Engineered nanoscale structures known as artificial graphene exhibit the properties of real graphene but in a setup where it is easy to tune features such as the electronic density, lattice constant, geometry or coupling with the environment.
Galileo Galilei famously stated the principle of Galilean invariance, which links the equations of motion of closed systems as viewed in distinct inertial frames translating relative to one another at a constant velocity.
In recent years evidence has accumulated that single biological cells often move in a way that is unlike Brownian motion, a paradigmatic model of random dynamics. Instead, cells migrate faster and exhibit so-called superdiffusion. This article reports on a new method to efficiently simulate superdiffusively moving cells.
LML External Fellow Rainer Klages was awarded a research grant by the Office of Naval Research Global (USA) of US$117,000 to study how living organisms like cells, bumblebees or turtles optimize their search for food.
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