We study the saturable absorption properties of single-walled carbon nanotubes (SWCNTs) with a large diameter of 2.2 nm and the corresponding exciton resonance at a wavelength of 2.4 µm. At resonant excitation, a large modulation depth of approximately 30 % and a small saturation fluence of a few tens of µJ/cm 2 are evaluated. The temporal response is characterized by an instantaneous rise and a subpicosecond recovery. We also utilize the SWCNTs to realize sub-50 fs, self-start mode locking in a Cr:ZnS laser, revealing that the film thickness is an important parameter that affects the possible pulse energy and duration. The results prove that semiconductor SWCNTs with tailored diameters exceeding 2 nm are useful for passive mode locking in the mid-infrared range.
Amid the increasing potential of ultrafast mid-infrared (mid-IR) laser
sources based on transition metal doped chalcogenides such as Cr:ZnS,
Cr:ZnSe, and Fe:ZnSe lasers, there is a need for direct and sensitive
characterization of mid-IR mode-locked laser pulses that work in the
nanojoule energy range. We developed a two-dimensional spectral
shearing interferometry (2DSI) setup to successfully demonstrate the
direct electric-field reconstruction of Cr:ZnS mode-locked laser
pulses with a central wavelength of 2.3 µm, temporal duration of
30.3 fs, and energies of 3 nJ. The reconstructed electric field is in
reasonable agreement with an independently measured intensity
autocorrelation trace, and the quantitative reliability of the 2DSI
measurement is verified from a material dispersion evaluation. The
presented implementation of 2DSI, including a choice of nonlinear
crystal as well as the use of high-throughput dispersive elements and
a high signal-to-noise ratio near-IR spectrometer, would benefit
future development of ultrafast mid-IR lasers and their
applications.
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