Home > Publications database > On-Chip Petahertz Electronics for Single-Shot Phase Detection > print

001     585148
005     20251014093403.0
024 7 _ |a 10.1038/s41467-024-53788-z
|2 doi
024 7 _ |a 10.3204/PUBDB-2023-03421
|2 datacite_doi
024 7 _ |a altmetric:171002738
|2 altmetric
024 7 _ |a pmid:39580474
|2 pmid
024 7 _ |a WOS:001362684200007
|2 WOS
024 7 _ |2 openalex
|a openalex:W4404645458
037 _ _ |a PUBDB-2023-03421
041 _ _ |a English
082 _ _ |a 500
100 1 _ |a Ritzkowsky, Felix
|0 P:(DE-H253)PIP1085492
|b 0
|e Corresponding author
245 _ _ |a On-Chip Petahertz Electronics for Single-Shot Phase Detection
260 _ _ |a [London]
|c 2024
|b Nature Publishing Group UK
336 7 _ |a article
|2 DRIVER
336 7 _ |a Output Types/Journal article
|2 DataCite
336 7 _ |a Journal Article
|b journal
|m journal
|0 PUB:(DE-HGF)16
|s 1734604972_44243
|2 PUB:(DE-HGF)
336 7 _ |a ARTICLE
|2 BibTeX
336 7 _ |a JOURNAL_ARTICLE
|2 ORCID
336 7 _ |a Journal Article
|0 0
|2 EndNote
520 _ _ |a Attosecond science has demonstrated that electrons can be controlled on the sub-cycle time scale of an optical waveform, paving the way towards optical frequency electronics. However, these experiments historically relied on high-energy laser pulses and detection not suitable for microelectronic integration. For practical optical frequency electronics, a system suitable for integration and capable of generating detectable signals with low pulse energies is needed. While current from plasmonic nanoantenna emitters can be driven at optical frequencies, low charge yields have been a significant limitation. In this work we demonstrate that large-scale electrically connected plasmonic nanoantenna networks, when driven in concert, enable charge yields sufficient for single-shot carrier-envelope phase detection at repetition rates exceeding tens of kilohertz. We not only show that limitations in single-shot CEP detection techniques can be overcome, but also demonstrate a flexible approach to optical frequency electronics in general, enabling future applications such as high sensitivity petahertz-bandwidth electric field sampling or logic-circuits.
536 _ _ |a 631 - Matter – Dynamics, Mechanisms and Control (POF4-631)
|0 G:(DE-HGF)POF4-631
|c POF4-631
|f POF IV
|x 0
536 _ _ |a AXSIS - Frontiers in Attosecond X-ray Science: Imaging and Spectroscopy (609920)
|0 G:(EU-Grant)609920
|c 609920
|f ERC-2013-SyG
|x 1
536 _ _ |a DFG project G:(GEPRIS)390715994 - EXC 2056: CUI: Advanced Imaging of Matter (390715994)
|0 G:(GEPRIS)390715994
|c 390715994
|x 2
536 _ _ |a DFG project G:(GEPRIS)453615464 - Dielektrischer Laserbeschleuniger im mittleren Infrarotbereich (453615464)
|0 G:(GEPRIS)453615464
|c 453615464
|x 3
542 _ _ |i 2024-11-23
|2 Crossref
|u https://creativecommons.org/licenses/by/4.0
542 _ _ |i 2024-11-23
|2 Crossref
|u https://creativecommons.org/licenses/by/4.0
588 _ _ |a Dataset connected to CrossRef, Journals: bib-pubdb1.desy.de
693 _ _ |a SINBAD
