Rayleigh and Raman light scattering in hydrogen-bonded acetonitrile–water

The structure, vibrational frequencies, light scattering activities and binding energies of CH₃CNH₂O are obtained from ab initio methods. The hydrogen NH bond distance is calculated as 2.06 Å, the dipole moment as 5.77 D and our best estimate for the binding energy is 3.5 kcal mol^–1 (14.7 kJ mol^–1), after correcting for zero-point vibrations. The calculated average dipole polarizability is 39.67 au and the anisotropy is fairly large, corresponding to 21.78 au. The changes in intramolecular vibrational frequencies are analyzed. The scattering activities and depolarization of the Rayleigh and Raman light scattered are calculated. In the Raman case the depolarization due to the intense NC stretching vibration is increased by 20% after the hydrogen bond. For the OH symmetric stretch of water there is a large redshift of 75 cm^–1 and a great intensification of the Raman scattering activity by a factor of 2 and a considerable increase of the depolarization by a factor of nearly 4.From the Proceedings of the 28th Congreso de Químicos Teóricos de Expresión Latina (QUITEL 2002)     

Role of solvents in the gelation process: can light scattering studies shed some light?

Sol–gel reactions continue to be of interest for the preparation of nanostructured materials. Two chemical reactions that are important in the sol–gel process are the hydrolysis and condensation reactions. The rate of the these two reactions are affected by a number of factors such as reaction pH, temperature, humidity, amount of water, type of alkoxide, molar ratio of alkoxide to water, and nature of solvent. Moreover, there is a physical process, that of particle aggregation that is also important in the overall gelation process. The role of solvents in these chemical and physical processes is still not very clear. In order to clarify the role of solvents in the gelation process, small angle light scattering studies (SALS) were carried out. A model system chosen was a colloidal silica solution that contained preformed silica particles of 10–15 nm in diameter. SALS studies indicate that gelation times are independent of the nature of solvent.     

Test ofBΣ-interaction potentials in Na 3P-rare gas systems from light scattering

The spectral dependences in Na-rare gas optical collisions $$Na3S + X + hv \to Na3P_J + X$$ have been used to study the long range interaction in Na 3P _J -X systems. For a test of available potentials the fine structure (fs) population ratio and theJ = 3/2 alignment were measured under single collision conditions by analyzing the fluorescence emitted after selective excitation of the molecularBΣ orAΠ states as function of the laser frequencyv. A comparison was made with quantum coupled channels (CC) calculations of thermally averaged spectral profiles using the potential data to be tested as input. In addition, model calculations were performed for a qualitative understanding of the role of the various nonadiabatic couplings involved and the trends in the spectral profiles by the corresponding molecular potentials. In NaAr and NaKr theBΣ-fs wings are seen to depend sensitively on the parameters of the potentials, in particular on the well depth? _ΣII of theBΣ-AΠ difference potentials which is comparable to the spin orbit interaction in these systems; the experimental profiles show, that the actual? _ΣII values are much smaller than those predicted by the model potentials of Düren. In NaKr also theBΣ-alignment wing depends sensitively on? _ΣII caused by a long-range parity dependent rotational coupling, as follows from the CC-analysis. The comparison with the experimental alignment confirms the result from theBΣ-fs wing regarding the actual? _ΣII value.     

A resonance light scattering sensor based on methylene blue–sodium dodecyl benzene sulfonate for ultrasensitive detection of guanine base associated mutations

A resonance light scattering (RLS) sensor for guanine base associated mutations has been developed on the basis of the high selectivity of methylene blue (MB) for guanine bases in the presence of sodium dodecyl benzene sulfonate (SDBS). MB, when bound to SDBS, underwent a dramatic enhancement of its RLS intensity. However, the addition of double-stranded DNA (dsDNA) and single-stranded DNA (ssDNA) caused the strong RLS intensity of MB-SDBS to decrease, and the RLS intensity of MB-SDBS-ssDNA was much lower than that of MB-SDBS-dsDNA. Consequently, it can be concluded that the binding abilities of MB-SDBS with ssDNA and dsDNA were different. Besides, the experimental results showed that MB-SDBS could bind specifically to oligonucleotides rich in guanine bases. Short DNA targets with sequences related to β-thalassaemia, thrombophilia and psoriasis, all of which are guanine base relevant mutations, were synthesized. It was found that MB-SDBS could recognize the single-base mismatches in the mutational DNA, followed by different RLS signal changes between MB-SDBS-normal DNA systems and MB-SDBS-mutational DNA systems. The ultrasensitive sensor allows simple, rapid, sensitive and selective detection of guanine base associated mutations, indicating its potential application in the medical field.     

