Publications

Proposed for publication in Journal of Physical Chemistry C.

Grest, Gary S.

Abstract not provided.

Bolintineanu, Dan S.; Grest, Gary S.; Lane, James M.

Abstract not provided.

Lane, James M.; Grest, Gary S.; Mattsson, Thomas M.

Abstract not provided.

Boyle, Timothy J.; Bell, Nelson S.; Martin, Kathleen M.; Kaehr, Bryan J.; Brinker, C.J.; Washburn, Cody M.; Brumbach, Michael T.; Alam, Todd M.; Lambert, Timothy N.; Lane, James M.; Grest, Gary S.; Pratt, Sarah H.; Apblett, Christopher A.; White II, Gregory V.

Abstract not provided.

Lane, James M.; Grest, Gary S.; Mattsson, Thomas M.

Abstract not provided.

Cheng, Shengfeng C.; Stevens, Mark J.; Grest, Gary S.

Abstract not provided.

Lane, James M.; Grest, Gary S.; Mattsson, Thomas M.

Abstract not provided.

Cheng, Shengfeng C.; Grest, Gary S.

Abstract not provided.

Grest, Gary S.

Abstract not provided.

Journal of Chemical Physics

Cheng, Shengfeng C.; Grest, Gary S.

Abstract not provided.

Cheng, Shengfeng C.; Grest, Gary S.

Abstract not provided.

Langmuir

Chandross, Michael; Grest, Gary S.

We present the results of large-scale molecular dynamics simulations of two different nanolithographic processes, step-flash imprint lithography (SFIL), and hot embossing. We insert rigid stamps into an entangled bead-spring polymer melt above the glass transition temperature. After equilibration, the polymer is then hardened in one of two ways, depending on the specific process to be modeled. For SFIL, we cross-link the polymer chains by introducing bonds between neighboring beads. To model hot embossing, we instead cool the melt to below the glass transition temperature. We then study the ability of these methods to retain features by removing the stamps, both with a zero-stress removal process in which stamp atoms are instantaneously deleted from the system as well as a more physical process in which the stamp is pulled from the hardened polymer at fixed velocity. We find that it is necessary to coat the stamp with an antifriction coating to achieve clean removal of the stamp. We further find that a high density of cross-links is necessary for good feature retention in the SFIL process. The hot embossing process results in good feature retention at all length scales studied as long as coated, low surface energy stamps are used. © 2011 American Chemical Society.

Proposed for publication in Soft Matter.

Lane, James M.; Grest, Gary S.

Abstract not provided.

Physical Review B

Root, Seth R.; Haill, Thomas A.; Lane, James M.; Thompson, Aidan P.; Grest, Gary S.; Mattsson, Thomas M.

Abstract not provided.

Schunk, Randy; Grest, Gary S.; Chandross, M.; Reedy, Earl D.; Cox, James C.; Fan, Hongyou F.

Large-scale, high-throughput production of nano-structured materials (i.e. nanomanufacturing) is a strategic area in manufacturing, with markets projected to exceed $1T by 2015. Nanomanufacturing is still in its infancy; process/product developments are costly and only touch on potential opportunities enabled by growing nanoscience discoveries. The greatest promise for high-volume manufacturing lies in age-old coating and imprinting operations. For materials with tailored nm-scale structure, imprinting/embossing must be achieved at high speeds (roll-to-roll) and/or over large areas (batch operation) with feature sizes less than 100 nm. Dispersion coatings with nanoparticles can also tailor structure through self- or directed-assembly. Layering films structured with these processes have tremendous potential for efficient manufacturing of microelectronics, photovoltaics and other topical nano-structured devices. This project is designed to perform the requisite R and D to bring Sandia's technology base in computational mechanics to bear on this scale-up problem. Project focus is enforced by addressing a promising imprinting process currently being commercialized.

Lechman, Jeremy B.; Plimpton, Steven J.; Grest, Gary S.

Abstract not provided.

Lane, James M.; Grest, Gary S.; Thompson, Aidan P.; Desjarlais, Michael P.; Mattsson, Thomas M.

Abstract not provided.

Journal of Chemical Physics

Maskey, Sabina; Pierce, Flint; Perahia, Dvora; Grest, Gary S.

The conformation of single molecules of dialkyl poly para phenylene ethynylenes (PPEs), electro-active polymers, is studied in solutions using molecular dynamics simulations. The conformation of conjugated polymers affects their electro-optical properties and therefore is critical to their current and potential uses, though only limited theoretical knowledge is available regarding the factors that control their configuration. The present study investigates the affects of molecular parameters including molecular weight of the polymer and chemical structure of the side chains of PPEs in different solvents on the conformation of the polymers. The PPEs are modeled atomistically where the solvents are modeled both implicitly and explicitly. The study finds that PPEs assume extended configuration which is affected by the length of the polymer backbone and the nature and length of substituting side chains. While the polymer remains extended, local dynamics is retained and no long range correlations are observed within the backbone. The results are compared with scattering experiments. © 2011 American Institute of Physics.

Journal of Chemical Physics

Cheng, Shengfeng C.; Lechman, Jeremy B.; Plimpton, Steven J.; Grest, Gary S.

Abstract not provided.

Journal of Chemical Physics

Grest, Gary S.

Abstract not provided.

Cheng, Shengfeng C.; Lechman, Jeremy B.; Plimpton, Steven J.; Grest, Gary S.

Abstract not provided.

Journal of Chemical Physics

Grest, Gary S.

Abstract not provided.

Journal of Chemical Physics

Grest, Gary S.

Abstract not provided.

Macromolecules

Pierce, Flint P.; Grest, Gary S.

Abstract not provided.

Grest, Gary S.; Cheng, Shengfeng C.; Lechman, Jeremy B.; Plimpton, Steven J.

The most feasible way to disperse particles in a bulk material or control their packing at a substrate is through fluidization in a carrier that can be processed with well-known techniques such as spin, drip and spray coating, fiber drawing, and casting. The next stage in the processing is often solidification involving drying by solvent evaporation. While there has been significant progress in the past few years in developing discrete element numerical methods to model dense nanoparticle dispersion/suspension rheology which properly treat the hydrodynamic interactions of the solvent, these methods cannot at present account for the volume reduction of the suspension due to solvent evaporation. As part of LDRD project FY-101285 we have developed and implemented methods in the current suite of discrete element methods to remove solvent particles and volume, and hence solvent mass from the liquid/vapor interface of a suspension to account for volume reduction (solvent drying) effects. To validate the methods large scale molecular dynamics simulations have been carried out to follow the evaporation process at the microscopic scale.