6 results on '"Rubinstein, Michael"'
Search Results
2. Perfect mixing of immiscible macromolecules at fluid interfaces.
- Author
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Sheiko, Sergei S., Zhou, Jing, Arnold, Jamie, Neugebauer, Dorota, Matyjaszewski, Krzysztof, Tsitsilianis, Constantinos, Tsukruk, Vladimir V., Carrillo, Jan-Michael Y., Dobrynin, Andrey V., and Rubinstein, Michael
- Subjects
MACROMOLECULES ,MOIETIES (Chemistry) ,SUPRAMOLECULAR chemistry ,POLYMER structure ,THIN films -- Design & construction ,FREE energy (Thermodynamics) ,ATOMIC force microscopy - Abstract
The difficulty of mixing chemically incompatible substances-in particular macromolecules and colloidal particles-is a canonical problem limiting advances in fields ranging from health care to materials engineering. Although the self-assembly of chemically different moieties has been demonstrated in coordination complexes, supramolecular structures, and colloidal lattices among other systems, the mechanisms of mixing largely rely on specific interfacing of chemically, physically or geometrically complementary objects. Here, by taking advantage of the steric repulsion between brush-like polymers tethered to surface-active species, we obtained long-range arrays of perfectly mixed macromolecules with a variety of polymer architectures and a wide range of chemistries without the need of encoding specific complementarity. The net repulsion arises from the significant increase in the conformational entropy of the brush-like polymers with increasing distance between adjacent macromolecules at fluid interfaces. This entropic-templating assembly strategy enables long-range patterning of thin films on sub-100 nm length scales. [ABSTRACT FROM AUTHOR]
- Published
- 2013
- Full Text
- View/download PDF
3. Adsorption-induced scission of carbon–carbon bonds.
- Author
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Sheiko, Sergei S., Sun, Frank C., Randall, Adrian, Shirvanyants, David, Rubinstein, Michael, Lee, Hyung-il, and Matyjaszewski, Krzysztof
- Subjects
CARBON ,CHEMICAL bonds ,MOLECULAR association ,MACROMOLECULES ,CHEMICAL reactions ,POLYMER solutions ,SCISSION (Chemistry) - Abstract
Covalent carbon–carbon bonds are hard to break. Their strength is evident in the hardness of diamonds and tensile strength of polymeric fibres; on the single-molecule level, it manifests itself in the need for forces of several nanonewtons to extend and mechanically rupture one bond. Such forces have been generated using extensional flow, ultrasonic irradiation, receding meniscus and by directly stretching a single molecule with nanoprobes. Here we show that simple adsorption of brush-like macromolecules with long side chains on a substrate can induce not only conformational deformations, but also spontaneous rupture of covalent bonds in the macromolecular backbone. We attribute this behaviour to the fact that the attractive interaction between the side chains and the substrate is maximized by the spreading of the side chains, which in turn induces tension along the polymer backbone. Provided the side-chain densities and substrate interaction are sufficiently high, the tension generated will be strong enough to rupture covalent carbon–carbon bonds. We expect similar adsorption-induced backbone scission to occur for all macromolecules with highly branched architectures, such as brushes and dendrimers. This behaviour needs to be considered when designing surface-targeted macromolecules of this type—either to avoid undesired degradation, or to ensure rupture at predetermined macromolecular sites. [ABSTRACT FROM AUTHOR]
- Published
- 2006
- Full Text
- View/download PDF
4. Polymers: A multitude of macromolecules.
- Author
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Granick, Steve and Rubinstein, Michael
- Subjects
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POLYMERS , *MACROMOLECULES , *MATERIALS science , *SUPRAMOLECULAR chemistry , *ENGINEERING - Abstract
Focuses on the current state of the evolution of polymer science. Possibility of threading some types of polymer chains through hollow ring-shaped molecules; Facilitation of a comprehensive review of the relevant techniques in the field of polymer engineering; Assessment of the thermodynamic stability of novel materials with interpenetrating chemistry.
- Published
- 2004
- Full Text
- View/download PDF
5. Tension Amplification in Tethered Layers of Bottle-Brush Polymers.
- Author
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Leuty, Gary M., Tsige, Mesfin, Grest, Gary S., and Rubinstein, Michael
- Subjects
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DEPOLYMERIZATION , *MACROMOLECULES , *MOLECULAR physics , *MOLECULAR calculations & mathematical techniques , *MOLECULAR dynamics - Abstract
Molecular dynamics simulations of a coarse-grained bead-spring model have been used to study the effects of molecular crowding on the accumulation of tension in the backbone of bottle-brush polymers tethered to a flat substrate. The number of bottle-brushes per unit surface area, Σ, as well as the lengths of the bottle-brush backbones Nbb (50 ≤ Nbb ≤ 200) and side chains Nsc (50 ≤ Nsc ≤ 200) were varied to determine how the dimensions and degree of crowding of bottle-brushes give rise to bond tension amplification along the backbone, especially near the substrate. From these simulations, we have identified three separate regimes of tension. For low Σ, the tension is due solely to intramolecular interactions and is dominated by the side chain repulsion that governs the lateral brush dimensions. With increasing Σ, the interactions between bottle-brush polymers induce compression of the side chains, transmitting increasing tension to the backbone. For large Σ, intermolecular side chain repulsion increases, forcing side chain extension and reorientation in the direction normal to the surface and transmitting considerable tension to the backbone. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
6. Spontaneous and Specific Activation of Chemical Bonds in Macromolecular Fluids.
- Author
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Park, Insun, Shirvanyants, David, Nese, Alper, F, Matyjaszewski, Krzysztof, Rubinstein, Michael, and Sheiko, Sergei S.
- Subjects
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CHEMICAL bonds , *MACROMOLECULES , *QUANTUM chemistry , *FLUID mechanics , *THIN films - Abstract
Mechanical activation of chemical bonds typically involves the application of external forces, which implies a broad distribution of bond tensions. We demonstrate that controlling the flow profile of a macromolecular fluid generates and delineates mechanical force concentration, enabling a hierarchical activation of chemical bonds on different length scales from the macroscopic to the molecular. Bond tension is spontaneously generated within brushlike macromolecules as they spread on a solid substrate. The molecular architecture creates an uneven distribution of tension in the covalent bonds, leading to spatially controlled bond scission. By controlling the flow rate and the gradient of the film pressure, one can sever the flowing macromolecules with high precision. Specific chemical bonds are activated within distinct macromolecules located in a defined area of a thin film. Furthermore, the flow-controlled loading rate enables quantitative analysis of the bond activation parameters. [ABSTRACT FROM AUTHOR]
- Published
- 2010
- Full Text
- View/download PDF
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