A dynamical Lie algebraic mehtod for quantum reactive scattering

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Dilute solutions of compositionally heterogeneous κ-carrageenan studied by combined dynamic and static light scattering

Dilute water–salt solutions of compositionally heterogeneous κ-carrageenan (κ-CG) containing 3% of ι-CG units are studied by combined static and dynamic (DLS) light scattering in 0.1M NaCl at 25°C. The structure-sensitive ratio R_g/R_h?=?2.2 of the fast DLS mode corresponds to the coils of κ-CG homopolymer. The irreversible core–shell aggregates (R_g/R_h?=?0.4) give rise to a slow mode. The optical rotation reveals that the aggregates originate from helical fragments of contaminating multi-block κ/ι-copolymers. Comparison with capillary viscometry shows that the weight fraction of aggregates is as small as the fraction of contaminating κ/ι-hybrids.     

Can the light scattering depolarization ratio of small particles be greater than 1/3?

According to the theory of light scattering by small randomly oriented particles, the depolarized ratio of the scattered intensities, I(vh)/I(vv), cannot exceed 1/3. Here we show that this conclusion does not hold for nonspherical plasmon resonant metal particles. Our analysis is based on the Rayleigh approximation and the exact T-matrix method as applied to spheroids and circular cylinders with semispherical ends. For small particles, the condition I(vh)/I(vv) >1/3 can be satisfied within the upper left quadrant of the complex relative dielectric permeability Real(eps) < -2 (rods) and within the upper unit semicircle centered at Real(eps) = -1 (disks). For gold nanorods with the axis ratio exceeding 2, the maximal theoretical values I(vh)/I(vv) lie between 1/3 and 3/4 at wavelengths of 550-650 nm. The extinction and static light scattering spectra (450-850 nm, at 90 degrees degrees) as well as the depolarized ratio of He-Ne laser light scattering were measured with gold nanospheres (the average diameters of 21, 29, and 46 nm) and nanorods (the longitudinal plasmon resonance peak positions at 655, 692, and 900 nm). The measured depolarization ratios of nanospheres (0.07-0.16) and nanorods (0.3-0.48) are in good agreement with theoretical calculations based on estimations of the average particle size and shape.     

Silver nanoparticle labeled immunoresonance scattering spectral assay for trace fibrinogen

Silver nanoparticles in size of 8.0 nm was prepared by the trisodium citrate and used to label goat anti-human fibrinogen. In the pH 5.8 Na2HPO4-NaH2O4 buffer solution (PBS) and in the presence of polyethylene glycol (PEG) and KCl, the immune reaction between silver-labeled goat anti-human fibrinogen and fibrinogen took place and led the resonance scattering intensity at 465 nm (I465) to decreasing. The I465 decreased intensity was linear to the fibrinogen concentration in the range from 0.067 to 1.67 μg/mL, with a detection limit of 0.024 μg/mL. This method was applied to determination of fibrinogen in human plasma, with satisfactory results.     

Structural characterization of protein–polymer conjugates for biomedical applications with small-angle scattering

Protein–polymer conjugates, typically consisting of one or more polymers covalently attached to a protein, are an increasingly common component in biotechnology. Polymers can increase circulation time, alter immune responses, and influence the self-assembly of proteins to which they are attached. To understand and take full advantage of the benefits that protein–polymer conjugates provide, there is a strong need for structural characterization of both the conjugates and their self-assembled structures. Although X-ray crystallography is suitable for determining protein structure, protein–polymer conjugates do not generally crystallize, requiring the use of alternative techniques. Small-angle scattering, with neutrons in particular, is one such technique. In this article, we review recent work in the area of protein–polymer conjugates and highlight the important role that structure plays. We then highlight shape-dependent and shape-independent approaches for structural characterization of protein–polymer conjugates and future directions in small-angle scattering interpretation. We conclude by introducing a new model that we suggest may be useful in the future to acquire more detailed structural properties.     

