transient mechanics /lab/vernerey/ en Rate-Dependent Damage Mechanics of Polymer Networks with Reversible Bonds /lab/vernerey/2023/03/11/rate-dependent-damage-mechanics-polymer-networks-reversible-bonds <span>Rate-Dependent Damage Mechanics of Polymer Networks with Reversible Bonds</span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2023-03-11T13:35:25-07:00" title="Saturday, March 11, 2023 - 13:35">Sat, 03/11/2023 - 13:35</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/lab/vernerey/sites/default/files/styles/focal_image_wide/public/article-thumbnail/abstract_image.jpeg?h=5222cdfe&amp;itok=LEfk2Q42" width="1200" height="600" alt="Rate dependent damage"> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/lab/vernerey/taxonomy/term/67"> damage </a> <a href="/lab/vernerey/taxonomy/term/68"> polymer networks </a> <a href="/lab/vernerey/taxonomy/term/60"> self-healing </a> <a href="/lab/vernerey/taxonomy/term/59"> transient mechanics </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/lab/vernerey/taxonomy/term/63" hreflang="en">research article</a> </div> <a href="/lab/vernerey/samuel-lamont">Samuel Lamont</a> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> <div> <div class="imageMediaStyle large_image_style"> <img loading="lazy" src="/lab/vernerey/sites/default/files/styles/large_image_style/public/article-image/images_large_ma1c01943_0002.jpeg?itok=atVcsYrZ" width="1500" height="513" alt="chain rupture vs chain detachment"> </div> </div> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> <div><p><strong>Brief Description</strong></p> <p>In this work, we develop a statistical theory of damage for transient networks that can directly bridge the molecular mechanisms and macroscopic response.&nbsp;The final model being able to capture the evolution of rate-dependent and anisotropic damage in transient networks.</p> <hr> <p><strong>Abstract</strong></p> <p>Dynamic polymer networks utilize weak bonding interactions to dissipate the stored energy and provide a source of self-healing for the material. Due to this, tracking the progression of damage in these networks is poorly understood as it becomes necessary to distinguish between reversible and irreversible bond detachment (by kinetic bond exchange or chain rupture, respectively). In this work, we present a statistical formulation based on the transient network theory to track the chain conformation space of a dynamic polymer network whose chains rupture after being pulled past a critical stretch. We explain the predictions of this model by the observable material timescales of relaxation and self-healing, which are related to the kinetic rates of attachment and detachment. We demonstrate our model to match experimental data of cyclic loading and self-healing experiments, providing physical interpretation for these complex behaviors in dynamic polymer networks.</p> <p><strong>Figures</strong></p> <p><em>Top:</em> Distinction between chain rupture and chain detachment in a transient network. In this network, a chain can be found in three distinct states: attached, detached, and ruptured. The ruptured chains are unable to create new network connections and are at the origin of irreversible damage.</p> <p><em>Bottom:</em> Cyclic loading experiment performed at a constant strain rate λ̇. (a) High Weissenberg loading. Energy dissipation is primarily a result of chain rupture. (b) Low Weissenberg loading. Energy dissipation is primarily due to reversible bond kinetics. Contour plots indicate the distribution ϕ at the respective stage of loading.</p> <hr> <p><strong>Citation</strong></p> <p>Lamont, S. C.; Mulderrig, J.; Bouklas, N.; Vernerey, F. J. Rate-Dependent Damage Mechanics of Polymer Networks with Reversible Bonds. <i>Macromolecules</i> 2021, <i>54</i> (23), 10801–10813. <a href="https://doi.org/10.1021/acs.macromol.1c01943" rel="nofollow">https://doi.org/10.1021/acs.macromol.1c01943</a>.</p></div> </div> </div> </div> </div> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Sat, 11 Mar 2023 20:35:25 +0000 Anonymous 427 at /lab/vernerey Computational exploration of treadmilling and protrusion growth observed in fire ant rafts /lab/vernerey/2023/03/11/computational-exploration-treadmilling-and-protrusion-growth-observed-fire-ant-rafts <span>Computational exploration of treadmilling and protrusion growth observed in fire ant rafts</span> <span><span>Anonymous (not verified)</span></span> <span><time datetime="2023-03-11T12:53:19-07:00" title="Saturday, March 11, 2023 - 12:53">Sat, 03/11/2023 - 12:53</time> </span> <div> <div class="imageMediaStyle focal_image_wide"> <img loading="lazy" src="/lab/vernerey/sites/default/files/styles/focal_image_wide/public/article-thumbnail/antrafttreadmill.png?h=6668681c&amp;itok=9erbmIWH" width="1200" height="600" alt="Ant Raft Treadmilling"> </div> </div> <div role="contentinfo" class="container ucb-article-categories" itemprop="about"> <span class="visually-hidden">Categories:</span> <div class="ucb-article-category-icon" aria-hidden="true"> <i class="fa-solid fa-folder-open"></i> </div> <a href="/lab/vernerey/taxonomy/term/58"> active networks </a> <a