|e AXSIS: Frontiers in Attosecond X-ray Science, Imaging and Spectroscopy
|1 EXP:(DE-H253)SINBAD-20200101
|0 EXP:(DE-H253)AXSIS-20200101
|5 EXP:(DE-H253)AXSIS-20200101
|x 0
700 1 _ |a Yeung, Matthew
|0 P:(DE-H253)PIP1102613
|b 1
700 1 _ |a Bebeti, Engjell
|0 P:(DE-H253)PIP1098013
|b 2
700 1 _ |a Gebert, Thomas
|0 P:(DE-H253)PIP1006950
|b 3
700 1 _ |a Matsuyama, Toru
|0 P:(DE-H253)PIP1024769
|b 4
700 1 _ |a Budden, Matthias
|0 P:(DE-H253)PIP1026964
|b 5
700 1 _ |a Mainz, Roland
|0 P:(DE-H253)PIP1010355
|b 6
700 1 _ |a Cankaya, Hueseyin
|0 P:(DE-H253)PIP1015195
|b 7
700 1 _ |a Rossi, Giulio Maria
|0 P:(DE-H253)PIP1020878
|b 8
700 1 _ |a Berggren, Karl
|0 P:(DE-HGF)0
|b 9
700 1 _ |a Keathley, Phillip
|0 P:(DE-HGF)0
|b 10
700 1 _ |a Kärtner, Franz
|0 P:(DE-H253)PIP1013198
|b 11
773 1 8 |a 10.1038/s41467-024-53788-z
|b Springer Science and Business Media LLC
|d 2024-11-23
|n 1
|p 10179
|3 journal-article
|2 Crossref
|t Nature Communications
|v 15
|y 2024
|x 2041-1723
773 _ _ |a 10.1038/s41467-024-53788-z
|g Vol. 15, no. 1, p. 10179
|0 PERI:(DE-600)2553671-0
|n 1
|p 10179
|t Nature Communications
|v 15
|y 2024
|x 2041-1723
856 4 _ |u https://bib-pubdb1.desy.de/record/585148/files/Article%20Approval%20Service.pdf
856 4 _ |u https://bib-pubdb1.desy.de/record/585148/files/HTML-Approval_of_scientific_publication.html
856 4 _ |u https://bib-pubdb1.desy.de/record/585148/files/PDF-Approval_of_scientific_publication.pdf
856 4 _ |y OpenAccess
|u https://bib-pubdb1.desy.de/record/585148/files/2024_On-chip_Ritzkowsky_NC.pdf
856 4 _ |x pdfa
|u https://bib-pubdb1.desy.de/record/585148/files/Article%20Approval%20Service.pdf?subformat=pdfa
856 4 _ |y Restricted
|u https://bib-pubdb1.desy.de/record/585148/files/supplementary%20information.pdf
856 4 _ |y OpenAccess
|x pdfa
|u https://bib-pubdb1.desy.de/record/585148/files/2024_On-chip_Ritzkowsky_NC.pdf?subformat=pdfa
856 4 _ |y Restricted
|x pdfa
|u https://bib-pubdb1.desy.de/record/585148/files/supplementary%20information.pdf?subformat=pdfa
909 C O |o oai:bib-pubdb1.desy.de:585148
|p openaire
|p open_access
|p OpenAPC
|p driver
|p VDB
|p ec_fundedresources
|p openCost
|p dnbdelivery
910 1 _ |a Centre for Free-Electron Laser Science
|0 I:(DE-H253)_CFEL-20120731
|k CFEL
|b 0
|6 P:(DE-H253)PIP1085492
910 1 _ |a External Institute
|0 I:(DE-HGF)0
|k Extern
|b 1
|6 P:(DE-H253)PIP1102613
910 1 _ |a External Institute
|0 I:(DE-HGF)0
|k Extern
|b 2
|6 P:(DE-H253)PIP1098013
910 1 _ |a Centre for Free-Electron Laser Science
|0 I:(DE-H253)_CFEL-20120731
|k CFEL
|b 3
|6 P:(DE-H253)PIP1006950
910 1 _ |a Max-Planck-Gesellschaft zur Förderung der Wissenschaften
|0 I:(DE-588b)2019024-4
|k MPG
|b 3
|6 P:(DE-H253)PIP1006950
910 1 _ |a Centre for Free-Electron Laser Science
|0 I:(DE-H253)_CFEL-20120731
|k CFEL
|b 4
|6 P:(DE-H253)PIP1024769
910 1 _ |a Max-Planck-Gesellschaft zur Förderung der Wissenschaften
|0 I:(DE-588b)2019024-4
|k MPG
|b 4
|6 P:(DE-H253)PIP1024769
910 1 _ |a Centre for Free-Electron Laser Science
|0 I:(DE-H253)_CFEL-20120731
