More Like this

1. Carbon-free Solid Dispersion LiCoO2 Redox Couple Characterization and Electrochemical Evaluation for All Solid Dispersion Redox Flow Batteries

   https://doi.org/10.1016/j.electacta.2017.01.061  

   Qi, Zhaoxiang ; Liu, Aaron L. ; Koenig, Gary M. ( February 2017 , Electrochimica Acta)
2. Shear dispersion from near-inertial internal Poincaré waves in large lakes: Shear dispersion in stratified large lakes

   https://doi.org/10.1002/lno.10163  

   Choi, Jun M. ; Troy, Cary D. ; Hawley, Nathan ( November 2015 , Limnology and Oceanography)
3. Efficient Density-Fitted Explicitly Correlated Dispersion and Exchange Dispersion Energies

   https://doi.org/10.1021/acs.jctc.0c01158  

   Kodrycka, Monika ; Patkowski, Konrad ( March 2021 , Journal of Chemical Theory and Computation)

   null (Ed.)
4. Diffusioosmosis-driven dispersion of colloids: a Taylor dispersion analysis with experimental validation

   https://doi.org/10.1017/jfm.2022.321  

   Alessio, Benjamin M. ; Shim, Suin ; Gupta, Ankur ; Stone, Howard A. ( July 2022 , Journal of Fluid Mechanics)

   Diffusiophoresis refers to the movement of colloidal particles in the presence of a concentration gradient of a solute and enables directed motion of colloidal particles in geometries that are inaccessible, such as dead-end pores, without imposing an external field. Previous experimental reports on dead-end pore geometries show that, even in the absence of mean flow, colloidal particles moving through diffusiophoresis exhibit significant dispersion. Existing models of diffusiophoresis are not able to predict the dispersion and thus the comparison between the experiments and the models is largely qualitative. To address these quantitative differences between the experiments and models, we derive an effective one-dimensional equation, similar to a Taylor dispersion analysis, that accounts for the dispersion created by diffusioosmotic flow from the channel sidewalls. We derive the effective dispersion coefficient and validate our results by comparing them with direct numerical simulations. We also compare our model with experiments and obtain quantitative agreement for a wide range of colloidal particle sizes. Our analysis reveals two important conclusions. First, in the absence of mean flow, dispersion is driven by the flow created by diffusioosmotic wall slip such that spreading can be reduced by decreasing the channel wall diffusioosmotic mobility. Second, the model can explain the spreading of colloids in a dead-end pore for a wide range of particle sizes. We note that, while the analysis presented here focuses on a dead-end pore geometry with no mean flow, our theoretical framework is general and can be adapted to other geometries and other background flows. 

   more » « less
5. Three-dimensional intracellular transport in neuron bodies and neurites investigated by label-free dispersion-relation phase spectroscopy: Dispersion-Relation Phase Spectroscopy in 3D

   https://doi.org/10.1002/cyto.a.23081  

   Kandel, Mikhail E. ; Fernandes, Daniel ; Taylor, Alison M. ; Shakir, Haadi ; Best-Popescu, Catherine ; Popescu, Gabriel ( May 2017 , Cytometry Part A)