Nanocluster assembled films have attracted great interest for designing nanostructured materials with unique electromagnetic properties through a bottom-up approach. Superatoms of group-5 metals (M V = V, Nb, and Ta) encapsulating silicon (Si) cage nanoclusters (M V @Si 16 ), which are synthesized by high-power impulse magnetron sputtering technique, can be efficiently generated to form assembled films. Temperature-dependent current−voltage (I−V) characteristics of the M V @Si 16 assembled films revealed that the electrical conduction mechanism is not band transport but hopping transport with Efros−Shklovskii variable range hopping for all central M V atoms. The results show that electrons involved in conduction are strongly correlated to localized electronic states; this correlation arises because of not only the geometrical disordering in noncrystalline assembled films but also the electronic nature of a superatomic 1H orbital with multiple nodes. The localization length depends on the specific M V and is several times the radius of M V @Si 16 (0.45 nm); it is the largest for Ta (2.2 nm) and the smallest for Nb (0.8 nm), revealing a periodicity of superatoms.
Vibrational spectra of thiolate-protected gold nanoclusters,
prepared
in a monolayer manner using the Langmuir–Blodgett method, were
measured by means of infrared reflection absorption spectroscopy (IRAS).
A transferred monolayer of gold nanoclusters ligated by dodecanethiolate
or 2-phenylethane-1-thiolate onto a single-crystal gold (Au) surface
of Au(111) exhibits worthy IRAS spectra that reveal temperature-dependent
behaviors from 100 to 340 K as well as comprehensive peak assignments
based on density functional theory calculations: the conformation
change in ligands between all trans and gauche defect forms with temperature. In addition to the temperature dependence,
the cluster size dependence of alkyl and phenyl moieties is discussed,
compared with the IRAS spectra of the corresponding self-assembled
monolayers (SAMs) on Au(111). Ligands spreading three-dimensionally
from the Au core determine the coordination structure of the ligated
Au nanoclusters.
The floating-gate memory characteristics of thiolate-protected gold (Au:SR) and palladium doped Au (AuPd:SR) nanoclusters, Au25(SR)18, Au24Pd(SR)18, and Au38(SR)24 (R = C12H25), were investigated by capacitance-voltage (C–V) measurements in vacuum. Monolayer films of Au:SR nanoclusters were formed as floating-gate memory layers on p-type Si substrates by the Langmuir-Schaefer method with surface pressure − area (π-A) isotherm measurements. A fluoropolymer (CYTOP, ∼15 nm thick) was spin-coated on top to form a hydrophobic insulating layer. Using an Au pad (∼40 nm thick) as the gate electrode, C–V measurements exhibit clockwise hysteresis curves originating from the Au:SR and AuPd:SR nanoclusters against the reference measured in each sample, and the hysteresis widths were dependent on the composition and sizes of the Au:SR nanoclusters. The positive and negative voltage shifts in the hysteresis can be explained in terms of electronic structures in Au:SR and AuPd:SR-based devices.
With the development of nanocluster (NC) synthesis methods in gas phase, atomically precise NCs composed of finite number of metal and semiconductor atoms have emerged. NCs are expected to be...
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