Nanoscaled Fractal Superstructures via Laser Patterning—A Versatile Route to Metallic Hierarchical Porous Materials

Reinhardt, Hendrik; Kroll, Moritz; Karstens, Sarah L.; Schlabach, Sabine; Hampp, Norbert; Tallarek, Ulrich

doi:10.1002/admi.202000253

Cited by 13 publications

(18 citation statements)

References 44 publications

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“…The high degree of connectivity and the complex geometry of the void space preclude a division into individual pores. We describe the void space distribution through chord length distributions (CLDs), which is an automatable method that does not rely on assumptions about the void space geometry and can in principle be applied to any porous medium [50–52] . The void space is scanned up to the solid‐void interface by chords of variable length; collecting and sorting the chords according to their length in a histogram yields the CLD.…”

Section: Resultsmentioning

confidence: 99%

Three‐Phase Reconstruction Reveals How the Microscopic Structure of the Carbon‐Binder Domain Affects Ion Transport in Lithium‐Ion Batteries

Kroll

Karstens

Cronau

et al. 2021

Batteries & Supercaps

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The morphology of the electrolyte‐filled pore space in lithium‐ion batteries is determined by the solid microstructure formed by μm‐sized active material particles and the smaller‐featured carbon binder domain (CBD). Tomographic reconstructions have largely neglected the CBD, resulting in inadequately defined pore space morphologies at odds with experimental ionic tortuosity values. We present a three‐phase reconstruction of a LiCoO2 composite cathode by focused ion‐beam scanning electron microscopy tomography. Morphological analysis proves that the reconstruction, which combines an unprecedented volume (20 μm minimum edge length) with the hitherto highest resolution (13.9×13.9×20 nm3 voxel size), represents the cathode's pore space morphology. Pore‐scale diffusion simulations show consideration of the resolved CBD as indispensable to reproduce ionic tortuosity values from electrochemical impedance spectroscopy. Our results reveal the CBD as a convoluted network that dominates the pore space morphology and limits Li+ transport through tortuous and constricted diffusion pathways.

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Section: Resultsmentioning

confidence: 99%

Three‐Phase Reconstruction Reveals How the Microscopic Structure of the Carbon‐Binder Domain Affects Ion Transport in Lithium‐Ion Batteries

Kroll

Karstens

Cronau

et al. 2021

Batteries & Supercaps

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“…Particular attention is currently dedicated to hierarchical structures consisting of different levels of structuring at micro- and nano-scales, which showed potential for modulating the attachment of living organisms, including cells. To date, hierarchical structures have been developed by micropattern fabrication followed by the growth of nano-topographical features, but these approaches required multi-step, complicated procedures and provided poor control over the resulting architectures [ 9 , 13 , 28 ].…”

Section: Resultsmentioning

confidence: 99%

“…Hierarchical structures have been fabricated by top-down, bottom-up, and hybrid approaches [ 12 , 13 , 14 ]. The top-down methods such as nanoimprint lithography, soft lithography, and capillary force lithography require additional efforts such as the application of pressure, heat, or coating the surface of the substrate with a thin adhesive layer that overwhelms the adhesion between the imprint mold and the patterned layer.…”

Section: Introductionmentioning

confidence: 99%

Laser Direct Writing via Two-Photon Polymerization of 3D Hierarchical Structures with Cells-Antiadhesive Properties