|k CFEL
|b 5
|6 P:(DE-H253)PIP1026964
910 1 _ |a Max-Planck-Gesellschaft zur Förderung der Wissenschaften
|0 I:(DE-588b)2019024-4
|k MPG
|b 5
|6 P:(DE-H253)PIP1026964
910 1 _ |a External Institute
|0 I:(DE-HGF)0
|k Extern
|b 6
|6 P:(DE-H253)PIP1010355
910 1 _ |a Deutsches Elektronen-Synchrotron
|0 I:(DE-588b)2008985-5
|k DESY
|b 7
|6 P:(DE-H253)PIP1015195
910 1 _ |a External Institute
|0 I:(DE-HGF)0
|k Extern
|b 7
|6 P:(DE-H253)PIP1015195
910 1 _ |a Deutsches Elektronen-Synchrotron
|0 I:(DE-588b)2008985-5
|k DESY
|b 8
|6 P:(DE-H253)PIP1020878
910 1 _ |a Centre for Free-Electron Laser Science
|0 I:(DE-H253)_CFEL-20120731
|k CFEL
|b 8
|6 P:(DE-H253)PIP1020878
910 1 _ |a External Institute
|0 I:(DE-HGF)0
|k Extern
|b 8
|6 P:(DE-H253)PIP1020878
910 1 _ |a MIT
|0 I:(DE-HGF)0
|b 9
|6 P:(DE-HGF)0
910 1 _ |a Deutsches Elektronen-Synchrotron
|0 I:(DE-588b)2008985-5
|k DESY
|b 11
|6 P:(DE-H253)PIP1013198
910 1 _ |a Centre for Free-Electron Laser Science
|0 I:(DE-H253)_CFEL-20120731
|k CFEL
|b 11
|6 P:(DE-H253)PIP1013198
910 1 _ |a European XFEL
|0 I:(DE-588)1043621512
|k XFEL.EU
|b 11
|6 P:(DE-H253)PIP1013198
913 1 _ |a DE-HGF
|b Forschungsbereich Materie
|l Von Materie zu Materialien und Leben
|1 G:(DE-HGF)POF4-630
|0 G:(DE-HGF)POF4-631
|3 G:(DE-HGF)POF4
|2 G:(DE-HGF)POF4-600
|4 G:(DE-HGF)POF
|v Matter – Dynamics, Mechanisms and Control
|x 0
914 1 _ |y 2024
915 _ _ |a Article Processing Charges
|0 StatID:(DE-HGF)0561
|2 StatID
|d 2023-08-29
915 _ _ |a WoS
|0 StatID:(DE-HGF)0113
|2 StatID
|b Science Citation Index Expanded
|d 2023-08-29
915 _ _ |a Fees
|0 StatID:(DE-HGF)0700
|2 StatID
|d 2023-08-29
915 _ _ |a OpenAccess
|0 StatID:(DE-HGF)0510
|2 StatID
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1190
|2 StatID
|b Biological Abstracts
|d 2023-08-29
915 _ _ |a Creative Commons Attribution CC BY 4.0
|0 LIC:(DE-HGF)CCBY4
|2 HGFVOC
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0160
|2 StatID
|b Essential Science Indicators
|d 2023-08-29
915 _ _ |a JCR
|0 StatID:(DE-HGF)0100
|2 StatID
|b NAT COMMUN : 2022
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0200
|2 StatID
|b SCOPUS
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0300
|2 StatID
|b Medline
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0501
|2 StatID
|b DOAJ Seal
|d 2024-01-30T07:48:07Z
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0500
|2 StatID
|b DOAJ
|d 2024-01-30T07:48:07Z
915 _ _ |a Peer Review
|0 StatID:(DE-HGF)0030
|2 StatID
|b DOAJ : Peer review
|d 2024-01-30T07:48:07Z
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0199
|2 StatID
|b Clarivate Analytics Master Journal List
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1040
|2 StatID
|b Zoological Record
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1060
|2 StatID
|b Current Contents - Agriculture, Biology and Environmental Sciences
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1150
|2 StatID
|b Current Contents - Physical, Chemical and Earth Sciences
