References of "Schilling, Tanja 50003011"
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See detailPercolation Revisited
Schilling, Tanja UL

Scientific Conference (2015, September)

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See detailCrystallization seen from a non-equilibrium point of view
Schilling, Tanja UL

Presentation (2015, September)

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See detailNon-universal Voronoi cell shapes in amorphous ellipsoid packs
Schaller, Fabian M; Kapfer, Sebastian C; Hilton, James E. et al

in Europhysics Letters [=EPL] (2015), 111

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See detailOn Crystallization and Percolation
Schilling, Tanja UL

Scientific Conference (2015, August)

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See detailPercolation in suspensions of polydisperse hard rods: Quasi universality and finite-size effects
Meyer, Hugues UL; Van der Schoot, Paul; Schilling, Tanja UL

in Journal of Chemical Physics (2015), 143(4), 044901

We present a study of connectivity percolation in suspensions of hard spherocylinders by means of Monte Carlo simulation and connectedness percolation theory. We focus attention on polydispersity in the ... [more ▼]

We present a study of connectivity percolation in suspensions of hard spherocylinders by means of Monte Carlo simulation and connectedness percolation theory. We focus attention on polydispersity in the length, the diameter, and the connectedness criterion, and we invoke bimodal, Gaussian, and Weibull distributions for these. The main finding from our simulations is that the percolation threshold shows quasi universal behaviour, i.e., to a good approximation, it depends only on certain cumulants of the full size and connectivity distribution. Our connectedness percolation theory hinges on a Lee-Parsons type of closure recently put forward that improves upon the often-used second virial approximation [T. Schilling, M. Miller, and P. van der Schoot, e-print arXiv:1505.07660 (2015)]. The theory predicts exact universality. Theory and simulation agree quantitatively for aspect ratios in excess of 20, if we include the connectivity range in our definition of the aspect ratio of the particles. We further discuss the mechanism of cluster growth that, remarkably, differs between systems that are polydisperse in length and in width, and exhibits non-universal aspects. [less ▲]

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See detailPercolation Revisited
Schilling, Tanja UL

Scientific Conference (2015, June)

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See detailDissipation in a crystallization process
Schilling, Tanja UL

Presentation (2015, June)

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See detailPercolation Revisited
Schilling, Tanja UL

Presentation (2015, May)

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See detailCrystallization and Percolation Revisited
Schilling, Tanja UL

Presentation (2015, April)

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See detailCrystallization seen from a non-equilibrium point of view
Schilling, Tanja UL

Presentation (2015, January)

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See detailCrystallization seen from a non-equilibrium point of view
Schilling, Tanja UL

Presentation (2015, January)

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See detailCrystallization of polyethylene: A molecular dynamics simulation study of the nucleation and growth mechanisms
Anwar, Muhammad; Schilling, Tanja UL

in Polymer (2015), 76

We have performed molecular dynamics simulations to study the mechanism of crystallization from an undercooled polyethylene (C500) melt. We observe that crystal nucleation is initiated by the alignment of ... [more ▼]

We have performed molecular dynamics simulations to study the mechanism of crystallization from an undercooled polyethylene (C500) melt. We observe that crystal nucleation is initiated by the alignment of chain segments, which is followed by straightening of the chains and densification. Growth procedes via alignment of segments, which are in the vicinity of the growth front, with the chains in the crystalline lamella. Once chains are attached, the lamella thickens by sliding of the segments along the long axis of the chain from the amorphous regions into the crystalline regions. We do not observe the formation of any folded precursors. [less ▲]

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See detailAbsolute Free Energies for Biomolecules in Implicit or Explicit Solvent
Berryman, Josh UL; Schilling, Tanja UL

in Physics Procedia (2014), 57

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See detailCrystallization in colloidal suspensions
Schilling, Tanja UL

Scientific Conference (2014, December)

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See detailCrystallization in colloidal suspensions
Schilling, Tanja UL

Presentation (2014, November)

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See detailCrystallization in colloidal suspensions
Schilling, Tanja UL

Presentation (2014, November)

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See detailCrystallization in colloidal suspensions
Schilling, Tanja UL

Presentation (2014, October)

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Peer Reviewed
See detailCrystallization in colloidal suspensions
Schilling, Tanja UL

Scientific Conference (2014, September)

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See detailCrystal growth from a supersaturated melt: Relaxation of the solid-liquid dynamic stiffness
Turci, Francesco UL; Schilling, Tanja UL

in Journal of Chemical Physics (2014), 141

We discuss the growth process of a crystalline phase out of a metastable over-compressed liquid that is brought into contact with a crystalline substrate. The process is modeled by means of molecular ... [more ▼]

We discuss the growth process of a crystalline phase out of a metastable over-compressed liquid that is brought into contact with a crystalline substrate. The process is modeled by means of molecular dynamics. The particles interact via the Lennard-Jones potential and their motion is locally thermalized by Langevin dynamics. We characterize the relaxation process of the solid-liquid interface, showing that the growth speed is maximal for liquid densities above the solid coexistence density, and that the structural properties of the interface rapidly converge to equilibrium-like properties. In particular, we show that the off-equilibrium dynamic stiffness can be extracted using capillary wave theory arguments, even if the growth front moves fast compared to the typical diffusion time of the compressed liquid, and that the dynamic stiffness converges to the equilibrium stiffness in times much shorter than the diffusion time. [less ▲]

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See detailCrystallization in polymermelts
Schilling, Tanja UL

Presentation (2014, July)

Detailed reference viewed: 29 (0 UL)