513 research outputs found
Effects of jamming on non-equilibrium transport times in nano-channels
Many biological channels perform highly selective transport without direct
input of metabolic energy and without transitions from a 'closed' to an 'open'
state during transport. Mechanisms of selectivity of such channels serve as an
inspiration for creation of artificial nano-molecular sorting devices and
bio-sensors. To elucidate the transport mechanisms, it is important to
understand the transport on the single molecule level in the experimentally
relevant regime when multiple particles are crowded in the channel. In this
paper we analyze the effects of inter-particle crowding on the non-equilibrium
transport times through a finite-length channel by means of analytical theory
and computer simulations
Taylor dispersion with absorbing boundaries: A Stochastic Approach
We describe how to solve the problem of Taylor dispersion in the presence of
absorbing boundaries using an exact stochastic formulation. In addition to
providing a clear stochastic picture of Taylor dispersion, our method leads to
closed-form expressions for all the moments of the convective displacement of
the dispersing particles in terms of the transverse diffusion eigenmodes. We
also find that the cumulants grow asymptotically linearly with time, ensuring a
Gaussian distribution in the long-time limit. As a demonstration of the
technique, the first two longitudinal cumulants (yielding respectively the
effective velocity and the Taylor diffusion constant) as well as the skewness
(a measure of the deviation from normality) are calculated for fluid flow in
the parallel plate geometry. We find that the effective velocity and the
skewness (which is negative in this case) are enhanced while Taylor dispersion
is suppressed due to absorption at the boundary.Comment: 4 pages, 1 figur
Thermodiffusion in model nanofluids by molecular dynamics simulations
In this work, a new algorithm is proposed to compute single particle
(infinite dilution) thermodiffusion using Non-Equilibrium Molecular Dynamics
simulations through the estimation of the thermophoretic force that applies on
a solute particle. This scheme is shown to provide consistent results for
simple Lennard-Jones fluids and for model nanofluids (spherical non-metallic
nanoparticles + Lennard-Jones fluid) where it appears that thermodiffusion
amplitude, as well as thermal conductivity, decrease with nanoparticles
concentration. Then, in nanofluids in the liquid state, by changing the nature
of the nanoparticle (size, mass and internal stiffness) and of the solvent
(quality and viscosity) various trends are exhibited. In all cases the single
particle thermodiffusion is positive, i.e. the nanoparticle tends to migrate
toward the cold area. The single particle thermal diffusion 2 coefficient is
shown to be independent of the size of the nanoparticle (diameter of 0.8 to 4
nm), whereas it increases with the quality of the solvent and is inversely
proportional to the viscosity of the fluid. In addition, this coefficient is
shown to be independent of the mass of the nanoparticle and to increase with
the stiffness of the nanoparticle internal bonds. Besides, for these
configurations, the mass diffusion coefficient behavior appears to be
consistent with a Stokes-Einstein like law
Universality in edge-source diffusion dynamics
We show that in edge-source diffusion dynamics the integrated concentration
N(t) has a universal dependence with a characteristic time-scale tau=(A/P)^2
pi/(4D), where D is the diffusion constant while A and P are the
cross-sectional area and perimeter of the domain, respectively. For the
short-time dynamics we find a universal square-root asymptotic dependence
N(t)=N0 sqrt(t/tau) while in the long-time dynamics N(t) saturates
exponentially at N0. The exponential saturation is a general feature while the
associated coefficients are weakly geometry dependent.Comment: 4 pages including 4 figures. Minor changes. Accepted for PR
Superdiffusion in quasi-two-dimensional Yukawa liquids
The emergence and vanishing of superdiffusion in quasi-two-dimensional Yukawa
systems are investigated by molecular dynamics simulations. Using both the
asymptotic behaviour of the mean-squared displacement of the particles and the
long-time tail of the velocity autocorrelation function as indicators for
superdiffusion, we confirm the existence of a transition from normal diffusion
to superdiffusion in systems changing from a three-dimensional to a
two-dimensional character. A connection between superdiffusion and
dimensionality is established by the behaviour of the projected pair
distribution function
Optimal Counter-current exchange networks
We present a general analysis of exchange devices linking their efficiency to the geometry of the exchange surface and supply network. For certain parameter ranges, we show that the optimal exchanger consists of densely packed pipes which can span a thin sheet of large area (an “active layer”), which may be crumpled into a fractal surface and supplied with a fractal network of pipes. We derive the efficiencies of such exchangers, showing the potential for significant gains compared to regular exchangers (where the active layer is flat), using parameters relevant to biological systems
Green tea improves metabolic biomarkers, not weight or body composition: a pilot study in overweight breast cancer survivors
Abstract Background: Overweight status after breast cancer treatment may increase a woman's risk for recurrent disease and/or early onset cardiovascular disease. Green tea has been proposed to promote weight loss and favourably modify glucose, insulin and blood lipids. This pilot study tested the effect of daily decaffeinated green tea consumption for 6 months on weight and body composition, select metabolic parameters and lipid profiles in overweight breast cancer survivors. Methods: The effect of daily decaffeinated green tea intake on weight, body composition and changes in resting metabolic rate, energy intake, glucose, insulin, homeostasis model assessment -insulin resistance (HOMA-IR) and lipids was evaluated in overweight breast cancer survivors. Participants had a mean weight of 80.2 kg; body mass index (BMI) 30.1 kg m )2 ; and body fat 46.4%. Participants (n = 54) were randomised to 960 mL of decaffeinated green or placebo tea daily for 6 months. Results: Mean (SD) tea intake among study completers (n = 39) was 5952 (1176) mL week )1 and was associated with a significant reduction in energy intake (P = 0.02). Change in body weight of )1.2 kg (green tea) versus +0.2 kg (placebo) suggests a weight change effect, although this was not statistically significant. Decaffeinated green tea intake was associated with elevated high-density lipoprotein (HDL) levels (P = 0.003) and nonsignificant improvements in the HDL/LDL ratio and HOMA-IR ()1.1 ± 5.9: green tea; +3.2 ± 7.2: herbal). Conclusions: Intake of decaffeinated green tea for 6 months was associated with a slight reduction in body weight and improved HDL and glucose homeostasis in overweight breast cancer survivors
Infinite Lifetime of Underwater Superhydrophobic States
Submerged superhydrophobic (SHPo) surfaces are well known to transition from the dewetted to wetted state over time. Here, a theoretical model is applied to describe the depletion of trapped air in a simple trench and rearranged to prescribe the conditions for infinite lifetime. By fabricating a microscale trench in a transparent hydrophobic material, we directly observe the air depletion process and verify the model. The study leads to the demonstration of infinite lifetime (>50 days) of air pockets on engineered microstructured surfaces under water for the first time. Environmental fluctuations are identified as the main factor behind the lack of a long-term underwater SHPo state to date
Diffusiophoretic Focusing of Suspended Colloids
Using a microfluidic system to impose and maintain controlled, steady-state multicomponent pH and electrolyte gradients, we present systems where the diffusiophoretic migration of suspended colloids leads them to focus at a particular position, even in steady-state gradients. We show that naively superpositing effects of each gradient may seem conceptually and qualitatively reasonable, yet is invalid due to the coupled transport of these multicomponent electrolytes. In fact, reformulating the classic theories in terms of the flux of each species (rather than local gradients) reveals rather stringent conditions that are necessary for diffusiophoretic focusing in steady gradients. Either particle surface properties must change as a function of local composition in solution (akin to isoelectric focusing in electrophoresis), or chemical reactions must occur between electrolyte species, for such focusing to be possible. The generality of these findings provides a conceptual picture for understanding, predicting, or designing diffusiophoretic systems
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