Interaction of carrier envelope phase-stable laser pulses with graphene: the transition from the weak-field to the strong-field regime

We demonstrate that currents induced in graphene by ultrashort laser pulses are sensitive to the exact shape of the electric-field waveform. By increasing the field strength, we found a transition of the light–matter interaction from the weak-field to the strong-field regime at around 2 V/nm, where intraband dynamics influence interband transitions. In this strong-field regime, the light-matter interaction can be described by the wavenumber trajectories of electrons in the reciprocal space. For linearly polarized light the electron dynamics are governed by repeated sub-optical-cycle Landau-Zener transitions between the valence- and conduction band, resulting in Landau-Zener-Stuckelberg interference, whereas for circular polarized light this interference is supressed.

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Strong-field Breit-Wheeler pair production in short laser pulses: Identifying multiphoton interference and carrier-envelope-phase effects

Physical Review D ◽

10.1103/physrevd.93.053011 ◽

2016 ◽

Vol 93 (5) ◽

Cited By ~ 19

Author(s):

Martin J. A. Jansen ◽

Carsten Müller

Keyword(s):

Pair Production ◽

Strong Field ◽

Laser Pulses ◽

Carrier Envelope Phase ◽

Short Laser Pulses

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Controlling quantum wave packet of electronic motion on field‐dressed Coulomb potential of by carrier‐envelope phase‐dependent strong field laser pulses

International Journal of Quantum Chemistry ◽

10.1002/qua.26783 ◽

2021 ◽

Author(s):

Mohammad Noh Daud

Keyword(s):

Wave Packet ◽

Coulomb Potential ◽

Strong Field ◽

Laser Pulses ◽

Carrier Envelope Phase ◽

Electronic Motion ◽

Quantum Wave

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Controlling Quantum Wave Packet of Electronic Motion on Field-Dressed Coulomb Potential of H2+ by Carrier-Envelope Phase-Dependent Strong Field Laser Pulses

10.22541/au.161528038.84368652/v1 ◽

2021 ◽

Author(s):

Mohammad Noh Daud

Keyword(s):

Coulomb Potential ◽

Strong Field ◽

Laser Pulses ◽

Time Duration ◽

Carrier Envelope Phase ◽

Free Region ◽

Field Free Region ◽

Electronic Motion ◽

Quantum Wave ◽

The Right

Solving numerically a non-Born-Oppenheimer time-dependent Schrödinger equation to study the dissociative-ionization of H subjected to strong field six-cycle laser pulses (I = 4 × 10 W/cm, λ = 800 nm) leads to newly ultrafast images of electron dynamics in H. The electron distribution in H oscillates symmetrically with laser cycle with θ + π periodicity and gets trapped between two protons for about 8 fs by a Coulomb potential well. Nonetheless, this electron symmetrical distribution breaks up for the H internuclear separation larger than 9 a.u. in the field-free region at a time duration of 24 fs as a result of the distortion of Coulomb potential where the ejected electron preferentially localizes in one of the double-well potential separated by the inner Coulomb potential barrier. Moreover, controlling laser carrier-envelope phase θ enables one to generate the highest total asymmetry A of 0.75 and -0.75 at 10 and 190, respectively, associated with the electron preferential directionality being ionized to the left or the right paths along the H molecular axis. Thus the laser-controlled electron slightly reorganizes its position accordingly to track the shift in the position of the protons despite much heavier the proton’s mass.

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