Nisha Shukla scite author profile

The atom transfer radical polymerization (ATRP) of styrene and acrylates from silicon wafers modified with an initiator layer composed of 2-bromoisobutyrate fragments is described. In the presence of the proper ratio of activating and deactivating transition-metal species, controlled radical polymerizations of styrene were observed such that the thickness of the layer consisting of chains grown from the surface increased linearly with the molecular weight of chains polymerized in solution in identical, yet separate, experiments. The layer thickness increased linearly with reaction time for ATRP of styrene and methyl acrylate due to both the extremely low initiator concentration relative to monomer and the low monomer conversion. Further evidence for control was observed by the polymerization of blocks of either methyl or tert-butyl acrylate from the polystyrene layer. Modification of the hydrophilicity of the surface layer was achieved by hydrolysis of the poly(styrene-b-tert-butyl acrylate) to poly(styrene-b-acrylic acid) and confirmed by decrease in water contact angle from 86° to 18°. The mechanistic aspects of ATRP in the polymerization process were confirmed by the growth of very thick polystyrene films in the presence of a pure copper(I) complex. Since no deactivator was present, the metal complex served only to facilitate initiation by a redox process. Attempts to extend chain with methyl acrylate under controlled conditions were unsuccessful in those films. The simulation of polymerization of surface layers suggests broader molecular weight and chain end distributions, confirming XPS results on the progressive decrease of Br absorption intensity.

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FTIR study of surfactant bonding to FePt nanoparticles

Shukla¹,

Liu²,

Jones³

et al. 2003

Journal of Magnetism and Magnetic Materials

260

175

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Enantioselective Separation on Chiral Au Nanoparticles

2010

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The surfaces of chemically synthesized Au nanoparticles have been modified with d- or l-cysteine to render them chiral and enantioselective for adsorption of chiral molecules. Their enantioselective interaction with chiral compounds has been probed by optical rotation measurements during exposure to enantiomerically pure and racemic propylene oxide. The ability of optical rotation to detect enantiospecific adsorption arises from the fact that the specific rotation of polarized light by (R)- and (S)-propylene oxide is enhanced by interaction with Au nanoparticles. This effect is related to previous observations of enhanced circular dichroism by Au nanoparticles modified by chiral adsorbates. More importantly, chiral Au nanoparticles modified with either d- or l-cysteine selectively adsorb one enantiomer of propylene oxide from a solution of racemic propylene oxide, thus leaving an enantiomeric excess in the solution phase. Au nanoparticles modified with l-cysteine (d-cysteine) selectively adsorb the (R)-propylene oxide ((S)-propylene oxide). A simple model has been developed that allows extraction of the enantiospecific equilibrium constants for (R)- and (S)-propylene oxide adsorption on the chiral Au nanoparticles.

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Nisha Shukla

Polymers at Interfaces: Using Atom Transfer Radical Polymerization in the Controlled Growth of Homopolymers and Block Copolymers from Silicon Surfaces in the Absence of Untethered Sacrificial Initiator

FTIR study of surfactant bonding to FePt nanoparticles

Enantioselective Separation on Chiral Au Nanoparticles

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