Earlier this year, our co-founders @philsantoro and David Kolodny sat down with the @nasdaqcenter to discuss #entrepreneurship, building businesses by solving real problems, and finding inspiration when faced with challenges. https://t.co/BSphcpCSHX
This was a super intriguing theory + experiment project, where we showed how to methodically break the physical symmetry of a system in order to stabilize symmetric behavior (dynamics) of the system - demonstrated with surface waves of a fluid and arrays of coupled pendula
Just out: an approach to mitigate instabilities in complex systems. It exploits heterogeneity to prevent the excitation of undesirable modes.
"Heterogeneity-stabilized homogeneous states in driven media" by Nicolaou, Case, van der Wee, Driscoll & Motter: https://t.co/wTgkXmAQpB
@ProfArmani Highlight if you led or established a team/collaboration. Include any side projects (and links to them). Try to match relevant experience with the responsibilities in the job post — candidates get reviewed so fast, it needs to be clear there is a fit.
I’m just getting started @wilburlabs (2 weeks in!) but it’s incredible to jump in and see the success that has been built after only 5 years. Amazing people — I’m excited to be part of the next 5!
Finished up a sound redesign for a Ghostrunner cinematic trailer I've been working on. Lots of stuff outside my wheelhouse on this one so I'm pretty happy with it. https://t.co/mGaKo2zNbb
Our Science Advances paper “Spontaneous Oscillations and Negative-Conductance Transitions in Microfluidic Networks” is now in the arXiv: https://t.co/XvcQhKYsfd
It is all about networks designed to exhibit nonlinear behaviors that enable new built-in flow control capabilities.
Our Nature paper Braess’s Paradox and Programmable Behaviour in Microfluidic Networks (w/ @danielJ_case et al.) now available on the arXiv: https://t.co/4rIAxg4LEw
It shows how to harness nonlinearity to control internal network flows solely by manipulating the input pressure.
We show some really surprising behavior in fluid flow through a microfluidic network. Increasing the driving pressure can cause the flow rate to decrease, and the flow rate oscillates even when the driving pressure is held constant!
Newly published research with @adilson_motter is out! This was a really interesting project at the intersection of low-dimensional dynamical systems, #fluiddynamics, and #networks.
https://t.co/iBKh8j2tZK
My husband has been working from home for 6 weeks. I've learned that he basically gets paid to be in meetings. Speak in meetings, meet with other people about their last meeting, and have meetings to plan for the next meeting. 😬🥱😧
@kuriharan The increase in storage units surprised me. One explanation I found was that people are making room in their homes for offices and exercise equipment.
Happening tomorrow! There'll be a virtual fashion show and conversation with Elizabeth Cline. Plus! I'll share a little about why conscious fashion matters from a faith-based perspective.