Visible light–driven photoelectrocatalytic semiconductor heterojunction anodes for water treatment applications

Research interest in photoelectrocatalysis or photoelectrochemical oxidation processes for water treatment is on the increase. This is because this method has the ability to abate a wide range of recalcitrant organic pollutants from wastewater. The application of visible or solar light, which has the potential to reduce cost, increase safety, and increase sustainability, is a recent direction in this novel electrochemical technology for water treatment. This review focuses on the use of semiconductor heterojunctions as a way of tuning the photoanode towards visible light activation. The classifications, preparations and various applications of semiconductor heterojunction for the removal of organic pollutants from water in the past two years are presented with concluding remarks and future perspective.     

Determination of molecular weight of polyethylene glycol using size-exclusion chromatography with multi-angle laser light scattering and acid–base titration

Size-exclusion chromatography with multi-angle laser light scattering (SEC-MALLS) and acid–base titration were used to determine the molecular weight of a polyethylene glycol with low molecular weight. All potential uncertainty factors for each measurement were evaluated using cause-effect diagrams. Weight analysis was applied to harmonize the two different measurement results. It was found that the main uncertainty sources of SEC-MALLS measurement arose from the dn/dc value, the calibration constant of the differential refractive index (DRI) detector, and the intermediate precision of the instrument, while the sample mass, the titration volume and the concentration of titrant contributed to the uncertainty of titration measurement. The weighted mean value of the two measurement results was taken as the molecular weight of the polyethylene glycol.     

Investigations on structure of regioselectively functionalized celluloses ID solution exemplified by using 3-β-alkyl ethers and light scattering

Regioselectively functionalized 3--alkyl ethers of cellulose (alkyl =-pentyl, isopentyl, dodecyl) can be synthesized using 2,6-di--thexyldimethylsilyl cellulose as a protected intermediate. ID comparison to the corresponding 2,3,6-tri--alkyl ethers, the dissolution behavior and the structure ID solution of the 3--alkyl ethers were investigated using light scattering. The aim of the paper ID to present the first experimental and systematic work on specific properties of regioselectively modified celluloses. The results of structure investigation ID solution are discussed ID detail and lead to a primary understanding of interactions of this type of cellulosics on a molecular and supramolecular level.     

Analysis of ″stepwise″ heterocoagulation process of small cationic polymer particles onto large anionic polymer particles using dynamic light scattering

In order to clarify in detail the process of the stepwise heterocoagulation of small polymer particles (SP) onto large polymer particles (LP), which we proposed to prepare anomalous polymer particles, the particle-size distribution in each step was estimated using dynamic light scattering.SP andLP have surface charges opposite to each other in emulsion states.SP were produced by emulsion copolymerization of styrene and methacryloyloxyethyltrimethylammonium chloride, andLP by emulsion terpolymerization of styrene, butyl acrylate, and methacrylic acid. Both emulsions in which nonionic emulsifier had been added were blended without coagulation and then the heterocoagulation was carried out by adjusting of the pH and heating.Part CXVII of the series Studies on Suspension and Emulsion.     

Determination of trace uranium (VI) using its self-assembly with a tetradentate–monodentate ditopic ligand by resonance light scattering

We describe here a resonance light scattering (RLS) method for uranium (VI) detection by using phosphorylethanol-amido-salophen (PAS) as optical probe. PAS is a tetradentate–monodentate ditopic ligand in which the tetradentate and monodentate ligands are salophen moiety and phosphate group, respectively. PAS can chelate uranyl with its salophen moiety. The chelated uranyl can connect phosphate group in another PAS through coordination reaction. This causes the self-assembly of PAS with uranyl to form a metallo-supramolecular polymer, resulting in a production of strong RLS signal. The RLS method was established based on the self-assemble. The RLS intensity is linearly related to the concentration of uranium (VI) in the 0.8–32 ng mL^?1 range, with a detection limit of 0.24 ng mL^?1 detection limit under optimal conditions. The method was successfully applied to determine uranium (VI) in environmental water samples with the recoveries between 97.1% and 102.6%.     

