Nonlinear optical limiters of pulsed laser radiation based on carbon‐containing nanostructures in viscous and solid matrices

Abstract: Results of the study of optical limiters of pulsed laser radiation based on nonlinear effects in carbon nanostructures placed into viscous and solid matrices are presented. A nonlinear optical limiting was studied by nanomaterials based on multi-wall polyhedral carbon nanostructures (astralens) placed in a sol-gel matrix. Similar studies for single-wall and multi-wall carbon-containing nanotubes placed in polymer matrices with various viscosities were performed. No additional mechanism of optical limiting due … Show more

“…As far as 1992 the limiting threshold of ∼ 0.1 J/cm 2 was reported for fullerene solutions, using 8-ns pulses at 532 nm [8]. Today's representative values of limiting threshold in various composite materials providing nonlinear absorption or nonlinear scattering are still in the range 0.1-1 J/cm 2 under nanosecond pulses for visible and near-infrared radiation [9][10][11]. Moreover, most studies deal with solutions, while for practical applications rather solid forms are desirable.…”

Optical limiting performance of a GaAs/AlAs heterostructure microcavity in the near-infrared

“…As far as 1992 the limiting threshold of ∼ 0.1 J/cm 2 was reported for fullerene solutions, using 8-ns pulses at 532 nm [8]. Today's representative values of limiting threshold in various composite materials providing nonlinear absorption or nonlinear scattering are still in the range 0.1-1 J/cm 2 under nanosecond pulses for visible and near-infrared radiation [9][10][11]. Moreover, most studies deal with solutions, while for practical applications rather solid forms are desirable.…”

Optical limiting performance of a GaAs/AlAs heterostructure microcavity in the near-infrared

“…The important role the non-linear optical properties of CNT are playing [7,8], including the ability to limit non-linear laser irradiation with increasing intensity [9,10]. The technical devices using carbon nanomaterials in aqueous dispersions of surfactants are improved [11,12]. The appearance of methods that allow creation of a stable suspensions of carbon nanotubes in the dispersions of surfactants [6], give possibility to control the CNT photophysical characteristics by tuning the local environment in the presence of surfactant [13].…”

Creating Carbon Nanotubes Microenvironment in Surfactant Water Solutions

Laser fabrication of composite layers from biopolymers with branched 3D networks of single-walled carbon nanotubes for cardiovascular implants