222 research outputs found
Free Energy Approach to the Formation of an Icosahedral Structure during the Freezing of Gold Nanoclusters
The freezing of metal nanoclusters such as gold, silver, and copper exhibits
a novel structural evolution. The formation of the icosahedral (Ih) structure
is dominant despite its energetic metastability. This important phenomenon,
hitherto not understood, is studied by calculating free energies of gold
nanoclusters. The structural transition barriers have been determined by using
the umbrella sampling technique combined with molecular dynamics simulations.
Our calculations show that the formation of Ih gold nanoclusters is attributed
to the lower free energy barrier from the liquid to the Ih phases compared to
the barrier from the liquid to the face-centered-cubic crystal phases
Molecular dynamics simulations of the dipolar-induced formation of magnetic nanochains and nanorings
Iron, cobalt and nickel nanoparticles, grown in the gas phase, are known to
arrange in chains and bracelet-like rings due to the long-range dipolar
interaction between the ferromagnetic (or super-paramagnetic) particles. We
investigate the dynamics and thermodynamics of such magnetic dipolar
nanoparticles for low densities using molecular dynamics simulations and
analyze the influence of temperature and external magnetic fields on two- and
three-dimensional systems. The obtained phase diagrams can be understood by
using simple energetic arguments.Comment: 6 pages, 6 figure
Particle-size dependence of orbital order-disorder transition in LaMnO3
The latent heat (L) associated with the orbital order-disorder transition at
T_JT is found to depend significantly on the average particle size (d) of
LaMnO3. It rises slowly with the decrease in d down to ~100 nm and then jumps
by more than an order of magnitude in between d ~ 100 nm and ~30 nm. Finally, L
falls sharply to zero at a critical particle size d_c ~ 19 nm. The transition
temperature T_JT also exhibits an almost similar trend of variation with the
particle size, near d ~ 30 nm and below, even though the extent of variation is
relatively small. The zero-field-cooled (ZFC) and field-cooled (FC)
magnetization versus temperature study over a temperature range 10-300 K
reveals that the antiferromagnetic transition temperature decreases with d
while the temperature range, over which the ZFC and FC data diverge, increases
with the drop in d. The FC magnetization also is found to increase sharply with
the drop in particle size. A conjecture of nonmonotonic variation in orbital
domain structure with decrease in particle size - from smaller domains with
large number of boundaries to larger domains with small number of boundaries
due to lesser lattice defects and, finally, down to even finer domain
structures with higher degree of metastability - along with increase in surface
area in core-shell structure, could possibly rationalize the observed L versus
d and T_JT versus d patterns. Transmission electron microscopy data provide
evidence for presence of core-shell structure as well as for increase in
lattice defects in finer particles.Comment: 26 pages including 5 figures; pdf only; accepted for publication in
Phys. Rev.
Why do gallium clusters have a higher melting point than the bulk?
Density functional molecular dynamical simulations have been performed on
Ga and Ga clusters to understand the recently observed
higher-than-bulk melting temperatures in small gallium clusters [Breaux {\em et
al.}, Phys. Rev. Lett. {\bf 91}, 215508 (2003)]. The specific-heat curve,
calculated with the multiple-histogram technique, shows the melting temperature
to be well above the bulk melting point of 303 K, viz. around 650 K and 1400 K
for Ga and Ga, respectively. The higher-than-bulk melting
temperatures are attributed mainly to the covalent bonding in these clusters,
in contrast with the covalent-metallic bonding in the bulk.Comment: 4 pages, including 6 figures. accepted for publication in Phys. Rev.
Let
Premelting of Thin Wires
Recent work has raised considerable interest on the nature of thin metallic
wires. We have investigated the melting behavior of thin cylindrical Pb wires
with the axis along a (110) direction, using molecular dynamics and a
well-tested many-body potential. We find that---in analogy with cluster
melting---the melting temperature of a wire with radius is lower
than that of a bulk solid, , by . Surface melting
effects, with formation of a thin skin of highly diffusive atoms at the wire
surface, is observed. The diffusivity is lower where the wire surface has a
flat, local (111) orientation, and higher at (110) and (100) rounded areas. The
possible relevance to recent results on non-rupturing thin necks between an STM
tip and a warm surface is addressed.Comment: 10 pages, 4 postscript figures are appended, RevTeX, SISSA Ref.
131/94/CM/S
Finite size melting of spherical solid-liquid aluminium interfaces
We have investigated the melting of nano-sized cone shaped aluminium needles
coated with amorphous carbon using transmission electron microscopy. The
interface between solid and liquid aluminium was found to have spherical
topology. For needles with fixed apex angle, the depressed melting temperature
of this spherical interface, with radius , was found to scale linearly with
the inverse radius . However, by varying the apex angle of the needles we
show that the proportionality constant between the depressed melting
temperature and the inverse radius changes significantly. This lead us to the
conclusion that the depressed melting temperature is not controlled solely by
the inverse radius . Instead we found a direct relation between the
depressed melting temperature and the ratio between the solid-liquid interface
area and the molten volume.Comment: to appear in Philosophical Magazine (2009
Impurity effects on the melting of Ni clusters
We demonstrate that the addition of a single carbon impurity leads to
significant changes in the thermodynamic properties of Ni clusters consisting
of more than a hundred atoms. The magnitude of the change induced is dependent
upon the parameters of the Ni-C interaction. Hence, thermodynamic properties of
Ni clusters can be effectively tuned by the addition of an impurity of a
particular type. We also show that the presence of a carbon impurity
considerably changes the mobility and diffusion of atoms in the Ni cluster at
temperatures close to its melting point. The calculated diffusion coefficients
of the carbon impurity in the Ni cluster can be used for a reliable estimate of
the growth rate of carbon nanotubes.Comment: 27 pages, 13 figure
Melting behavior of ultrathin titanium nanowires
The thermal stability and melting behavior of ultrathin titanium nanowires
with multi-shell cylindrical structures are studied using molecular dynamic
simulation. The melting temperatures of titanium nanowires show remarkable
dependence on wire sizes and structures. For the nanowire thinner than 1.2 nm,
there is no clear characteristic of first-order phase transition during the
melting, implying a coexistence of solid and liquid phases due to finite size
effect. An interesting structural transformation from helical multi-shell
cylindrical to bulk-like rectangular is observed in the melting process of a
thicker hexagonal nanowire with 1.7 nm diameter.Comment: 4 pages, 4 figure
Simulation of the thermally induced austenitic phase transition in NiTi nanoparticles
The reverse martensitic ("austenitic") transformation upon heating of
equiatomic nickel-titanium nanoparticles with diameters between 4 and 17 nm is
analyzed by means of molecular-dynamics simulations with a semi-empirical model
potential. After constructing an appropriate order parameter to distinguish
locally between the monoclinic B19' at low and the cubic B2 structure at high
temperatures, the process of the phase transition is visualized. This shows a
heterogeneous nucleation of austenite at the surface of the particles, which
propagates to the interior by plane sliding, explaining a difference in
austenite start and end temperatures. Their absolute values and dependence on
particle diameter are obtained and related to calculations of the surface
induced size dependence of the difference in free energy between austenite and
martensite.Comment: 6 pages, 4 figures, accepted for publication in "The European
Physical Journal B
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