We studied monatomic
linear carbon chains stabilized by gold nanoparticles
attached to their ends and deposited on a solid substrate. We observe
spectral features of straight chains containing from 8 to 24 atoms.
Low-temperature PL spectra reveal characteristic triplet fine structures
that repeat themselves for carbon chains of different lengths. The
triplet is invariably composed of a sharp intense peak accompanied
by two broader satellites situated 15 and 40 meV below the main peak.
We interpret these resonances as an edge-state neutral exciton and
positively and negatively charged trions, respectively. The time-resolved
PL shows that the radiative lifetime of the observed quasiparticles
is about 1 ns, and it increases with the increase of the length of
the chain. At high temperatures a nonradiative exciton decay channel
appears due to the thermal hopping of carriers between parallel carbon
chains. Excitons in carbon chains possess large oscillator strengths
and extremely low inhomogeneous broadenings.
International audienceWe report the results of continuous wave laser interactions with both gold and silver targets in the presence of different liquids (deionized water, ethanol, and glycerol). Upon moderate laser irradiation at wavelength of 1.06 nm during 30 min, nanoparticle colloids are shown to be formed with surprisingly narrow size distributions and average dispersion as small as 15–20 nm. The average particle sizes range between 8 and 52 nm for gold and between 20 and 107 nm for silver. This parameter is shown to be stable and well-controlled by such laser parameters as intensity and effective irradiation time, as well as by the choice of the liquid phase. The possibilities of an efficient control over the proposed synthesis techniques are discussed, and the results of a bimetallic Au–Ag structure deposition from the obtained colloids are presented. The formation of the extended arrays of gold and silver nanoparticles with controlled morphology is examined. The changes in the optical properties of the obtained thin films are found to depend on their morphology, in particular, on the particle size, and distance between them
We stabilize monoatomic carbon chains in water by attaching them to gold nanoparticles (NPs) by means of the laser ablation process. Resulting nanoobjects represent pairs of NPs connected by multiple straight carbon chains of several nanometer lengths. If NPs at the opposite ends of a chain differ in size, the structure acquires a dipole moment due to the difference in work functions of the two NPs. We take advantage of the dipole polarisation of carbon chains for ordering them by the external electric field. We deposit them on a glass substrate by the sputtering method in the presence of static electric fields of magnitudes up to 105 V/m. The formation of one-dimensional carbyne quasi-crystals deposited on a substrate is evidenced by high-resolution TEM and X-ray diffraction measurements. The original kinetic model describing the dynamics of ballistically flowing nano-dipoles reproduces the experimental diagram of orientation of the deposited chains.
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