A gold@silica core–shell nanoparticle-based surface-enhanced Raman scattering biosensor for label-free glucose detection

The gold nanostar@silica core–shell nanoparticles conjugated with glucose oxidase (GOx) enzyme molecules have been developed as the surface-enhanced Raman scattering (SERS) biosensor for label-free detection of glucose. The surface-immobilized GOx enzyme catalyzes the oxidation of glucose, producing hydrogen peroxide. Under laser excitation, the produced H₂O₂ molecules near the Au nanostar@silica nanoparticles generate a strong SERS signal, which is used to measure the glucose concentration. The SERS signal of nanostar@silica∼GOx nanoparticle-based sensing assay shows the dynamic response to the glucose concentration range from 25 μM to 25 mM in the aqueous solution with the limit of detection of 16 μM. The sensing assay does not show any interference when glucose co-exists with both ascorbic acid and uric acid. The sensor can be applied to a saliva sample.     

Visible light induced four component reaction of styrene for the access of thiodifluoroesters

The visible light induced multicomponent reaction of styrene, carbon disulfide, amine and ethyl difluorobromoacetate for the synthesis of thiodifluoroesters is disclosed. This developed protocol offers a facile and general route to access various valuable thiodifluoroesters in moderate to good yields. Preliminary mechanistic studies revealed that a radical process might be involved in this transformation.     

Model to describe light scattering by polymer film containing droplets with inhomogeneous anchoring of liquid crystal molecules at the polymer–droplet interface: asymmetry effect in the angular distribution of light

A model to describe light scattering by polymer film containing of monolayer of liquid crystal droplets with inhomogeneous anchoring of liquid crystal molecules at the polymer-droplet interface is developed. It is based on the interference approximation of the wave scattering theory. The director field distribution in the droplet volume is determined by solving the free energy density minimization problem using the relaxation method. The spatial distribution of droplets in the layer is described by the hard disks model. The amplitude scattering matrices of individual droplets are found in the anomalous diffraction approximation. The algorithm for numerical analysis of the characteristics of light scattered in a polymer film containing droplets at homogeneous and inhomogeneous surface anchoring is described in terms of the partial filling factors of the monolayer film. Electrically controllable symmetry breaking effect of angular distribution of light scattered by films containing droplets with inhomogeneous anchoring at the polymer-droplet interface is described and experimentally confirmed.     

Determination of triadimenol based on the quenching effect on resonance light scattering from the triadimenol–deoxyribonucleic acid–hydrochloric acid system

Analysis of triadimenol was carried out using deoxyribonucleic acids (DNA) via the resonance light scattering (RLS) technique. After adding triadimenol into aqueous medium of pH 1.72, the RLS of DNA was remarkably quenched. A resonance light scattering peak at 310 nm was found, and the quenched intensity of RLS at this wavelength was proportional to the concentration of triadimenol. The linear range of the calibration curve was approximately 0–3 μg mL⁻¹ with a detection limit (S/N = 3) of 0.07 μg mL⁻¹. The triadimenol in samples of water, cucumber and human serum was determined. The results were satisfactory, and the recovery rates were in the range of 96.3–106.0%, 94.8–105.9% and 92.3–100.5%, respectively. The interaction mechanism was also studied.     

The S-matrix version of the Hulthén-Kohn variational principle for quantum scattering: Finite element calculations for state-to-state reaction probabilities

Summary The finite element (FE) method can be applied to solve the reactive scattering problem of the A + BC AB + C type. We are using the S-matrix version of the Hulthén-Kohn variational principle for the two-dimensional collinear problem. The asymptotic wavefunction is described by analytical functions and the interaction part by FE functions.Two approaches are used and compared to each other: 1) FE functions are employed as the basis functions for the interior part of the potential; 2) the FE method is used in order to calculate eigenfunctions for the interior region of the potential and then these eigenfunctions are used as a new basis. In the second case two ways of choosing grid points are applied. First a grid is built that covers both reaction channels, secondly we considered the two reactions channels separately and two basis sets are used in the scattering calculations. This last version would be more helpful from the point of application to three-dimensional non-collinear problems. Results obtained by raising the number of elements, or by increasing the polynomial order, are compared. General formulas for the formfunctions in case of arbitrary order of the polynomials will be presented.Dedicated to the 60th birthday of Prof. Jan Linderberg (Aarhus)