Control of the supercontinuum spectrum bandwidth and emission efficiency for intense-isolated sub 40-as pulse generation by using a coherent superposition of states

Mohebbi, Masoud; Batebi, S.

doi:10.1016/j.elspec.2012.12.002

Cited by 7 publications

(4 citation statements)

References 23 publications

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“…1(a). Thus, it is not possible to obtain the intense higher-energy harmonics with He+ ions in a ground state alone [37,47] or with He+ ions in an excited state alone (i.e., when the initial state is prepared as the excited state). For comparison, we also present results when the initial state is the excited state [green dashed curve in Fig.…”

Section: R Esu Lt a N D Discussionmentioning

confidence: 98%

Controlling the ionization and recombination rates of an electron in preexcited ions to generate an intense isolated sub-4-as pulse in a multicycle regime

Mohebbi

2015

Phys. Rev. A

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We present a numerical study of an isolated attosecond pulse generation in a preexcited medium driven by a moderately intense multicycle laser pulse, which is synthesized by adding a chirp-free laser pulse to a chirped laser pulse. The results show that by preparing the initial state of He+ ion as a preexcited state, the electron trajectories significantly can be modulated and the supercontinuous harmonics with higher emission efficiency can be obtained. Optimizing the chirp parameter allows a multicycle field to behave like a few-cycle one due to the control of electron tunneling. Therefore, a wide 1172-eV intense supercontinuum would be achieved on the high-order-harmonic generation spectrum. The classical and time-frequency approaches reveal that the long quantum path is suppressed and only the short quantum path is left. By properly filtering the harmonics from the supercontinuum, a 34-as intense isolated pulse with clean time profile is directly obtained without any phase compensation. Our simulation shows that by superposing the total supercontinuum region with phase compensation, we can obtain the shortest sub-4-as intense isolated pulse.

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Section: R Esu Lt a N D Discussionmentioning

confidence: 98%

Controlling the ionization and recombination rates of an electron in preexcited ions to generate an intense isolated sub-4-as pulse in a multicycle regime

Mohebbi

2015

Phys. Rev. A

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“…Moreover, this approach also has the potential to select a short or long quantum path, which leads to the production of isolated short attosecond pulses, such as a 108-as pulse via an intense few-cycle chirped pulse, [25] a 10-as pulse with phase compensation using a chirped few-cycle laser and a static electric field, [26] a 37-as (57-as) pulse by an intense few-cycle chirped laser and a half cycle pulse (an ultraviolet attosecond pulse), [27,28] a 59-as pulse by a multicycle chirped pulse combined with a chirp-free pulse, [29] a 31-as (5-as) pulse without (with) phase compensation using a two-color laser pulse with the combined chirps, [30] a 102-as pulse with a multicycle chirped and chirp-free two-color field, [31] a sub-24-as pulse with phase compensation using multi-cycle chirped polarization gating pulses, [32] and an intense isolated sub-40-as pulse generation in pre-excited He-ionic medium with the use of a same-frequency laser field synthesis. [33] In our previous work, [34] by combining a 9-fs/800-nm fundamental chirped pulse and a 9-fs/1600-nm controlling chirped pulse, we realized a 1342-eV supercontinuum with a short path contribution and also obtained an isolated 28-as pulse with a bandwidth of 155 eV.…”

Section: Introductionmentioning

confidence: 99%

“…Our recent simulation calculation showed that a static electric field can not only modulate the quantum paths of the HHG, but also increase the ionization yield of electrons contributing to the continuous spectrum; as a result, the extension and enhancement of the HHG spectrum are achieved synchronously, which results in the production of an intense isolated 26-as pulse. [42] In this paper, the motivation of our simulation lies in the following considerations: first, though isolated attosecond pulse generations from the single chirped pulse, [25,43] the single chirped pulse or two-color laser in combination with a static electric field, [26,44] and two-color chirped pulse [28][29][30][31][32][33][34] have been investigated, few studies have been reported for the combination of the multicycle two-color chirped pulse and a static electric field; second, one of the current theoretical methods for producing single ultrashort attosecond pulses is by using the phase compensation for an achievable supercontinuum spectrum, which is not easy to achieve in an experiment; third, we intend to generate a single attosecond pulse with a duration below one atomic unit of time by straightforwardly filtering a large range of harmonics. Due to these ideas, in this paper we further investigate the HHG and isolated attosecond pulse generation of a model Ne atom in a multicycle two-color chirped laser and a static electric field.…”

Section: Introductionmentioning

confidence: 99%

Isolated sub-30-attosecond pulse generation using a multicycle two-color chirped laser and a static electric field

Zhang¹

2014

Chinese Phys. B

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We present a theoretical investigation of high-order harmonic generation in a chirped two-color laser field, which is synthesized by a 10-fs/800-nm fundamental chirped pulse and a 10-fs/1760-nm subharmonic pulse. It is shown that a supercontinuum can be produced using the multicycle two-color chirped field. However, the supercontinuum reveals a strong modulation structure, which is not good for the generation of an isolated attosecond pulse. By adding a static electric field to the multicycle two-color chirped field, not only the harmonic cutoff is extended remarkably, but also the quantum paths of the high-order harmonic generation (HHG) are modified significantly. As a result, both the extension of the supercontinuum and the selection of a single quantum path are achieved, producing an isolated 23-as pulse with a bandwidth of about 170.6 eV. Furthermore, the influences of the laser intensities on the supercontinuum and isolated attosecond pulse generation are investigated.

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“…The production of isolated attosecond pulses can be experimentally achieved either with the technique of HHG in gas from a few-cycle driving pulse [10,11] or with the technique of temporal confinement of the HHG by polarization gating [12]. Moreover, theoretically, the two-colour control mechanisms [13][14][15][16], the coherent superposition state of the target technique [17][18][19] and the frequency-chirping method [20][21][22][23][24][25][26][27][28], have been introduced. To have easy way to create and control a focused wavepacket of the laser field, we employ the frequencychirping of driving laser pulse method this in article.…”

Section: Introductionmentioning

confidence: 99%

Electron path control of high-order harmonic generation by a spatially inhomogeneous field

Mohebbi

Malaei

2015

Journal of Modern Optics

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We theoretically investigate the control of high-order harmonics cut-off and as-pulse generation by a chirped laser field using a metallic bow tie-shaped nanostructure. The numerical results show that the trajectories of the electron wave packet are strongly modified, the short quantum path is enhanced, the long quantum path is suppressed and the low modulated spectrum of the harmonics can be remarkably extended. Our calculated results also show that, by confining electron motion, a broadband supercontinuum with the width of 1670 eV can be produced which directly generates an isolated 34 as-pulse without phase compensation. To explore the underlying mechanism responsible for the cut-off extension and the quantum path selection, we perform time-frequency analysis and a classical simulation based on the three-step model.

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Control of the supercontinuum spectrum bandwidth and emission efficiency for intense-isolated sub 40-as pulse generation by using a coherent superposition of states

Cited by 7 publications

References 23 publications

Controlling the ionization and recombination rates of an electron in preexcited ions to generate an intense isolated sub-4-as pulse in a multicycle regime

Controlling the ionization and recombination rates of an electron in preexcited ions to generate an intense isolated sub-4-as pulse in a multicycle regime

Isolated sub-30-attosecond pulse generation using a multicycle two-color chirped laser and a static electric field

Electron path control of high-order harmonic generation by a spatially inhomogeneous field

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