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Vasil'ev S.G.,RAS Institute of Problems of Chemical Physics | Volkov V.I.,RAS Institute of Problems of Chemical Physics | Tatarinova E.A.,Institute of Synthetic Polymeric Materials | Muzafarov A.M.,Institute of Synthetic Polymeric Materials
Applied Magnetic Resonance | Year: 2014

The self-diffusion of silicone MQ copolymers in solutions with chloroform was studied by pulsed field-gradient nuclear magnetic resonance over a wide range of macromolecular concentrations. The highly branched structure of the molecules reveals some characteristic features of the translational mobility. The studies were performed with the initial MQ copolymer as well as with the narrow-dispersed fractions obtained from it. The data indicate the differences in dynamics between fractions. The appearance of the species with different self-diffusivity with increasing of the polymer concentration in solutions was observed. Such behavior was attributed to the formation of aggregates of macromolecules in solution. The results show that the molecular weight influences the diffusion behavior of the MQ resins in solutions. The diffusion of the MQ resins reveals features characteristic for rigid macromolecular structures rather than flexible polymers. Differences in translational dynamics of MQ copolymers, linear flexible polymers and particle-like macromolecules are discussed. © 2014 Springer-Verlag Wien.


Volynskii A.L.,Moscow State University | Panchuk D.A.,Moscow State University | Bazhenov S.L.,Institute of Synthetic Polymeric Materials | Yablokov M.Y.,Institute of Synthetic Polymeric Materials | And 4 more authors.
Thin Solid Films | Year: 2013

Mechanical properties and structure of a thin aluminum coating were investigated. Experimental methods of measuring yield stress, strength and fracture strain of ultrathin coatings were developed. Yield stress, strength and fracture strain of aluminum increase with decrease in the coating thickness. The increase of yield stress and strength was explained by reduction of the crystal size and by strain-hardening of metal. © 2013 Elsevier B.V. All Rights Reserved.


Filippov A.,RAS Institute of Macromolecular Compounds | Amirova A.I.,RAS Institute of Macromolecular Compounds | Kirila T.,RAS Institute of Macromolecular Compounds | Belyaeva E.V.,RAS Institute of Macromolecular Compounds | And 2 more authors.
Polymer International | Year: 2015

The molecular and hydrodynamic properties of carbosilane pseudo-dendrimer are investigated. The comparison with solution behavior of analogues, namely, hyperbranched polymer and "perfect" dendrimer, are carried out. A carbosilane pseudo-dendrimer with irregular structure and degree of branching DB = 1 was synthesized and fractionated. The molar masses of the obtained fractions ranged from 5000 to 490 000 g mol-1. The hydrodynamic and conformational properties were studied by the methods of light scattering, sedimentation-diffusion analysis and viscometry in dilute hexane and toluene solutions. The Mark - Kuhn - Houwink dependences were obtained. The results for the pseudo-dendrimer are compared with the data for the initial hyperbranched poly(diallylcarbosilane) with DB = 0.5 and carbosilane dendrimer. It is shown that the solution properties of the pseudo-dendrimer are close to those for the irregular hyperbranched polymer and differ significantly from the dendrimer behavior. Hence, it is branching regularity rather than the degree of branching that determines the conformational and hydrodynamic properties of hyperbranched polymers with a high degree of branching DB ≥ 0.5. © 2014 Society of Chemical Industry.


Vasil'ev S.G.,RAS Institute of Problems of Chemical Physics | Volkov V.I.,RAS Institute of Problems of Chemical Physics | Tatarinova E.A.,Institute of Synthetic Polymeric Materials | Muzafarov A.M.,Institute of Synthetic Polymeric Materials
Applied Magnetic Resonance | Year: 2013

The structure of MQ copolymers of the general chemical formula [(CH3)3SiO0.5]m [SiO2]n was characterized by means of solid-state magic angle spinning (MAS) nuclear magnetic resonance (NMR) spectroscopy. The MQ copolymers are highly branched polycyclic compounds (densely cross-linked nanosized networks). MQ copolymers were prepared by hydrolytic polycondensation in active medium. 29Si NMR spectra were obtained by single pulse excitation (or direct polarization, DP) and cross-polarization (CP) 29Si{1H} techniques in concert with MAS. It was shown that material consist of monofunctional M (≡SiO Si (CH3)3) and two types of tetrafunctional Q units: Q4 ((≡SiO)4 Si) and Q3 ((≡SiO)3 SiOH). Spin-lattice relaxation times T 1 measurements of 29Si nuclei and analysis of 29Si{1H} variable contact time signal intensities allowed us to obtain quantitative data on the relative content of different sites in copolymers. These investigations indicate that MQ copolymers represent dense structure with core and shell. © 2013 The Author(s).


