Paul A. Monderkamp scite author profile

The survival of many microorganisms, like Leptospira or Spiroplasma bacteria, can depend on their ability to navigate towards regions of favorable viscosity. While this ability, called viscotaxis, has been observed in several bacterial experiments, the underlying mechanism remains unclear. We provide a framework to study viscotaxis of biological or synthetic self-propelled swimmers in slowly varying viscosity fields and show that suitable body shapes create viscotaxis based on a systematic asymmetry of viscous forces acting on a microswimmer. Our results shed new light on viscotaxis in Spiroplasma and Leptospira and suggest that dynamic body shape changes exhibited by both types of microorganisms may have an unrecognized functionality: to prevent them from drifting to low viscosity regions where they swim poorly. The present theory classifies microswimmers regarding their ability to show viscotaxis and can be used to design synthetic viscotactic swimmers, e.g., for delivering drugs to a target region distinguished by viscosity.

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Topology of Orientational Defects in Confined Smectic Liquid Crystals

Monderkamp

Wittmann

Cortes

et al. 2021

Phys. Rev. Lett.

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Active particles using reinforcement learning to navigate in complex motility landscapes

Monderkamp

Schwarzendahl

Klatt

et al. 2022

Mach. Learn.: Sci. Technol.

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As the length scales of the smallest technology continue to advance beyond the micron scale it becomes increasingly important to equip robotic components with the means for intelligent and autonomous decision making with limited information. With the help of a tabular Q-learning algorithm, we design a model for training a microswimmer, to navigate quickly through an environment given by various diﬀerent scalar motility ﬁelds, while receiving a limited amount of local information. We compare the performances of the microswimmer, deﬁned via time of ﬁrst passage to a target, with performances of suitable reference cases. We show that the strategy obtained with our reinforcement learning model indeed represents an eﬃcient navigation strategy, that outperforms the reference cases. By confronting the swimmer with a variety of unfamiliar environments after the ﬁnalised training, we show that the obtained strategy generalises to diﬀerent classes of random ﬁelds.

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Topological fine structure of smectic grain boundaries and tetratic disclination lines within three-dimensional smectic liquid crystals

Monderkamp

Wittmann

Vrugt

et al. 2022

Phys. Chem. Chem. Phys.

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Network topology of interlocked chiral particles

Monderkamp¹,

Windisch²,

Wittmann³

et al. 2023

Preprint

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Self-assembly of chiral particles with an L-shape is explored by Monte-Carlo computer simulations in two spatial dimensions. For sufficiently high packing densities in confinement, a carpet-like texture emerges due to the interlocking of L-shaped particles, resembling a distorted smectic liquid crystalline layer pattern. From the positions of either of the two axes of the particles, two different types of layers can be extracted, which form distinct but complementary entangled networks. These coarse-grained network structures are then analyzed from a topological point of view. We propose a global charge conservation law by using an analogy to uniaxial smectics and show that the individual network topology can be steered by both confinement and particle geometry. Our topological analysis provides a general classification framework for applications to other intertwined dual networks.

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