Spatio-temporal couplings in ultrashort laser pulses

Aktürk, Selçuk; Gu, Xun; Bowlan, Pamela; Trebino, Rick

doi:10.1088/2040-8978/12/9/093001

Cited by 223 publications

(151 citation statements)

References 128 publications

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“…This points to the conclusion that it should correlate to the spatial properties of the laser pulse. A plausible explanation is the spatiotemporal coupling (STC) of the laser beam [33]. It is to be noted here that the laser focus shown in the inset of Fig.…”

Section: Resultsmentioning

confidence: 94%

Multi-μJ harmonic emission energy from laser-driven plasma

et al. 2014

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Section: Resultsmentioning

confidence: 94%

Multi-μJ harmonic emission energy from laser-driven plasma

et al. 2014

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“…Under the effect of even simple optical components, the spatial properties of these beams can vary over the duration of the light pulse [1]. In this letter, we show how such spatio-temporally coupled electromagnetic fields can be exploited to produce an attosecond lighthouse, i.e.…”

mentioning

confidence: 95%

“…Ultrashort light beams are said to exhibit spatiotemporal couplings (STC) when their spatial properties depend on time, and conversely [1] -i.e. their electric field E(x, y, z = z 0 , t) = E 1 (t)E 2 (x, y).…”

mentioning

confidence: 99%

“…In contrast, the problem is still unsolved experimentally for HHG on plasma mirrors [8][9][10], one of the promising processes to obtain the next generation of attosecond light sources [11,12]. We describe here how STC provide a new approach to this problem, of unprecedented simplicity, generality and potential : one of the most basic types of STC, wavefront rotation [1] (WFR), can be exploited to generate a collection of single attosecond pulses in angularly well-separated light beams -an attosecond lighthouse-even with relatively long laser pulses.…”

mentioning

confidence: 99%

“…Out of focus, this Position STC takes a different form, called pulse front tilt [1], which corresponds to an E-field of the form (assuming Gaussian profiles in time and space) :…”

mentioning

confidence: 99%

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Attosecond Lighthouses: How To Use Spatiotemporally Coupled Light Fields To Generate Isolated Attosecond Pulses

2012

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Coherent light beams composed of ultrashort pulses are now increasingly used in different fields of Science, from time-resolved spectroscopy to plasma physics. Under the effect of even simple optical components, the spatial properties of these beams can vary over the duration of the light pulse [1]. In this letter, we show how such spatio-temporally coupled electromagnetic fields can be exploited to produce an attosecond lighthouse, i.e. a source emitting a collection of isolated attosecond pulses, propagating in angularly well-separated light beams. This very general effect not only opens the way to a new generation of attosecond light sources, particularly suitable for pump-probe experiments, but also provides a powerful new tool for ultrafast metrology, for instance giving direct access to fluctuations in the phase of the laser field oscillations with respect to the pulse envelop, right at the focus of even the most intense ultrashort laser beams. PACS numbers:Ultrashort light beams are said to exhibit spatiotemporal couplings (STC) when their spatial properties depend on time, and conversely [1] -i.e. their electric field E(x, y, z = z 0 , t) = E 1 (t)E 2 (x, y). The importance of STC has been largely overlooked in most laser-matter interaction experiments, until recently [2]. In strong-field science, STC are even considered as highly detrimental, because they systematically decrease the peak intensity at focus [3]. In this letter, we show that on the opposite, moderate and controlled STC provide a powerful means of controlling high-intensity laser-matter interactions, and pave the way to a whole range of new experimental capabilities.To demonstrate this idea, we consider a particular application of STC to attosecond pulse generation (1 as=10 −18 s), which has been the key issue in the development of attosecond Science [4]. All attosecond light sources demonstrated so far are based on high-order harmonic generation (HHG) of intense femtosecond laser pulses in different media [4,5]. Since many-cycle long pulses naturally produce trains of attosecond pulses, considerable efforts had to be deployed in the last fifteen years for the development of 'temporal gating' techniques, to isolate single attosecond pulses, more readily usable for time-resolved measurements of electron dynamics in matter. A variety of experimentally-challenging techniques have now been demonstrated for HHG in gases [6,7]. In contrast, the problem is still unsolved experimentally for HHG on plasma mirrors [8][9][10], one of the promising processes to obtain the next generation of attosecond light sources [11,12]. We describe here how STC provide a new approach to this problem, of unprecedented simplicity, generality and potential : one of the most basic types of STC, wavefront rotation [1] (WFR), can be exploited to generate a collection of single attosecond pulses in angularly well-separated light beams -an attosecond lighthouse-even with relatively long laser pulses.Let us first briefly summarize the concept of WFR at the focus of a femto...

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In‐Band Noise Filtering via Spatio‐Spectral Coupling

Wang

Yuan

et al. 2018

Laser & Photonics Reviews

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Noise is a fundamental and ubiquitous problem in optics, and only those out of the signal bandwidth can be filtrated away by traditional spectral filters. This paper presents an in‐band noise filtering scheme where the ultrafast signal is controlled by spatio‐spectral coupling such that the signal and its in‐band noise can be separated in the spatio‐spectral domain. As an example of its impact on ultra‐intense lasers, this filter is applied to show that the noise produced in chirped‐pulse amplification can be efficiently filtrated within the signal bandwidth. Near‐noiseless amplification of pulses with contrast as high as 1011 is demonstrated in a high‐gain optical parametric chirped‐pulse amplifier, resulting in approximately 40 times enhancement in output contrast. The simplicity, efficiency, and direct compatibility with existing techniques for short‐pulse generation will make in‐band filtering attractive to a wide range of applications in ultrafast optics and time‐resolved spectroscopy.

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Spatio-temporal couplings in ultrashort laser pulses

Cited by 223 publications

References 128 publications

Multi-μJ harmonic emission energy from laser-driven plasma

Multi-μJ harmonic emission energy from laser-driven plasma

Attosecond Lighthouses: How To Use Spatiotemporally Coupled Light Fields To Generate Isolated Attosecond Pulses

In‐Band Noise Filtering via Spatio‐Spectral Coupling

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