Home > Press > Organic crystals allow creating flexible electronic devices: The researchers from the Faculty of Physics of the Moscow State University have grown organic crystals that allow creating flexible electronic devices Abstract: Scientists from the Faculty of Physics of the Moscow State University have grown organic semiconductor crystals which can reduce the cost of the process of creating light, flexible and transparent light-emitting electronic devices of the new generation. A team of researchers from the Faculty of Physics of Moscow State University in cooperation with Russian and foreign colleagues learnt to grow organic semiconductor crystals with extremely high light-emitting efficiency that promise a bright future for wet-processed organic optoelectronics. Moreover, they made a double breakthrough using much simpler and cheaper technologies that previously were considered impractical. The scientists have published the results of their work in the latest issue of the Applied Materials and Interfaces journal. The organic optoelectronics is a rapidly growing area that promises to achieve the ultimate dream to make light, flexible and transparent electronic devices of the new generation, such as organic light-emitting transistors (OLET) and organic lasers pumped by electric current. This is, indeed, a very promising area: the organic semiconductors due to their availability can even replace silicon in some electronic applications. It was believed that the organic semiconductor crystals grown from the vapor phase are much preferred than the ones grown from solution, since those obtained from vapor are purer and free of structure impurities. A group of physicists from the Moscow State University, led by Professor Dmitry Paraschuk, are of those who do not share this opinion, and prefer the solution growing for several reasons, particularly because of much simpler and cheaper technologies stemming from this method. In their study, so called thiophene-phenylene oligomers were chosen as work-horse molecules. The desired molecules were synthesized for them by chemists from the Moscow State University and the Enikolopov Institute of Synthetic Polymeric Materials of RAS. At the Faculty of Physics of the Moscow State University crystals were grown from solution of these molecules. Their luminescent and electrical properties were measured there as well. The main results of this study were overwhelming: the solution-grown crystals are more luminescent than their analogues obtained from vapor. Their quantum yield (i.e. the ratio of the number of photons emitted to the number of absorbed ones) reached 60%, whereas vapor-grown crystals presented no more than 38%. Such a striking difference in the luminescence efficiency is explained, particularly, by the fact that, perhaps, during the solution-growing some internal radiationless channels that take some part of the excitation energy are suppressed in crystals. But, apparently, this is not the only explanation. "We have found reasons for such a high quantum yield, but we are not ready to publish these yet. This is a matter of our future studies, "- told Professor Paraschuk. It is noteworthy that despite all previously known disadvantages of the solution-growing techniques, the new study made it possible to talk about their advantages compared to the vapor-growing methods of crystals. In one of the recent researches, the group of Paraschuk found out that crystals can be grown on the surface of the solution instead of a solid substrate, due to the surface tension forces. "We have shown that it is possible to grow crystals on the surface of the liquid in different ways. Roughly speaking, after we place a solution with molecules in a vessel and then begin to cool it, under some certain conditions we allow molecules to be deposited on the surface at the "air-liquid" interface. Because the liquid surface is almost perfect, the crystals grown on it are of good quality, and owing to their high electronic performance they are much more preferable to the vapor-grown ones. Moreover, the surface of the solution-grown crystals is molecularly smooth with angstrom-scale roughness, which allows us to create field-effect transistors on their basis, and its quality is irreplaceable in this case" - says the professor. Dmitry Paraschuk emphasizes that the applicability of the crystals in light-emitted transistors, and therefore in organic optoelectronics is just a suggestion, the validity of which is still to be proved. The same situation is with the possibility of creating lasers controlled by electric current obtained on the same basis. "People dream to get lasers that can ignite by simple connection of the film to the power source, but they haven't achieved success yet,"- told Paraschuk. - "We hope that with the help of organic crystals we can reach this goal. The combination of good conductivity and high efficiency allows us to hope that the first electrically pumped laser will be created on the basis of such crystals." For more information, please click If you have a comment, please us. Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.

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