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1050
|2 StatID
|b BIOSIS Previews
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1030
|2 StatID
|b Current Contents - Life Sciences
|d 2025-01-02
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0150
|2 StatID
|b Web of Science Core Collection
|d 2025-01-02
915 _ _ |a IF >= 15
|0 StatID:(DE-HGF)9915
|2 StatID
|b NAT COMMUN : 2022
|d 2025-01-02
915 p c |a APC keys set
|2 APC
|0 PC:(DE-HGF)0000
915 p c |a Local Funding
|2 APC
|0 PC:(DE-HGF)0001
915 p c |a DFG OA Publikationskosten
|2 APC
|0 PC:(DE-HGF)0002
915 p c |a DEAL: Springer Nature 01.01.2024
|2 APC
|0 PC:(DE-HGF)0178
915 p c |a DOAJ Journal
|2 APC
|0 PC:(DE-HGF)0003
920 1 _ |0 I:(DE-H253)FS-CFEL-2-20120731
|k FS-CFEL-2
|l Ultrafast Lasers & X-rays Division
|x 0
920 1 _ |0 I:(DE-H253)FS-LA-20130416
|k FS-LA
|l Laser Forschung und Entwicklung
|x 1
980 _ _ |a journal
980 _ _ |a VDB
980 _ _ |a UNRESTRICTED
980 _ _ |a I:(DE-H253)FS-CFEL-2-20120731
980 _ _ |a I:(DE-H253)FS-LA-20130416
980 _ _ |a APC
980 1 _ |a APC
980 1 _ |a FullTexts
999 C 5 |a 10.1098/rspl.1904.0143
|9 -- missing cx lookup --
|1 JA Fleming
|p 476 -
|2 Crossref
|u Fleming, J. A. On the conversion of electric oscillations into continuous currents by means of a vacuum valve. Proc. R. Soc. Lond. 74, 476–487 (1905).
|t Proc. R. Soc. Lond.
|v 74
|y 1905
999 C 5 |a 10.1038/nature10196
|9 -- missing cx lookup --
|1 M Krüger
|p 78 -
|2 Crossref
|u Krüger, M., Schenk, M. & Hommelhoff, P. Attosecond control of electrons emitted from a nanoscale metal tip. Nature 475, 78–81 (2011).
|t Nature
|v 475
|y 2011
999 C 5 |a 10.1038/s41586-022-05577-1
|9 -- missing cx lookup --
|1 HY Kim
|p 662 -
|2 Crossref
|u Kim, H. Y. et al. Attosecond field emission. Nature 613, 662–666 (2023).
|t Nature
|v 613
|y 2023
999 C 5 |a 10.1038/s41586-023-05839-6
|9 -- missing cx lookup --
|1 P Dienstbier
|p 702 -
|2 Crossref
|u Dienstbier, P. et al. Tracing attosecond electron emission from a nanometric metal tip. Nature 616, 702–706 (2023).
|t Nature
|v 616
|y 2023
999 C 5 |a 10.1038/nature11720
|9 -- missing cx lookup --
|1 M Schultze
|p 75 -
|2 Crossref
|u Schultze, M. et al. Controlling dielectrics with the electric field of light. Nature 493, 75–78 (2013).
|t Nature
|v 493
|y 2013
999 C 5 |a 10.1038/nature11567
|9 -- missing cx lookup --
|1 A Schiffrin
|p 70 -
|2 Crossref
|u Schiffrin, A. et al. Optical-field-induced current in dielectrics. Nature 493, 70–74 (2013).
|t Nature
|v 493
|y 2013
999 C 5 |a 10.1038/s41566-020-0690-1
|9 -- missing cx lookup --
|1 S Sederberg
|p 680 -
|2 Crossref
|u Sederberg, S. et al. Vectorized optoelectronic control and metrology in a semiconductor. Nat. Photonics 14, 680–685 (2020).
|t Nat. Photonics
|v 14
|y 2020
999 C 5 |a 10.1038/nature23900
|9 -- missing cx lookup --
|1 T Higuchi
|p 224 -
|2 Crossref
|u Higuchi, T., Heide, C., Ullmann, K., Weber, H. B. & Hommelhoff, P. Light-field-driven currents in graphene. Nature 550, 224–228 (2017).
