Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Impact of Targeting Moiety Type and Protein Corona Formation on the Uptake of Fn14-Targeted Nanoparticles by Cancer Cells by Christine P. Carney (14116727)

“…Lastly, we uncovered that full monoclonal antibody-targeted NPs enter cancer cells via clathrin-mediated endocytosis and traffic through the endolysosomal pathway. …”

Polyethylene Glycol Impacts Conformation and Dynamics of Escherichia coli Prolyl-tRNA Synthetase Via Crowding and Confinement Effects by Jessica Liebau (18359653)

“…Thus, lower-molecular-weight PEG molecules impact protein dynamics and function via crowding effects, whereas larger PEGs induce confinement effects. …”

Polyethylene Glycol Impacts Conformation and Dynamics of Escherichia coli Prolyl-tRNA Synthetase Via Crowding and Confinement Effects by Jessica Liebau (18359653)

“…Thus, lower-molecular-weight PEG molecules impact protein dynamics and function via crowding effects, whereas larger PEGs induce confinement effects. …”

Gender category beliefs (GCB) as a function of participant sex and other demographic variables. by Mostafa Salari Rad (8201484)

Fig 2 - by Rabia Asghar (18840759)

A Model for MST1-mediated protection in liver fibrosis caused by <i>Schistosoma japonicum</i> infection. by Jianyang Li (461703)

The list of sequences of primers in this study. by Jianyang Li (461703)

“…Mice with macrophages-specific <i>Mst1</i> knockout (termed <i>Mst1</i>^{<i>△M/△M</i>}) mice developed exacerbated liver pathology, characterized by larger egg-induced granulomas, and increased fibrosis post infection. …”

Image1_Clinical insights into tooth extraction via torsion method: a biomechanical analysis of the tooth-periodontal ligament complex.PDF by Jiawei Xing (11838517)

Fig 1 - by Rashida Nayeem (11851764)

Fig 7 - by Rashida Nayeem (11851764)

Pathogen load in control and rough box migratory colonies. by Maggie Shanahan (17879479)

Explanation of Depolarization Block Mechanisms Using Square Pulses. A. by Christopher J. Knowlton (11450436)

“…Depolarization block is entered via a gradual decrease in spike amplitude, with a maximum firing rate of 28 Hz. …”

Bifurcation Structure of Atypical and Conventional Models. by Christopher J. Knowlton (11450436)