Păun

Călin

Mustăciosu

et al. 2021

IJMS

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We report the design and fabrication by laser direct writing via two photons polymerization of innovative hierarchical structures with cell-repellency capability. The structures were designed in the shape of “mushrooms”, consisting of an underside (mushroom’s leg) acting as a support structure and a top side (mushroom’s hat) decorated with micro- and nanostructures. A ripple-like pattern was created on top of the mushrooms, over length scales ranging from several µm (microstructured mushroom-like pillars, MMP) to tens of nm (nanostructured mushroom-like pillars, NMP). The MMP and NMP structures were hydrophobic, with contact angles of (127 ± 2)° and (128 ± 4)°, respectively, whereas flat polymer surfaces were hydrophilic, with a contact angle of (43 ± 1)°. The cell attachment on NMP structures was reduced by 55% as compared to the controls, whereas for the MMP, a reduction of only 21% was observed. Moreover, the MMP structures preserved the native spindle-like with phyllopodia cellular shape, whereas the cells from NMP structures showed a round shape and absence of phyllopodia. Overall, the NMP structures were more effective in impeding the cellular attachment and affected the cell shape to a greater extent than the MMP structures. The influence of the wettability on cell adhesion and shape was less important, the cellular behavior being mainly governed by structures’ topography.

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“…The self-organization of surfaces is governed through perturbation by means of temperature treatment, induced strains, and energetic beams. [17,18] The material surface undergoes phase transformation and surface atoms reorganize in various morphologies forming nanoscale or microscale features, with increased or decreased roughness, based on the surface kinetics during the treatment. In the present work, we have employed the self-organization process for nanoscale polygons on the germanium surface.…”

Section: Conceptmentioning

confidence: 99%

Tailoring Surface Self‐Organization for Nanoscale Polygonal Morphology on Germanium

et al. 2021

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radiation (THz radiation) emission. [12][13][14] Partially amorphized Ge quantum dots encapsulated in the silicon matrix are proven to show an improved lasing action making them potentially useful for application in silicon integrated technology. [1,2] Enhanced molecular sensing capabilities have been demonstrated by plasmonenhanced infrared absorption due to an array of germanium nanostructures. [3,4] Arrays of GeSi nanostructures on silicon substrate showed an enhancement in the photo-voltage, showing promise for solar cell applications. [10] Surprisingly, germanium being an indirect bandgap semiconductor, periodic arrays of germanium nanostructures gave rise to THz radiation emission with comparable amplitude to the direct bandgap semiconductor n-GaAs (n-type GaAs). [13] Germanium nanostructures show threefold to fivefold increased amplitude of THz radiation emission as compared to the baregermanium surface. Local surface charge collection due to the high surface area is attributed to the enhanced THz emission from the Ge nanostructures. [12] These reports suggest that the periodic arrays of nanostructures play an essential role for improved light-matter interactions such as enhanced surface plasmon based sensing and improved terahertz emission. [3,4,13] The evolution of polygonal-shaped nanoholes on the (100) surface of germanium, aided by focused ion beam induced self-organization, is presented. The energetic beam of ions creates a viscous phase which, at a thermodynamical minimum, leads to surface self-organization. A directed viscous-flow along the predefined nanoholes provides well-ordered polygonal nanostructures, ranging from triangles to hexagons and octagons, as desired. The amorphization exhibiting a confined viscous-flow at the walls of nanoholes is attributed to the localized melting zones induced by sitespecific thermal spikes during ion irradiation, as revealed by microscopy and molecular dynamics studies. This leads to a local self-organization in the vicinity of each circular nanohole via a viscous-fingering process at the nanoscale. Such controlled self-organization, with the help of a predefined scanning grid, transforms the circular holes into the desired polygonal shape. The present morphology manipulation promises to surmount the barriers concerning the size reduction efforts in the field of nanofabrication.

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Nanoscaled Fractal Superstructures via Laser Patterning—A Versatile Route to Metallic Hierarchical Porous Materials

Cited by 13 publications

References 44 publications

Three‐Phase Reconstruction Reveals How the Microscopic Structure of the Carbon‐Binder Domain Affects Ion Transport in Lithium‐Ion Batteries

Three‐Phase Reconstruction Reveals How the Microscopic Structure of the Carbon‐Binder Domain Affects Ion Transport in Lithium‐Ion Batteries

Laser Direct Writing via Two-Photon Polymerization of 3D Hierarchical Structures with Cells-Antiadhesive Properties

Tailoring Surface Self‐Organization for Nanoscale Polygonal Morphology on Germanium

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