|t Nature
|v 550
|y 2017
999 C 5 |a 10.1038/nphoton.2016.174
|9 -- missing cx lookup --
|1 T Rybka
|p 667 -
|2 Crossref
|u Rybka, T. et al. Sub-cycle optical phase control of nanotunnelling in the single-electron regime. Nat. Photonics 10, 667–670 (2016).
|t Nat. Photonics
|v 10
|y 2016
999 C 5 |a 10.1038/nphys3978
|9 -- missing cx lookup --
|1 WP Putnam
|p 335 -
|2 Crossref
|u Putnam, W. P., Hobbs, R. G., Keathley, P. D., Berggren, K. K. & Kärtner, F. X. Optical-field-controlled photoemission from plasmonic nanoparticles. Nat. Phys. 13, 335–339 (2017).
|t Nat. Phys.
|v 13
|y 2017
999 C 5 |a 10.1364/OPTICA.5.000402
|9 -- missing cx lookup --
|1 SB Park
|p 402 -
|2 Crossref
|u Park, S. B. et al. Direct sampling of a light wave in air. Optica 5, 402–408 (2018).
|t Optica
|v 5
|y 2018
999 C 5 |a 10.1038/s41566-021-00792-0
|9 -- missing cx lookup --
|1 MR Bionta
|p 456 -
|2 Crossref
|u Bionta, M. R. et al. On-chip sampling of optical fields with attosecond resolution. Nat. Photonics 15, 456–460 (2021).
|t Nat. Photonics
|v 15
|y 2021
999 C 5 |a 10.1364/OPTICA.411434
|9 -- missing cx lookup --
|1 D Zimin
|p 586 -
|2 Crossref
|u Zimin, D. et al. Petahertz-scale nonlinear photoconductive sampling in air. Optica 8, 586–590 (2021).
|t Optica
|v 8
|y 2021
999 C 5 |a 10.1038/s41566-021-00918-4
|9 -- missing cx lookup --
|1 D Hui
|p 33 -
|2 Crossref
|u Hui, D. et al. Attosecond electron motion control in dielectric. Nat. Photonics 16, 33–37 (2022).
|t Nat. Photonics
|v 16
|y 2022
999 C 5 |a 10.1364/OPTICA.7.000035
|9 -- missing cx lookup --
|1 M Kubullek
|p 35 -
|2 Crossref
|u Kubullek, M. et al. Single-shot carrier-envelope-phase measurement in ambient air. Optica 7, 35–39 (2020).
|t Optica
|v 7
|y 2020
999 C 5 |a 10.1038/s41586-022-04565-9
|9 -- missing cx lookup --
|1 T Boolakee
|p 251 -
|2 Crossref
|u Boolakee, T. et al. Light-field control of real and virtual charge carriers. Nature 605, 251–255 (2022).
|t Nature
|v 605
|y 2022
999 C 5 |a 10.1088/1367-2630/aae100
|9 -- missing cx lookup --
|1 JD Lee
|p 093029 -
|2 Crossref
|u Lee, J. D., Kim, Y. & Kim, C.-M. Model for petahertz optical memory based on a manipulation of the optical-field-induced current in dielectrics. New J. Phys. 20, 093029 (2018).
|t New J. Phys.
|v 20
|y 2018
999 C 5 |a 10.1038/s41467-020-17250-0
|1 Y Yang
|9 -- missing cx lookup --
|2 Crossref
|u Yang, Y. et al. Light phase detection with on-chip petahertz electronic networks. Nat. Commun. 11, 3407 (2020).
|t Nat. Commun.
|v 11
|y 2020
999 C 5 |a 10.1038/s41567-019-0613-6
|9 -- missing cx lookup --
|2 Crossref
|u Keathley, P. D. et al. Vanishing carrier-envelope-phase-sensitive response in optical-field photoemission from plasmonic nanoantennas. Nat. Phys. 15, 1128–1133 (2019).
