Solid-state light-phase detector

Tim Paasch-Colberg; Agustin Schiffrin; Nicholas Karpowicz; Stanislav Kruchinin; Özge Saǧlam; Sabine Keiber; Olga Razskazovskaya; Sascha Mühlbrandt; Ali Alnaser; Matthias Kübel; Vadym Apalkov; Daniel Gerster; Joachim Reichert; Tibor Wittmann; Johannes V. Barth; Mark I. Stockman; Ralph Ernstorfer; Vladislav S. Yakovlev; Reinhard Kienberger; Ferenc Krausz

doi:10.1038/nphoton.2013.348

Solid-state light-phase detector

Tim Paasch-Colberg, Agustin Schiffrin, Nicholas Karpowicz, Stanislav Kruchinin, Özge Saǧlam, Sabine Keiber, Olga Razskazovskaya, Sascha Mühlbrandt, Ali Alnaser, Matthias Kübel, Vadym Apalkov, Daniel Gerster, Joachim Reichert, Tibor Wittmann, Johannes V. Barth, Mark I. Stockman, Ralph Ernstorfer, Vladislav S. Yakovlev, Reinhard Kienberger, Ferenc Krausz

Chair of Laser and X-ray Physics

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

85 Scopus citations

Abstract

Attosecond science relies on the use of intense, waveform-controlled, few-cycle laser pulses to control extreme nonlinear optical processes taking place within a fraction of an optical period. A number of techniques are available for retrieving the amplitude envelope and chirp of such few-cycle laser pulses. However, their full characterization requires detection of the absolute offset between the rapidly oscillating carrier wave and the pulse envelope, the carrier-envelope phase (CEP). So far, this has only been feasible with photoelectron spectroscopy, relying on complex vacuum set-ups. Here, we present a technique that enables the detection of the CEP of few-cycle laser pulses under ambient conditions. This is based on the CEP-dependence of directly measurable electric currents generated by the electric field of light in a metal-dielectric-metal nanojunction. The device holds promise for routine measurement and monitoring of the CEP in attosecond laboratories.

Original language	English
Pages (from-to)	214-218
Number of pages	5
Journal	Nature Photonics
Volume	8
Issue number	3
DOIs	https://doi.org/10.1038/nphoton.2013.348
State	Published - Mar 2014

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Paasch-Colberg, T., Schiffrin, A., Karpowicz, N., Kruchinin, S., Saǧlam, Ö., Keiber, S., Razskazovskaya, O., Mühlbrandt, S., Alnaser, A., Kübel, M., Apalkov, V., Gerster, D., Reichert, J., Wittmann, T., Barth, J. V., Stockman, M. I., Ernstorfer, R., Yakovlev, V. S., Kienberger, R., & Krausz, F. (2014). Solid-state light-phase detector. Nature Photonics, 8(3), 214-218. https://doi.org/10.1038/nphoton.2013.348

@article{f425fde7236e42e4abfc4f93887dd257,

title = "Solid-state light-phase detector",

abstract = "Attosecond science relies on the use of intense, waveform-controlled, few-cycle laser pulses to control extreme nonlinear optical processes taking place within a fraction of an optical period. A number of techniques are available for retrieving the amplitude envelope and chirp of such few-cycle laser pulses. However, their full characterization requires detection of the absolute offset between the rapidly oscillating carrier wave and the pulse envelope, the carrier-envelope phase (CEP). So far, this has only been feasible with photoelectron spectroscopy, relying on complex vacuum set-ups. Here, we present a technique that enables the detection of the CEP of few-cycle laser pulses under ambient conditions. This is based on the CEP-dependence of directly measurable electric currents generated by the electric field of light in a metal-dielectric-metal nanojunction. The device holds promise for routine measurement and monitoring of the CEP in attosecond laboratories.",

author = "Tim Paasch-Colberg and Agustin Schiffrin and Nicholas Karpowicz and Stanislav Kruchinin and {\"O}zge Saǧlam and Sabine Keiber and Olga Razskazovskaya and Sascha M{\"u}hlbrandt and Ali Alnaser and Matthias K{\"u}bel and Vadym Apalkov and Daniel Gerster and Joachim Reichert and Tibor Wittmann and Barth, {Johannes V.} and Stockman, {Mark I.} and Ralph Ernstorfer and Yakovlev, {Vladislav S.} and Reinhard Kienberger and Ferenc Krausz",

