2012
DOI: 10.1002/andp.201200189
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Strong‐field photoemission from silicon field emitter arrays

Abstract: Strong-field photoemission from silicon field emitter arrays is investigated experimentally and results are explained using a "simple-man" optical-field emission model. Spectra are collected throughout an in-situ laser annealing process, leading to a red-shift in emitted electron energy along with an increase in electron yield. After the annealing process, a high energy plateau is formed which is explained through optical-field emission along with electron re-scattering with the tip surface.

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Cited by 40 publications
(43 citation statements)
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“…Due primarily to the tip's sharp geometry, the field enhancement is typically <10, and the temporal profile of the enhanced field, F tip (t), approximately follows that of the instantaneous incident field 21,22 . With typical incident intensities, F tip (t) can drive strong-field processes: photoemission current yields and photoelectron energy spectra from nanotips have shown strong-field characteristics [3][4][5]7,10,11,14,15 , and exciting nanotips with phase-stabilized laser pulses, CEP-sensitive signatures have been observed 5,14 . Compared with nanotips, metallic nanoparticles offer higher field enhancements as well as additional resonant and geometric degrees of freedom.…”
mentioning
confidence: 99%
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“…Due primarily to the tip's sharp geometry, the field enhancement is typically <10, and the temporal profile of the enhanced field, F tip (t), approximately follows that of the instantaneous incident field 21,22 . With typical incident intensities, F tip (t) can drive strong-field processes: photoemission current yields and photoelectron energy spectra from nanotips have shown strong-field characteristics [3][4][5]7,10,11,14,15 , and exciting nanotips with phase-stabilized laser pulses, CEP-sensitive signatures have been observed 5,14 . Compared with nanotips, metallic nanoparticles offer higher field enhancements as well as additional resonant and geometric degrees of freedom.…”
mentioning
confidence: 99%
“…For instance, when an intense laser pulse interacts with an atomic gas, individual cycles of the incident electric field ionize gas atoms and steer the resulting attosecond-duration electrical wavepackets 1,2 . Such field-controlled light-matter interactions form the basis of attosecond science and have recently expanded from gases to solid-state nanostructures [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] . Here, we extend these field-controlled interactions to metallic nanoparticles supporting localized surface plasmon resonances.…”
mentioning
confidence: 99%
“…Highresolution electron-beam lithography may facilitate production of bright, ultrafast, high-repetition-rate electron sources via creation of nanoscale electron-emitter dimensions, thus limiting the effective source size, and allowing for improved cathode brightness, and enhancement of the optical field to allow operation at lower applied laser intensity [1,2,6,7]. Additionally, the design of nanostructured metallic photocathodes with localized surface plasmon resonance (LSPR) modes may allow further enhancement of local electric fields, thus allowing increased electron emission via multiphoton absorption or strong optical field emission [1,2,[7][8][9][10][11][12].…”
Section: Introductionmentioning
confidence: 99%
“…Nonlinear photoelectron emission, a prominent phenomenon in this area, has been intensively studied for various individual metallic nanostructures, 1-9 thin films 10,11 or antenna arrays, [12][13][14][15] with motivations for optically-controlled electron propagation in ultrafast electronics, 16 ultrafast electron [17][18][19] and x-ray sources, 20 as well as phase-resolved imaging and spectroscopy. 16,21 Metal nanotips displaying broadband near-field enhancements present a prominent model system for highly nonlinear photoelectron emission and acceleration, and studies have been conducted in the visible to near-infrared, 1,3,7,22,23 mid-infrared 6 and Terahertz ranges 16,24 Nanoparticles and plasmonic antennas constitute another platform for photoemission studies, 8,9,15,25 as they exhibit field enhancements from resonant surface plasmon modes, [25][26][27] which may be further amplified by geometric edge enhancements.…”
mentioning
confidence: 99%