999 C 5 |a 10.1038/s41467-023-40802-z
|1 V Hanus
|9 -- missing cx lookup --
|2 Crossref
|u Hanus, V. et al. Carrier-envelope phase on-chip scanner and control of laser beams. Nat. Commun. 14, 5068 (2023).
|t Nat. Commun.
|v 14
|y 2023
999 C 5 |a 10.1038/s41567-019-0745-8
|9 -- missing cx lookup --
|1 M Ludwig
|p 341 -
|2 Crossref
|u Ludwig, M. et al. Sub-femtosecond electron transport in a nanoscale gap. Nat. Phys. 16, 341–345 (2020).
|t Nat. Phys.
|v 16
|y 2020
999 C 5 |a 10.1364/CLEO_AT.2019.JTu4M.4
|9 -- missing cx lookup --
|2 Crossref
|u Keathley, P. et al. Carrier-Envelope Phase Detection with Arrays of Electrically Connected Bowtie Nanoantennas (OSA, San Jose, CA, USA, 2019).
999 C 5 |a 10.1364/OL.485610
|9 -- missing cx lookup --
|2 Crossref
|u Ritzkowsky, F. et al. Passively CEP stable sub-2-cycle source in the mid-infrared by adiabatic difference frequency generation. Opt. Lett. 48, 1870–1873 (2023).
999 C 5 |a 10.1364/OL.43.003850
|9 -- missing cx lookup --
|1 D Hoff
|p 3850 -
|2 Crossref
|u Hoff, D. et al. Continuous every-single-shot carrier-envelope phase measurement and control at 100 kHz. Opt. Lett. 43, 3850–3853 (2018).
|t Opt. Lett.
|v 43
|y 2018
999 C 5 |a 10.1038/nphys281
|9 -- missing cx lookup --
|1 IJ Sola
|p 319 -
|2 Crossref
|u Sola, I. J. et al. Controlling attosecond electron dynamics by phase-stabilized polarization gating. Nat. Phys. 2, 319–322 (2006).
|t Nat. Phys.
|v 2
|y 2006
999 C 5 |a 10.1126/science.1132838
|9 -- missing cx lookup --
|1 G Sansone
|p 443 -
|2 Crossref
|u Sansone, G. et al. Isolated single-cycle attosecond pulses. Science 314, 443–446 (2006).
|t Science
|v 314
|y 2006
999 C 5 |a 10.1038/s41566-020-0659-0
|9 -- missing cx lookup --
|1 GM Rossi
|p 629 -
|2 Crossref
|u Rossi, G. M. et al. Sub-cycle millijoule-level parametric waveform synthesizer for attosecond science. Nat. Photonics 14, 629–635 (2020).
|t Nat. Photonics
|v 14
|y 2020
999 C 5 |1 LV Keldysh
|y 1965
|2 Crossref
|u Keldysh, L. V. Ionization in the field of a strong electromagnetic wave. Sov. Phys. JETP 20, 1307–1314 (1965).
999 C 5 |1 FV Bunkin
|y 1965
|2 Crossref
|u Bunkin, F. V. & Fedorov, M. V. Cold emission of electrons from surface of a metal in a strong radiation field. Soviet Physics JETP 21, 896–899 (1965).
999 C 5 |a 10.1103/PhysRevA.64.013409
|9 -- missing cx lookup --
|1 GL Yudin
|p 013409 -
|2 Crossref
|u Yudin, G. L. & Ivanov, M. Y. Nonadiabatic tunnel ionization: Looking inside a laser cycle. Phys. Rev. A 64, 013409 (2001).
|t Phys. Rev. A
|v 64
|y 2001
999 C 5 |1 RH Fowler
|y 1928
|2 Crossref
|u Fowler, R. H. & Nordheim, L. Electron emission in intense electric fields. Proc. R. Soc. A 119, 173–181 (1928).
