Thermosensitive water‐soluble poly(ethylene glycol)‐based polythiophene graft copolymers

Diethyleneglycol methylethermethacrylate(MeO₂MA) and oligoethylene glycol methylethermethacrylate(OEGMA) are polymerized on polythiophene(PT) backbone to produce water‐soluble PT‐g‐PMeO₂MA(PTD) and PT‐g‐P(MeO₂MA‐co‐OEGMA)(PTDO) using atom transfer radical polymerization. They are characterized by ¹H NMR and GPC techniques. TEM micrographs indicate that PT‐chains self‐organize as nanospheres, and atomic force micrographs suggest that aggregated PT‐chains are present at the centre surrounded by dispersed PMeO₂MA fibers producing miceller‐type aggregates. Dynamic light scattering study indicates an initial decrease followed by sharp increase of Z‐average particle size of PTD with temperature for attaining lower critical solution temperature (LCST) at 20 °C. The LCST increases with OEGMA concentration in PTDO. The temperature dependent PL emission of PTD shows a minimum at 19 °C, followed by a sharp increase till 21 °C, and in the cooling cycle, it shows a complete reversibility. In the PTDO copolymers, the PL intensity shows the hike at progressively higher temperatures due to the increase of LCST with increasing OEGMA concentration. © 2012 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2013     

Kinetics of hydrogen bonds in aqueous solutions of cyclodextrin and its methyl-substituted forms

Molecular dynamics simulations of β-cyclodextrin (BCD) and its two methyl-substituted derivatives, namely, heptakis(2,6-di-O-methyl)-β-cyclodextrin (DIMEB) and heptakis(2,3,6-tri-O-methyl)-β-cyclodextrin (TRIMEB) have been performed in aqueous solutions. Detailed analyses were carried out to investigate the effects of substitution on the kinetics of cyclodextrin-water and water-water hydrogen bonds formed by water present in the hydration layers around these macromolecules as well as those formed by water inside their cavities. It is observed that increased geometrical constraints due to substitution of the OH groups of the glucose rings of the BCD molecule result in rapid establishment of hydrogen bond breaking and reformation equilibria for DIMEB and TRIMEB. This has been found to be the microscopic origin of highly rigid arrangement of water around TRIMEB and inside its cavity, as against water in and around BCD and DIMEB.     

Role of confinements on the melting of Wigner molecules in quantum dots

We explore the stability of a Wigner molecule (WM) formed in confinements with differentgeometries emulating the role of disorder and analyze the melting (or crossover) of such asystem. Building on a recent calculation [D. Bhattacharya, A. Ghosal, Eur. Phys. J.B 86, 499 (2013)] that discussed the effects of irregularities on thethermal crossover in classical systems, we expand our studies in the untested territory byincluding both the effects of quantum fluctuations and ofdisorder. Our results, using classical and quantum (path integral)Monte Carlo techniques, unfold complementary mechanisms that drive the quantum and thermalcrossovers in a WM and show that the symmetry of the confinement plays no significant rolein determining the quantum crossover scale n_X. This is because thezero-point motion screens the boundary effects within short distances. The phase diagramas a function of thermal and quantum fluctuations determined from independent criteria isunique, and shows “melting” from the WM to both the classical and quantum “liquids”. Anintriguing signature of weakening liquidity with increasing temperature, T, is found in the extreme quantum regime. The crossover is associated with production of defects. However, thesedefects appear to play distinct roles in driving the quantum and thermal “melting”. Ouranalyses carry serious implications for a variety of experiments on many-particle systems? semiconductor heterostructure quantum dots, trapped ions, nanoclusters, colloids and complex plasma.     

