457 research outputs found
Physics of Solid and Liquid Alkali Halide Surfaces Near the Melting Point
This paper presents a broad theoretical and simulation study of the high
temperature behavior of crystalline alkali halide surfaces typified by
NaCl(100), of the liquid NaCl surface near freezing, and of the very unusual
partial wetting of the solid surface by the melt. Simulations are conducted
using two-body rigid ion BMHFT potentials, with full treatment of long-range
Coulomb forces. After a preliminary check of the description of bulk NaCl
provided by these potentials, which seems generally good even at the melting
point, we carry out a new investigation of solid and liquid surfaces. Solid
NaCl(100) is found in this model to be very anharmonic and yet exceptionally
stable when hot. It is predicted by a thermodynamic integration calculation of
the surface free energy that NaCl(100) should be a well ordered, non-melting
surface, metastable even well above the melting point. By contrast, the
simulated liquid NaCl surface is found to exhibit large thermal fluctuations
and no layering order. In spite of that, it is shown to possess a relatively
large surface free energy. The latter is traced to a surface entropy deficit,
reflecting some kind of surface short range order. Finally, the solid-liquid
interface free energy is derived through Young's equation from direct
simulation of partial wetting of NaCl(100) by a liquid droplet. It is concluded
that three elements, namely the exceptional anharmonic stability of the solid
(100) surface, the molecular short range order at the liquid surface, and the
costly solid liquid interface, all conspire to cause the anomalously poor
wetting of the (100) surface by its own melt in the BMHFT model of NaCl -- and
most likely also in real alkali halide surfaces.Comment: modified version of JCP 123, 164701 15 pages, 25 figure
Why Are Alkali Halide Solid Surfaces Not Wetted By Their Own Melt?
Alkali halide (100) crystal surfaces are anomalous, being very poorly wetted
by their own melt at the triple point. We present extensive simulations for
NaCl, followed by calculations of the solid-vapor, solid-liquid, and
liquid-vapor free energies showing that solid NaCl(100) is a nonmelting
surface, and that its full behavior can quantitatively be accounted for within
a simple Born-Meyer-Huggins-Fumi-Tosi model potential. The incomplete wetting
is traced to the conspiracy of three factors: surface anharmonicities
stabilizing the solid surface; a large density jump causing bad liquid-solid
adhesion; incipient NaCl molecular correlations destabilizing the liquid
surface. The latter is pursued in detail, and it is shown that surface
short-range charge order acts to raise the surface tension because incipient
NaCl molecular formation anomalously reduces the surface entropy of liquid NaCl
much below that of solid NaCl(100).Comment: 4 pages, 3 figure
WSES classification and guidelines for liver trauma
The severity of liver injuries has been universally classified according to the American Association for the Surgery of Trauma (AAST) grading scale. In determining the optimal treatment strategy, however, the haemodynamic status and associated injuries should be considered. Thus the management of liver trauma is ultimately based on the anatomy of the injury and the physiology of the patient. This paper presents the World Society of Emergency Surgery (WSES) classification of liver trauma and the management Guidelines
Exploiting the Photonic Crystal Properties of TiO2 Nanotube Arrays To Enhance Photocatalytic Hydrogen Production
Two series of self-assembled TiO2 nanotube (NT) arrays were grown by electrochemical anodization on a metallic titanium substrate with different anodization times and applied potentials in HF-containing ethylene glycol electrolyte solutions and postcalcined at 450 \ub0C. The obtained thin films were characterized by FESEM, XRD, UV-vis-NIR DRS analyses and tested as photoanodes in incident photon to current efficiency (IPCE) measurements and in a two-compartment photoelectrochemical cell (PEC) for separate H2 and O2 production. The photocatalytic performance of the NT arrays significantly increased with an increase in the potential applied during anodization (i.e., with increasing the NT inner diameter) and the incident angle of the light. IPCE measurements revealed that such unexpected behavior is due to a red shift of the activity threshold that allows harvesting and converting a larger portion of the solar spectrum. This phenomenon is ascribed to the parallel shift of the photonic band gap position originated by the intrinsic photonic crystal properties and demonstrates the important role played by ordered hierarchical structures in improving the photocatalytic performance of NT arrays by confining and manipulating light
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