999 C 5 |a 10.1116/1.2834563
|9 -- missing cx lookup --
|1 RG Forbes
|p 209 -
|2 Crossref
|u Forbes, R. G. Description of field emission current/voltage characteristics in terms of scaled barrier field values (f-values). J. Vac. Sci. Technol. B 26, 209–213 (2008).
|t J. Vac. Sci. Technol. B
|v 26
|y 2008
999 C 5 |a 10.1364/JOSAB.424549
|9 -- missing cx lookup --
|1 D Buckley
|p C11 -
|2 Crossref
|u Buckley, D., Yang, Y., Yang-Keathley, Y., Berggren, K. K. & Keathley, P. D. Nanoantenna design for enhanced carrier-envelope-phase sensitivity. JOSA B 38, C11–C21 (2021).
|t JOSA B
|v 38
|y 2021
999 C 5 |a 10.1016/0031-8914(66)90125-X
|9 -- missing cx lookup --
|1 GW Timm
|p 1333 -
|2 Crossref
|u Timm, G. W. & Van der Ziel, A. Noise in field emission diodes. Physica 32, 1333–1344 (1966).
|t Physica
|v 32
|y 1966
999 C 5 |a 10.1116/6.0003142
|9 -- missing cx lookup --
|1 R Bhattacharya
|p 063202 -
|2 Crossref
|u Bhattacharya, R. et al. Effect of ultraviolet light on field emission performance and lifetime of lateral field emitter devices. J. Vac. Sci. Technol. B 41, 063202 (2023).
|t J. Vac. Sci. Technol. B
|v 41
|y 2023
999 C 5 |a 10.1038/nphys1250
|9 -- missing cx lookup --
|1 T Wittmann
|p 357 -
|2 Crossref
|u Wittmann, T. et al. Single-shot carrier-envelope phase measurement of few-cycle laser pulses. Nat. Phys. 5, 357–362 (2009).
|t Nat. Phys.
|v 5
|y 2009
999 C 5 |a 10.1364/OL.498664
|9 -- missing cx lookup --
|1 C Guo
|p 5431 -
|2 Crossref
|u Guo, C. et al. Single-shot, high-repetition rate carrier-envelope-phase detection of ultrashort laser pulses. Opt. Lett. 48, 5431–5434 (2023).
|t Opt. Lett.
|v 48
|y 2023
999 C 5 |a 10.1088/1748-0221/14/11/C11028
|9 -- missing cx lookup --
|1 M Andrä
|p C11028 -
|2 Crossref
|u Andrä, M. et al. Towards MYTHEN III - prototype characterisation of MYTHEN III.0.2. J. Instrum. 14, C11028 (2019).
|t J. Instrum.
|v 14
|y 2019
999 C 5 |a 10.1515/nanoph-2021-0276
|9 -- missing cx lookup --
|1 J Schötz
|p 3769 -
|2 Crossref
|u Schötz, J. et al. Onset of charge interaction in strong-field photoemission from nanometric needle tips. Nanophotonics 10, 3769–3775 (2021).
|t Nanophotonics
|v 10
|y 2021
999 C 5 |a 10.1364/OPTICA.4.001474
|9 -- missing cx lookup --
|1 J Ma
|p 1474 -
|2 Crossref
|u Ma, J., Masoodian, S., Starkey, D. A. & Fossum, E. R. Photon-number-resolving megapixel image sensor at room temperature without avalanche gain. Optica 4, 1474–1481 (2017).
|t Optica
|v 4
|y 2017
999 C 5 |a 10.1038/s41566-021-00924-6
|9 -- missing cx lookup --
|1 Y Liu
|p 109 -
|2 Crossref
|u Liu, Y., Beetar, J. E., Nesper, J., Gholam-Mirzaei, S. & Chini, M. Single-shot measurement of few-cycle optical waveforms on a chip. Nat. Photonics 16, 109–112 (2022).
|t Nat. Photonics
|v 16
|y 2022
999 C 5 |a 10.1038/nphoton.2017.34
|9 -- missing cx lookup --
|1 P Krogen
|p 222 -
|2 Crossref
|u Krogen, P. et al. Generation and multi-octave shaping of mid-infrared intense single-cycle pulses. Nat. Photonics 11, 222–226 (2017).
|t Nat. Photonics
|v 11
|y 2017
999 C 5 |a 10.1088/2040-8978/18/10/103501
|9 -- missing cx lookup --
|1 C Manzoni
|p 103501 -
|2 Crossref
|u Manzoni, C. & Cerullo, G. Design criteria for ultrafast optical parametric amplifiers. J. Opt. 18, 103501 (2016).
|t J. Opt.
|v 18
|y 2016

LibraryCollectionCLSMajorCLSMinorLanguageAuthor
Marc 21