Active and Passive Motion in Complex pH‐Fields

Möller, Nadir; Seiffert, Sebastian; Palberg, Thomas; Niu, Ran

doi:10.1002/cnma.202100201

Cited by 7 publications

(5 citation statements)

References 52 publications

(81 reference statements)

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“…Guided motion of the pen can further be realized by mechanical guiding, [ 47 ] optical [ 48 ] or magnetic forces, [ 49 ] and chemical fields. [ 50 ] Exploiting steering by chemical gradients would allow visualizing faint chemical traces left by other objects. Additionally, steering pH sources with optical tweezers in 3D buoyant ink dispersions would open access to freely suspended 3D patterns of arbitrary shape.…”

Section: Discussionmentioning

confidence: 99%

Writing Into Water

Möller,

Hecht,

Niu

et al. 2023

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Writing is an ancient communication technique dating back at least 30 000 years. While even sophisticated contemporary writing techniques hinge on solid surfaces for engraving or the deposition of ink, writing within a liquid medium requires a fundamentally different approach. The study here demonstrates the writing of lines, letters, and complex patterns in water by assembling lines of colloidal particles. Unlike established techniques for underwater writing on solid substrates, these lines are fully reconfigurable and do not require any fixation onto the substrate. Exploiting gravity, an ion‐exchange bead (pen) is rolled across a layer of sedimented colloidal particles (ink). The pen evokes a hydrodynamic flow collecting ink‐particles into a durable, high‐contrast line along its trajectory. Deliberate substrate‐tilting sequences facilitate pen‐steering and thus drawing and writing. The experiments are complemented with a minimal model that quantitatively predicts the observed parameter dependence for writing in fluids and highlights the generic character of writing by line‐assembly. Overall, the approach opens a versatile route for writing, drawing, and patterning fluids—even at the micro‐scale.

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Section: Discussionmentioning

confidence: 99%

Writing Into Water

Möller,

Hecht,

Niu

et al. 2023

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“…In the early approaches, the solute concentration gradients were generated globally by utilizing a rather bold micro uidic setup, where an analyte channel is connected from opposite sides to solute and solvent reservoirs, generating the ow by external pumping and uid mixing. [16][17][18][19] There are only very few strategies for locally generating DO ow, involving small catalytic objects such as ion exchange resin (IEX), [20][21][22][23][24] ion-exchanger Na on, [25] titanium dioxide colloids, [26][27][28][29][30] or natural enzymes. [31,32] Recently we have devised a method how to induce concentration gradients to adjust the direction of DO ow and its strength on demand in a closed system.…”

Section: Introductionmentioning

confidence: 99%

Manipulation of artificial and living small objects by light driven diffusioosmotic flow

Muraveva,

Lomadze,

Gordievskaya

et al. 2024

Preprint

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Here we report on light-triggered generation of local flow utilizing a bio-compatible non-ionic photo-active surfactant. The mechanism is based on diffusioosmotic phenomenon where the gradient of relative concentration with respect to different chemical species near a surface leads to an osmotic pressure gradient driving liquid flow along the surface. The application of a photo-responsive surfactant allows for easy and reversible changes in concentration gradient by positioning a light source at the desired place. Along with the so-inscribed concentration gradient one can control the direction and strength of the flow even in a closed system. The phenomenology of light-driven diffusioosmotic flow (LDDO) can be used in a rather flexible way: colloids can be gathered or dispersed and bio-compatibility extends the range of colloid types also to living microorganisms such as soil bacterium Pseudomonas putida. We show that DO flow can be considered a versatile method to set hydrodynamic conditions along the sample for investigating the motility of living cells. Further advantages of employing LDDO are the flexibility of flow generation in a reversible way and with spatiotemporal control, without the need to either change the channel geometry by loading a different device, or the periphery of pumps and connectors.

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“…[ 8 ] More recently, active colloids have been placed in increasingly complex environments, often with the intention of creating smart material structures that can be controlled via the active components. The complexity is increased using either passive particles, [ 9,10 ] introducing environments that are characterized by viscosity, [ 11 ] or chemical equilibria, [ 12 ] and by introducing new capabilities like information processing. [ 13,14 ] A plethora of different types of collective dynamics in such phoretic active colloids has been theoretically predicted [ 15–21 ] and experimentally observed.…”

Section: Introductionmentioning

confidence: 99%

Pair Interaction between Two Catalytically Active Colloids

Sharan

Daddi-Moussa-Ider

Agudo-Canalejo

et al. 2023

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Due to the intrinsically complex non‐equilibrium behavior of the constituents of active matter systems, a comprehensive understanding of their collective properties is a challenge that requires systematic bottom–up characterization of the individual components and their interactions. For self‐propelled particles, intrinsic complexity stems from the fact that the polar nature of the colloids necessitates that the interactions depend on positions and orientations of the particles, leading to a 2d − 1 dimensional configuration space for each particle, in d dimensions. Moreover, the interactions between such non‐equilibrium colloids are generically non‐reciprocal, which makes the characterization even more complex. Therefore, derivation of generic rules that enable us to predict the outcomes of individual encounters as well as the ensuing collective behavior will be an important step forward. While significant advances have been made on the theoretical front, such systematic experimental characterizations using simple artificial systems with measurable parameters are scarce. Here, two different contrasting types of colloidal microswimmers are studied, which move in opposite directions and show distinctly different interactions. To facilitate the extraction of parameters, an experimental platform is introduced in which these parameters are confined on a 1D track. Furthermore, a theoretical model for interparticle interactions near a substrate is developed, including both phoretic and hydrodynamic effects, which reproduces their behavior. For subsequent validation, the degrees of freedom are increased to 2D motion and resulting trajectories are predicted, finding remarkable agreement. These results may prove useful in characterizing the overall alignment behavior of interacting self‐propelling active swimmer and may find direct applications in guiding the design of active‐matter systems involving phoretic and hydrodynamic interactions.

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Active and Passive Motion in Complex pH‐Fields

Cited by 7 publications

References 52 publications

Writing Into Water

Writing Into Water

Manipulation of artificial and living small objects by light driven diffusioosmotic flow

Pair Interaction between Two Catalytically Active Colloids

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