note = "Funding Information: The authors thank Y. Deng for technical support and fruitful discussions as well as the Munich-Centre for Advanced Photonics for financial support. A.S. acknowledges the Alexander von Humboldt Foundation and the Swiss National Science Foundation. N.K. acknowledges the Alexander von Humboldt Foundation. {\"O}.S. acknowledges a Marie Curie International Incoming Fellowship (project NANOULOP, no. 302157). R.K. acknowledges an ERC starting grant.",

year = "2014",

month = mar,

doi = "10.1038/nphoton.2013.348",

language = "English",

volume = "8",

pages = "214--218",

journal = "Nature Photonics",

issn = "1749-4885",

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Paasch-Colberg, T, Schiffrin, A, Karpowicz, N, Kruchinin, S, Saǧlam, Ö, Keiber, S, Razskazovskaya, O, Mühlbrandt, S, Alnaser, A, Kübel, M, Apalkov, V, Gerster, D, Reichert, J, Wittmann, T, Barth, JV, Stockman, MI, Ernstorfer, R, Yakovlev, VS, Kienberger, R & Krausz, F 2014, 'Solid-state light-phase detector', Nature Photonics, vol. 8, no. 3, pp. 214-218. https://doi.org/10.1038/nphoton.2013.348

TY - JOUR

T1 - Solid-state light-phase detector

AU - Paasch-Colberg, Tim

AU - Schiffrin, Agustin

AU - Karpowicz, Nicholas

AU - Kruchinin, Stanislav

AU - Saǧlam, Özge

AU - Keiber, Sabine

AU - Razskazovskaya, Olga

AU - Mühlbrandt, Sascha

AU - Alnaser, Ali

AU - Kübel, Matthias

AU - Apalkov, Vadym

AU - Gerster, Daniel

AU - Reichert, Joachim

AU - Wittmann, Tibor

AU - Barth, Johannes V.

AU - Stockman, Mark I.

AU - Ernstorfer, Ralph

AU - Yakovlev, Vladislav S.

AU - Kienberger, Reinhard

AU - Krausz, Ferenc

N1 - Funding Information: The authors thank Y. Deng for technical support and fruitful discussions as well as the Munich-Centre for Advanced Photonics for financial support. A.S. acknowledges the Alexander von Humboldt Foundation and the Swiss National Science Foundation. N.K. acknowledges the Alexander von Humboldt Foundation. Ö.S. acknowledges a Marie Curie International Incoming Fellowship (project NANOULOP, no. 302157). R.K. acknowledges an ERC starting grant.

PY - 2014/3

Y1 - 2014/3

N2 - Attosecond science relies on the use of intense, waveform-controlled, few-cycle laser pulses to control extreme nonlinear optical processes taking place within a fraction of an optical period. A number of techniques are available for retrieving the amplitude envelope and chirp of such few-cycle laser pulses. However, their full characterization requires detection of the absolute offset between the rapidly oscillating carrier wave and the pulse envelope, the carrier-envelope phase (CEP). So far, this has only been feasible with photoelectron spectroscopy, relying on complex vacuum set-ups. Here, we present a technique that enables the detection of the CEP of few-cycle laser pulses under ambient conditions. This is based on the CEP-dependence of directly measurable electric currents generated by the electric field of light in a metal-dielectric-metal nanojunction. The device holds promise for routine measurement and monitoring of the CEP in attosecond laboratories.

AB - Attosecond science relies on the use of intense, waveform-controlled, few-cycle laser pulses to control extreme nonlinear optical processes taking place within a fraction of an optical period. A number of techniques are available for retrieving the amplitude envelope and chirp of such few-cycle laser pulses. However, their full characterization requires detection of the absolute offset between the rapidly oscillating carrier wave and the pulse envelope, the carrier-envelope phase (CEP). So far, this has only been feasible with photoelectron spectroscopy, relying on complex vacuum set-ups. Here, we present a technique that enables the detection of the CEP of few-cycle laser pulses under ambient conditions. This is based on the CEP-dependence of directly measurable electric currents generated by the electric field of light in a metal-dielectric-metal nanojunction. The device holds promise for routine measurement and monitoring of the CEP in attosecond laboratories.

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U2 - 10.1038/nphoton.2013.348

DO - 10.1038/nphoton.2013.348

M3 - Article

AN - SCOPUS:84897615372

SN - 1749-4885

VL - 8

SP - 214

EP - 218

JO - Nature Photonics

JF - Nature Photonics

IS - 3

ER -

Solid-state light-phase detector

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