href="/lab/vernerey/taxonomy/term/65"> self-assembly </a> <a href="/lab/vernerey/taxonomy/term/59"> transient mechanics </a> </div> <div role="contentinfo" class="container ucb-article-tags" itemprop="keywords"> <span class="visually-hidden">Tags:</span> <div class="ucb-article-tag-icon" aria-hidden="true"> <i class="fa-solid fa-tags"></i> </div> <a href="/lab/vernerey/taxonomy/term/63" hreflang="en">research article</a> </div> <span>Robert Wagner</span> <div class="ucb-article-content ucb-striped-content"> <div class="container"> <div class="paragraph paragraph--type--article-content paragraph--view-mode--default"> <div class="ucb-article-content-media ucb-article-content-media-above"> <div> <div class="paragraph paragraph--type--media paragraph--view-mode--default"> <div> <div class="imageMediaStyle large_image_style"> <img loading="lazy" src="/lab/vernerey/sites/default/files/styles/large_image_style/public/article-image/antrafttreadmill.png?itok=HH42MtDk" width="1500" height="737" alt="Ant Raft Treadmilling"> </div> </div> </div> </div> </div> <div class="ucb-article-text d-flex align-items-center" itemprop="articleBody"> <div><p><strong>Brief Description</strong></p> <p>Cooperative behavior in organisms often permits groups to achieve collective tasks that are unattainable to individuals. Such is the case of fire ant workers that aggregate together to create buoyant rafts that unify their colonies and ensure survival during floods. Under certain conditions, these rafts undergo a process called treadmilling that allows them to morph perpetually over the span of several hours. This morphogenesis includes the growth of tether-like protrusions that colonies can use as land-bridges to escape water. Employing a discrete, agent-based model, we here demonstrate how the local interactions between ants in these systems may be sufficient to cause stochastic and spontaneous protrusion emergence in the absence of external gradients, long-range interactions, or targeted stimuli.</p> <hr> <p><strong>Abstract</strong></p> <p>Collective living systems regularly achieve cooperative emergent functions that individual organisms could not accomplish alone. The rafts of&nbsp;fire ants&nbsp;(Solenopsis invicta) are often studied in this context for their ability to create aggregated structures comprised entirely of their own bodies, including tether-like protrusions that facilitate exploration of and escape from flooded environments. While similar protrusions are observed in cytoskeletons and cellular aggregates, they are generally dependent on morphogens or external gradients leaving the isolated role of local interactions poorly understood. Here we demonstrate through an ant-inspired, agent-based numerical model how protrusions in ant rafts may emerge spontaneously due to local interactions. The model is comprised of a condensed structural network of agents that represents the monolayer of interconnected worker ants, which floats on the water and gives ant rafts their form. Experimentally, this layer perpetually contracts, which we capture through the pairwise contraction of all neighboring structural agents at a strain rate of d. On top of the structural layer, we model a dispersed, on-lattice layer of motile agents that represents free ants, which walk on top of the floating network. Experimentally, these self-propelled free ants walk with some mean persistence length and speed that we capture through an ant-inspired phenomenological model. Local interactions occur between neighboring free ants within some radius of detection, R, and the persistence length of freely active agents is tuned through a noise parameter, [eta] as introduced by the Vicsek model. Both R and [eta] where fixed to match the experimental trajectories of free ants. Treadmilling of the raft occurs as agents transition between the structural and free layers in accordance with experimental observations. Ultimately, we demonstrate how phases of exploratory protrusion growth may be induced by increased ant activity as characterized by a dimensionless parameter, A. These results provide an example in which functional&nbsp;morphogenesis&nbsp;of a living system may emerge purely from local interactions at the constituent length scale, thereby providing a source of inspiration for the development of decentralized, autonomous active matter and swarm robotics.</p> <p><strong>Figures</strong></p> <p><em>Top:</em>&nbsp;Ant Raft Treadmilling.</p> <p><em>Bottom:</em> (A-G) Agent Based Model Schematic.</p> <hr> <p><strong>Citation</strong></p> <p>Wagner, R. J.; Vernerey, F. J. Computational Exploration of Treadmilling and Protrusion Growth Observed in Fire Ant Rafts. <i>PLoS Comput Biol</i> 2022, <i>18</i> (2), e1009869. <a href="https://doi.org/10.1371/journal.pcbi.1009869" rel="nofollow">https://doi.org/10.1371/journal.pcbi.1009869</a>.</p></div> </div> </div> </div> </div> <h2> <div class="paragraph paragraph--type--ucb-related-articles-block paragraph--view-mode--default"> <div>Off</div> </div> </h2> <div>Traditional</div> <div>0</div> <div>On</div> <div>White</div> Sat, 11 Mar 2023 19:53:19 +0000 Anonymous 424 at /lab/vernerey