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

89 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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10.1038/nphoton.2013.348

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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.

UR - https://www.scopus.com/pages/publications/84897615372

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

Abstract

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