Fluctuating hydrodynamics and the Rayleigh–Plateau instability

Bryn, Barker,; Bell, John B.; Garcia, Alejandro L.

doi:10.1073/pnas.2306088120

Cited by 6 publications

(2 citation statements)

References 42 publications

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“…3E ), and nozzle size (e.g., 23, 25, 27, and 32 gauge). To avoid unfavorable printing issues (e.g., disconnected droplets or bead-on-string patterns on a substrate) caused by Rayleigh instability ( 36 ), we identified the optimal range of printing conditions, including printing speed and extrusion pressure ( Fig. 3F and fig.…”

Section: Resultsmentioning

confidence: 99%

Body-temperature softening electronic ink for additive manufacturing of transformative bioelectronics via direct writing

Kwon,

Lee,

Kim

et al. 2024

Sci. Adv.

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Mechanically transformative electronic systems (TESs) built using gallium have emerged as an innovative class of electronics due to their ability to switch between rigid and flexible states, thus expanding the versatility of electronics. However, the challenges posed by gallium’s high surface tension and low viscosity have substantially hindered manufacturability, limiting high-resolution patterning of TESs. To address this challenge, we introduce a stiffness-tunable gallium-copper composite ink capable of direct ink write printing of intricate TES circuits, offering high-resolution (~50 micrometers) patterning, high conductivity, and bidirectional soft-rigid convertibility. These features enable transformative bioelectronics with design complexity akin to traditional printed circuit boards. These TESs maintain rigidity at room temperature for easy handling but soften and conform to curvilinear tissue surfaces at body temperature, adapting to dynamic tissue deformations. The proposed ink with direct ink write printing makes TES manufacturing simple and versatile, opening possibilities in wearables, implantables, consumer electronics, and robotics.

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Section: Resultsmentioning

confidence: 99%

Body-temperature softening electronic ink for additive manufacturing of transformative bioelectronics via direct writing

Kwon,

Lee,

Kim

et al. 2024

Sci. Adv.

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“…In particular, we develop a protein-interaction term to be coupled with a diffuse interface, Ginzburg–Landau type of free energy which reproduces the results of classical elasticity membrane models 46 , 47 —namely the Canham–Helfrich Hamiltonian 48 , 49 — and overcomes the associated limitations by accounting for topology-related effects across membrane severing 50 . Analogous approaches were recently proved effective in thoroughly reproducing mesoscale phenomena like, e.g., boiling 51 , water cavitation 52 , 53 , vapor bubble nucleation 54 , 55 , Rayleigh-Plateau instability 56 , crystal growth 57 , and dielectrics breakdown 58 . Figure 1 depicts the outline and general idea of this article.…”

Section: Introductionmentioning

confidence: 99%

Mesoscopic elasticity controls dynamin-driven fission of lipid tubules

Bussoletti,

Gallo,

Bottacchiari

et al. 2024

Sci Rep

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Mesoscale physics bridges the gap between the microscopic degrees of freedom of a system and its large-scale continuous behavior and highlights the role of a few key quantities in complex and multiscale phenomena, like dynamin-driven fission of lipid membranes. The dynamin protein wraps the neck formed during clathrin-mediated endocytosis, for instance, and constricts it until severing occurs. Although ubiquitous and fundamental for life, the cooperation between the GTP-consuming conformational changes within the protein and the full-scale response of the underlying lipid substrate is yet to be unraveled. In this work, we build an effective mesoscopic model from constriction to fission of lipid tubules based on continuum membrane elasticity and implicitly accounting for ratchet-like power strokes of dynamins. Localization of the fission event, the overall geometry, and the energy expenditure we predict comply with the major experimental findings. This bolsters the idea that a continuous picture emerges soon enough to relate dynamin polymerization length and membrane rigidity and tension with the optimal pathway to fission. We therefore suggest that dynamins found in in vivo processes may optimize their structure accordingly. Ultimately, we shed light on real-time conductance measurements available in literature and predict the fission time dependency on elastic parameters.

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A Personal Journey in Nanoscience via Developing and Applying Liquid Phase TEM

Zheng

2024

Israel Journal of Chemistry

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Liquid phase TEM has attracted widespread attention in recent years as a groundbreaking tool to address various fundamental problems in nanoscience. It has provided the opportunity to reveal many unseen dynamic phenomena of nanoscale materials in solution processes by direct imaging through liquids with high spatial and temporal resolution. After my earlier work on real‐time imaging of the nucleation, growth, and dynamic motion of nanoparticles in liquids by developing high‐resolution liquid phase transmission electron microscopy (TEM) down to the sub‐nanometer level, I established my own research group at Lawrence Berkeley National Lab in 2010. My group focuses on developing and applying liquid phase TEM to investigate complex systems and reactions. We have studied a set of scientific problems centered on understanding how atomic level heterogeneity and fluctuations at solid‐liquid interfaces impact nanoscale materials transformations using advanced liquid phase TEM. This article describes my personal journey in nanoscience, highlighting the main discoveries of my research group using liquid phase TEM as a unique tool. Some perspectives on the impacts of liquid phase TEM and the future opportunities in nanoscience and nanotechnology enabled by liquid phase TEM are also included.

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Fluctuating hydrodynamics and the Rayleigh–Plateau instability

Cited by 6 publications

References 42 publications

Body-temperature softening electronic ink for additive manufacturing of transformative bioelectronics via direct writing

Body-temperature softening electronic ink for additive manufacturing of transformative bioelectronics via direct writing

Mesoscopic elasticity controls dynamin-driven fission of lipid tubules

A Personal Journey in Nanoscience via Developing and Applying Liquid Phase TEM

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