Your search keyword '"Michael E. Mackay"' showing total 4 results

1. Breakdown of the Continuum Stokes−Einstein Relation for Nanoparticle Diffusion

Author

Michael E. Mackay, Subashini Asokan, Suresh Narayanan, Anish Tuteja, and Michael S. Wong

Subjects

Polymeric liquid, Materials science, Cadmium selenide, Continuum (measurement), business.industry, Mechanical Engineering, Nanoparticle, Bioengineering, General Chemistry, Quantum entanglement, Condensed Matter Physics, Molecular physics, Physics::Fluid Dynamics, chemistry.chemical_compound, Optics, chemistry, Drag, Stokes einstein, General Materials Science, Basso continuo, business

Abstract

Cadmium selenide nanoparticles are found to diffuse approximately 200 times faster in a polymeric liquid than predicted by the Stokes-Einstein relation. This remarkable behavior is hypothesized to be due to the nanoparticles being smaller than the entanglement mesh to create a frictional drag that does not follow continuum expectations, in line with a theoretical calculation presented before. This is one of the first demonstrations of X-ray photo correlation spectroscopy applied to polymeric liquids, which we use to explain the simultaneous 60% viscosity reduction of the mixture through a proposed constraint release mechanism.

Published

2007

2. Self-assembled multilayers of nanocomponents

Author

Michael E. Mackay, Brooke A. Van Horn, Phillip M. Duxbury, Craig J. Hawker, Michael S. Wong, Alicia Pastor, Subashini Asokan, and R. S. Krishnan

Subjects

chemistry.chemical_classification, Spin coating, Materials science, business.industry, Mechanical Engineering, Nanoparticle, Bioengineering, Nanotechnology, General Chemistry, Dielectric, Polymer, Condensed Matter Physics, Surface energy, Optical coating, chemistry, Optoelectronics, General Materials Science, Nanometre, business, Layer (electronics)

Abstract

We show it is possible to assemble nanoparticle-polymer layers in a controllable manner dictated by the difference in nano-object morphology and dielectric properties. A thin (10-100 nm) layer of the two components is spin coated onto a solid substrate and the system thermally aged to activate a cross-linking process between polymer molecules. The nanoparticles segregate to the solid substrate prior to complete cross-linking if entropic forces are dominant or to the air interface if dielectric (surface energy) forces are properly tuned. Subsequent layers are then spin coated onto the layer below, and the process is repeated to create layered structures with nanometer accuracy useful for tandem solar cells, sensors, optical coatings, etc. Unlike other self-assembly techniques the layer thicknesses are dictated by the spin coating conditions and relative concentration of the two components.

Published

2007

3. Breakdown of the Continuum Stokes−Einstein Relation for Nanoparticle Diffusion.

Author

Anish Tuteja, Michael E. Mackay, Suresh Narayanan, Subashini Asokan, and Michael S. Wong

Subjects

*NANOPARTICLES, *POLYWATER, *RHEOLOGY, *SPECTRUM analysis

Abstract

Cadmium selenide nanoparticles are found to diffuse approximately 200 times faster in a polymeric liquid than predicted by the Stokes−Einstein relation. This remarkable behavior is hypothesized to be due to the nanoparticles being smaller than the entanglement mesh to create a frictional drag that does not follow continuum expectations, in line with a theoretical calculation presented before. This is one of the first demonstrations of X-ray photo correlation spectroscopy applied to polymeric liquids, which we use to explain the simultaneous 60% viscosity reduction of the mixture through a proposed constraint release mechanism. [ABSTRACT FROM AUTHOR]

Published

2007

4. Self-Assembled Multilayers of Nanocomponents.

Author

R. S. Krishnan, Michael E. Mackay, Phillip M. Duxbury, Alicia Pastor, Craig J. Hawker, Brooke Van Horn, Subashini Asokan, and Michael S. Wong

Subjects

*NANOPARTICLES, *POLYMERS, *MOLECULES, *MORPHOLOGY

Abstract

We show it is possible to assemble nanoparticle−polymer layers in a controllable manner dictated by the difference in nano-object morphology and dielectric properties. A thin (10−100 nm) layer of the two components is spin coated onto a solid substrate and the system thermally aged to activate a cross-linking process between polymer molecules. The nanoparticles segregate to the solid substrate prior to complete cross-linking if entropic forces are dominant or to the air interface if dielectric (surface energy) forces are properly tuned. Subsequent layers are then spin coated onto the layer below, and the process is repeated to create layered structures with nanometer accuracy useful for tandem solar cells, sensors, optical coatings, etc. Unlike other self-assembly techniques the layer thicknesses are dictated by the spin coating conditions and relative concentration of the two components. [ABSTRACT FROM AUTHOR]

Published

2007