side and parallel to the wafer substrate, to accelerate particles. This current approach is experimentally challenging and, as it turns out, not quite necessary for most experiments and practical applications. Here, we experimentally demonstrate and numerically verify the efficacy of top-illuminated structures, and measure a maximum acceleration gradient of 49.2 ± 3.1 MeV/m. We discuss how, in practice, this approach proves superior to the current standard in the field, and expect it to become the definitive choice for nanophotonic particle laser acceleration.

Original language	English
Pages (from-to)	14403-14411
Number of pages	9
Journal	Optics Express
Volume	29
Issue number	10
DOIs	https://doi.org/10.1364/OE.420235
State	Published - 10 May 2021
Externally published	Yes

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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title = "Particle acceleration using top-illuminated nanophotonic dielectric structures",

abstract = "In dielectric laser acceleration, nanostructures etched into silicon are used to convert free-space ultrashort laser pulses, incident from the side and parallel to the wafer substrate, to accelerate particles. This current approach is experimentally challenging and, as it turns out, not quite necessary for most experiments and practical applications. Here, we experimentally demonstrate and numerically verify the efficacy of top-illuminated structures, and measure a maximum acceleration gradient of 49.2 ± 3.1 MeV/m. We discuss how, in practice, this approach proves superior to the current standard in the field, and expect it to become the definitive choice for nanophotonic particle laser acceleration.",

author = "R. Shiloh and T. Chlouba and P. Yousefi and P. Hommelhoff",

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T1 - Particle acceleration using top-illuminated nanophotonic dielectric structures

AU - Shiloh, R.

AU - Chlouba, T.

AU - Yousefi, P.

AU - Hommelhoff, P.

PY - 2021/5/10

Y1 - 2021/5/10

N2 - In dielectric laser acceleration, nanostructures etched into silicon are used to convert free-space ultrashort laser pulses, incident from the side and parallel to the wafer substrate, to accelerate particles. This current approach is experimentally challenging and, as it turns out, not quite necessary for most experiments and practical applications. Here, we experimentally demonstrate and numerically verify the efficacy of top-illuminated structures, and measure a maximum acceleration gradient of 49.2 ± 3.1 MeV/m. We discuss how, in practice, this approach proves superior to the current standard in the field, and expect it to become the definitive choice for nanophotonic particle laser acceleration.

AB - In dielectric laser acceleration, nanostructures etched into silicon are used to convert free-space ultrashort laser pulses, incident from the side and parallel to the wafer substrate, to accelerate particles. This current approach is experimentally challenging and, as it turns out, not quite necessary for most experiments and practical applications. Here, we experimentally demonstrate and numerically verify the efficacy of top-illuminated structures, and measure a maximum acceleration gradient of 49.2 ± 3.1 MeV/m. We discuss how, in practice, this approach proves superior to the current standard in the field, and expect it to become the definitive choice for nanophotonic particle laser acceleration.

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M3 - مقالة

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SN - 1094-4087

VL - 29

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EP - 14411

JO - Optics Express

JF - Optics Express

IS - 10

ER -

Particle acceleration using top-illuminated nanophotonic dielectric structures

Abstract

All Science Journal Classification (ASJC) codes

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