771,083 research outputs found
Charge localization in multiply charged clusters and their electrical properties: Some insights into electrospray droplets
The surface composition of charged Lennard-Jones clusters A,
composed of N particles (55 \leq N \leq 1169) among which n are positively
charged with charge q, thus having a net total charge Q = nq, is investigated
by Monte Carlo with Parallel Tempering simulations. At finite temperature, the
surface sites of these charged clusters are found to be preferentially occupied
by charged particles carrying large charges, due to Coulombic repulsions, but
the full occupancy of surface sites is rarely achieved for clusters below the
stability limit defined in this work. Large clusters (N = 1169) follow the same
trends, with a smaller propensity for positive particles to occupy the cluster
surface at non-zero temperature. We show that these charged clusters rather
behave as electrical spherical conductors for the smaller sizes (N \leq 147)
but as spheres uniformly charged in their volume for the larger sizes (N =
1169).Comment: 10 pages and 4 figure
Boundary Condition of Polyelectrolyte Adsorption
The modification of the boundary condition for polyelectrolyte adsorption on
charged surface with short-ranged interaction is investigated under two
regimes. For weakly charged Gaussian polymer in which the short-ranged
attraction dominates, the boundary condition is the same as that of the neutral
polymer adsorption. For highly charged polymer (compressed state) in which the
electrostatic interaction dominates, the linear relationship (electrostatic
boundary condition) between the surface monomer density and the surface charge
density needs to be modified.Comment: 4 page
Surface-induced layer formation in polyelectrolytes
We analyze, by means of an RPA calculation, the conditions under which a
mixture of oppositely charged polyelectrolytes can micro-segregate in the
neighborhood of a charged surface creating a layered structure. A number of
stable layers can be formed if the surface is sufficiently strongly charged
even at temperatures at which the bulk of the mixture is homogeneous.Comment: 6 pages, 3 figures, revtex, epsf, psfi
Method and apparatus for neutralizing potentials induced on spacecraft surfaces
A potential induced on the surface of an orbiting spacecraft is neutralized to the potential of a plasma through which the spacecraft is traveling by directing charged particles into the plasma from the spacecraft surface. The induced potential occurs in response to bombardment of the spacecraft surface by ambient charged particles which may be negative or positive. The charged particles directed into the plasma from the surface have the same polarity as the induced potential to provide the neutralization. The invention can be utilized to maintain different, electrically isolated segments of a spacecraft surface at the same potential to prevent electric discharges between the different parts and thereby protect electric circuits within the spacecraft
Electrochemical Attachment of Motile Bacterial Cells to Gold
Selective attachment of Escherichia coli K-12 bacterial cells to charged gold surfaces was demonstrated. Electrostatic binding of E. coli K-12 bacterial cells to positively charged surfaces was observed starting at +750 mV. The binding of E. coli K-12 cells to positively charged gold surfaces is proposed to occur due to long-range electrostatic interactions between the negatively charged O-chain of lipopolysaccharide (LPS) molecules protruding the bacterial cell body and the electrode surface. Removing LPS alters the cellular surface charge and results in cellular attachment to negatively charged surfaces. Thus, applying an electrical potential allows for the direct, real time detection of live, dead or damaged bacterial cells. The attachment of E. coli K-12 bacterial cells to surfaces with an applied potential substantiates the hypothesis that an electrostatic interaction is responsible for the binding of bacterial cells to positively charged molecular assemblies on surfaces used for building bacterial microarrays
Polyelectrolyte Multilayering on a Charged Planar Surface
The adsorption of highly \textit{oppositely} charged flexible
polyelectrolytes (PEs) on a charged planar substrate is investigated by means
of Monte Carlo (MC) simulations. We study in detail the equilibrium structure
of the first few PE layers. The influence of the chain length and of a (extra)
non-electrostatic short range attraction between the polycations and the
negatively charged substrate is considered. We show that the stability as well
as the microstructure of the PE layers are especially sensitive to the strength
of this latter interaction. Qualitative agreement is reached with some recent
experiments.Comment: 28 pages; 11 (main) Figs - Revtex4 - Higher resolution Figs can be
obtained upon request. To appear in Macromolecule
On the possibility to supercool molecular hydrogen down to superfluid transition
Recent calculations by Vorobev and Malyshenko (JETP Letters, 71, 39, 2000)
show that molecular hydrogen may stay liquid and superfluid in strong electric
fields of the order of . I demonstrate that strong local
electric fields of similar magnitude exist beneath a two-dimensional layer of
electrons localized in the image potential above the surface of solid hydrogen.
Even stronger local fields exist around charged particles (ions or electrons)
if surface or bulk of a solid hydrogen crystal is statically charged.
Measurements of the frequency shift of the photoresonance transition
in the spectrum of two-dimensional layer of electrons above positively or
negatively charged solid hydrogen surface performed in the temperature range 7
- 13.8 K support the prediction of electric field induced surface melting. The
range of surface charge density necessary to stabilize the liquid phase of
molecular hydrogen at the temperature of superfluid transition is estimated.Comment: 5 pages, 2 figure
Adsorption and Depletion of Polyelectrolytes from Charged Surfaces
Mean-field theory and scaling arguments are presented to model
polyelectrolyte adsorption from semi-dilute solutions onto charged surfaces.
Using numerical solutions of the mean-field equations, we show that adsorption
exists only for highly charged polyelectrolytes in low salt solutions. Simple
scaling laws for the width of the adsorbed layer and the amount of adsorbed
polyelectrolyte are obtained. In other situations the polyelectrolyte chains
will deplete from the surface. For fixed surface potential conditions, the salt
concentration at the adsorption--depletion crossover scales as the product of
the charged fraction of the polyelectrolyte f and the surface potential, while
for a fixed surface charge density, \sigma, it scales as \sigma^{2/3}f^{2/3},
in agreement with single-chain results.Comment: 12 pages, 8 figures, final version to be published in J. Chem. Phys.
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