Fluorescence behavior of intramolecular charge transfer probe in anionic, cationic, and nonionic micelles

The intramolecular charge transfer (ICT) property of trans-ethyl p-(dimethylamino) cinnamate is used to probe the anionic, cationic, and nonionic micelles by steady-state and picosecond time-resolved fluorescence spectroscopy. The ICT fluorescence band intensity was found to increase with concomitant blue shift with addition of surfactants. All the experimental results suggest that the probe molecule resides in the micelle-water interface rather than going into the core. However, the penetration is more toward the micellar core in nonionic surfactants when compared with ionic micelles. The decrease in nonradiative decay constants in micellar environments indicate restricted motion of the probe toward the formation of ICT state. Critical micelle concentrations were determined from the sharp change in fluorescence intensity and effective dielectric constants of the micelle-water interface were calculated from the correlation diagram of 0,0 transition energy with polarity of the medium.     

Zwitterionic imidazolium salt: An efficient organocatalyst for tetrahydropyranylation of alcohols

An aprotic imidazole based zwitterionic-salt, 4-(3-methylimidazolium)-butane sulfonate has been found to be an efficient organocatalyst for tetrahydropyranylation by the reaction of 3,4-dihydro-2H-pyran (DHP) and different aliphatic alcohols as well as various phenolic compounds. The notable advantages of the present method are general applicability to various alcohols, clean reaction, production of no hazardous waste, open air reaction conditions and high yields. The catalyst can be reused without the loss of significant catalytic activity.     

A method for characterizing adsorption of flowing solutes to microfluidic device surfaces

We present a method for characterizing the adsorption of solutes in microfluidic devices that is sensitive to both long-lived and transient adsorption and can be applied to a variety of realistic device materials, designs, fabrication methods, and operational parameters. We have characterized the adsorption of two highly adsorbing molecules (FITC-labeled bovine serum albumin (BSA) and rhodamine B) and compared these results to two low adsorbing species of similar molecular weights (FITC-labeled dextran and fluorescein). We have also validated our method by demonstrating that two well-known non-fouling strategies [deposition of the polyethylene oxide (PEO)-like surface coating created by radio-frequency glow discharge plasma deposition (RF-GDPD) of tetraethylene glycol dimethyl ether (tetraglyme, CH(3)O(CH(2)CH(2)O)(4)CH(3)), and blocking with unlabeled BSA] eliminate the characteristic BSA adsorption behavior observed otherwise.     

Diffusion thermopower of the two-dimensional electron gas in GaN single quantum wells

Diffusion thermopower ($S_d$) of the two-dimensional (2D) electron gas in GaN single quantum wells is calculated in the temperature range 1 K–12 K using the Fermi–Dirac distribution function. Scattering of carriers through acoustic phonons via deformation potential and piezoelectric couplings, and through background and remote ionized impurities is included. $S_d$ is found to decrease with temperature and the 2D electron concentration, and is primarily controlled by deformation potential acoustic scattering. The dependence of $S_d$ on the well width and the ionized impurity concentration is found to be quite weak.     

Steady state convergence acceleration of the generalized lattice Boltzmann equation with forcing term through preconditioning

Several applications exist in which lattice Boltzmann methods (LBM) are used to compute stationary states of fluid motions, particularly those driven or modulated by external forces. Standard LBM, being explicit time-marching in nature, requires a long time to attain steady state convergence, particularly at low Mach numbers due to the disparity in characteristic speeds of propagation of different quantities. In this paper, we present a preconditioned generalized lattice Boltzmann equation (GLBE) with forcing term to accelerate steady state convergence to flows driven by external forces. The use of multiple relaxation times in the GLBE allows enhancement of the numerical stability. Particular focus is given in preconditioning external forces, which can be spatially and temporally dependent. In particular, correct forms of moment projections of source/forcing terms are derived such that they recover preconditioned Navier–Stokes equations with non-uniform external forces. As an illustration, we solve an extended system with a preconditioned lattice kinetic equation for magnetic induction field at low magnetic Prandtl numbers, which imposes Lorentz forces on the flow of conducting fluids. Computational studies, particularly in three-dimensions, for canonical problems show that the number of time steps needed to reach steady state is reduced by orders of magnitude with preconditioning. In addition, the preconditioning approach resulted in significantly improved stability characteristics when compared with the corresponding single relaxation time formulation.