James Gabbard, graduate student in our lab, has received a AY19-20 MathWorks Engineering Fellowship. He has used Matlab extensively in his education and research so-far, and we’re happy to see his expertise recognized!
As part of our published paper in Soft Matter, we have released on source code that underlies our simulation algorithm on GitHub under the open-source BSD-3 clause. The code forms the basis for our simulations of non-Euclidean plates and growing thin sheets, and is easy to adapt to different problems in plate and shell elasticity, with or without growth. The code can be downloaded from https://github.com/wimvanrees/growth_SM2018 .
This summer I published an article in Science, together with Prof. William Irvine and his group at the University of Chicago, discussing our results on the dynamics of helicity in a viscous fluid. Helicity is a scalar quantity that measures the intertwining of vortex lines in a fluid domain. In ideal (inviscid) fluids, helicity is conserved – but in viscous fluids helicity can increase, decrease, or (as we showed) stay the same.
The first major contribution was an experimental break-through by the Chicago group: we introduced a new technique to measure helicity in a real fluid, water, for the special case of thin-core vortices. The total helicity for such vortices can be split into two components: the writhe, or ‘curling’ of the vortex centerline, and the twist of the vortex lines that are swirling around the centerline. The writhe can be computed just by inspecting the geometry, or shape, of the centerline, and together with the measurement of total helicity we could compute the twist by subtracting one from the other.
This provided our second major contribution: by observing the dynamics of twist and writhe separately, and using some theoretical analysis, we could show that for our helical vortex loops, the twist contribution would always be dissipated by viscosity, whereas the writhe of the centerline persists. This means the an initial helical vortex loop, with both twist and writhe, will see its twist being dissipated by viscosity and end up as a twist-free, writhing vortex that persists. In other words: helicity can be non-zero and conserved, even in a viscous fluid.
This is just the beginning: looking at fluid flows through the lens of vortex-line geometry is a promising approach to study the flow evolution. There are many questions that are still unanswered, mostly relating to the dynamics of twist in helical vortices.
You can find the full article on our publications page, or click here to download the pdf. For more insight in this topic, Prof. H. Keith Moffatt wrote an insightful perspective on our article that can be found here.
We’re launching the lab website (and lab) during November — stay tuned for more content, pictures & videos!