Academic literature on the topic 'Dynamic hierarchical self-Assembly'
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Journal articles on the topic "Dynamic hierarchical self-Assembly"
Zhang, Huan, Fan Pan, and Shiben Li. "Self-Assembly of Lipid Molecules under Shear Flows: A Dissipative Particle Dynamics Simulation Study." Biomolecules 13, no. 9 (September 7, 2023): 1359. http://dx.doi.org/10.3390/biom13091359.
Full textShi, Lijuan, Fenglin Liu, Tingting Liu, Jingsi Chen, Shaobo Xu, and Hongbo Zeng. "Reversible fabrication and self-assembly of a gemini supra-amphiphile driven by dynamic covalent bonds." Soft Matter 14, no. 29 (2018): 5995–6000. http://dx.doi.org/10.1039/c8sm01239c.
Full textFreeman, Ronit, Ming Han, Zaida Álvarez, Jacob A. Lewis, James R. Wester, Nicholas Stephanopoulos, Mark T. McClendon, et al. "Reversible self-assembly of superstructured networks." Science 362, no. 6416 (October 4, 2018): 808–13. http://dx.doi.org/10.1126/science.aat6141.
Full textWu, Ruirui, Shunfa Gong, Lifang Wu, Hailong Yu, Qiuju Han, and Wenzhi Wu. "Laser-induced crystal growth observed in CsPbBr3 perovskite nanoplatelets." Physical Chemistry Chemical Physics 24, no. 14 (2022): 8303–10. http://dx.doi.org/10.1039/d1cp05874f.
Full textMelaku, Ashenafi Zeleke, Wei-Tsung Chuang, Yeong-Tarng Shieh, Chih-Wei Chiu, Duu-Jong Lee, Juin-Yih Lai, and Chih-Chia Cheng. "Programmed exfoliation of hierarchical graphene nanosheets mediated by dynamic self-assembly of supramolecular polymers." Materials Chemistry Frontiers 5, no. 18 (2021): 6998–7011. http://dx.doi.org/10.1039/d1qm00810b.
Full textSuárez-Picado, Esteban, Maëva Coste, Jean-Yves Runser, Mathieu Fossépré, Alain Carvalho, Mathieu Surin, Loïc Jierry, and Sébastien Ulrich. "Hierarchical Self-Assembly and Multidynamic Responsiveness of Fluorescent Dynamic Covalent Networks Forming Organogels." Biomacromolecules 23, no. 1 (December 15, 2021): 431–42. http://dx.doi.org/10.1021/acs.biomac.1c01389.
Full textZeng, Chunyan, Chen Gao, Li Yuan, Tao Liang, Ruisong Yang, Wei Zhang, and Song Nie. "Water Evaporation-Induced Self-Assembly of Hierarchical CuO/MnO2 Composite Nanospheres and their Applications in Lithium-Ion Batteries." Nano 12, no. 02 (February 2017): 1750022. http://dx.doi.org/10.1142/s1793292017500229.
Full textBystrov, Vladimir, Ilya Likhachev, Sergey Filippov, and Ekaterina Paramonova. "Molecular Dynamics Simulation of Self-Assembly Processes of Diphenylalanine Peptide Nanotubes and Determination of Their Chirality." Nanomaterials 13, no. 13 (June 21, 2023): 1905. http://dx.doi.org/10.3390/nano13131905.
Full textCoste, Maëva, Esteban Suárez-Picado, and Sébastien Ulrich. "Hierarchical self-assembly of aromatic peptide conjugates into supramolecular polymers: it takes two to tango." Chemical Science 13, no. 4 (2022): 909–33. http://dx.doi.org/10.1039/d1sc05589e.
Full textRakotondradany, Felaniaina, Hanadi Sleiman, and M. A. Whitehead. "Hydrogen-bond self-assembly of DNA-base analogues — Experimental results." Canadian Journal of Chemistry 87, no. 5 (May 2009): 627–39. http://dx.doi.org/10.1139/v09-028.
Full textDissertations / Theses on the topic "Dynamic hierarchical self-Assembly"
Parras, Petros. "Self-assembly and dynamics in block copolymers with hierarchical order." Thesis, University of Reading, 2006. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.493799.
Full textPung, Hélène. "Cristaux liquides ioniques thermotropes : Relations structure/propriétés de transport ionique." Electronic Thesis or Diss., Université Grenoble Alpes, 2024. http://www.theses.fr/2024GRALV007.
Full textDeveloping multi-scale spatial (nano/meso/micro-macroscopic) and temporal studies is crucial to understand, control, and pilot the relationships linking the structure to the ionic transport properties of hierarchically self-assembled functional materials. It is along these research lines that this exploratory work is positioned to meet their associated scientific challenges. It aims in particular to bring together elements of understanding for designing families of electrolytes with tuneable-by-design (cat/an)ionic conductivity levels and that can be implemented by reliable manufacturing processes to authorize their scalable integration into more efficient electrochemical energy conversion and storage devices. The scrutinized model families of soft-matter electrolytes are Thermotropic Ionic Liquid Crystals (TILCs), which synergistically combine dynamic hierarchical self-assembly with self-healing functionalities to encode dimensionality (quasi-1D/ quasi-2D/3D) controlled ionic transport. This research work presents and discusses the molecular engineering, syntheses and detailed studies of these model stimuli-responsive (An/Cat)ionic (A/C)-TILCs conductors.The study of the supramolecular organization of a model family of K+ and Na+ cation-conducting C-TILCs has unravelled i) a monotropic (i.e. which develops only during of the first heating scan) bicontinuous Cubic mesophase (Cubbi) with an Ia3d symmetry and ii) a hexagonal Columnar mesophase (Colhex), encoding 3D and quasi-1D transport processes, respectively. Polar ionic sub-domains are localized at the heart of the columns decorated at their periphery by aliphatic chains. The experimental study and modelling of the confinement of charge carriers within a model family of C18C18Im+/X- (X= Br-, I-, N(CN)2-) A-TILCs forming interdigitated Smectic A mesophases (SmAd are hosting quasi-2D anisotropic ionic transport) reveals a regime of nanoconfinement of anions subjected to electrostatic interactions within the ca. 1 nm-"thick" polar sub-layers within their lamellar organizations. The study of these TILCs thus addresses the functional impact of mosaicity, i.e. how the coexistence of mesomorphic domains presenting different orientations and sizes is impacting ionic transport.A first direct experimental description allows to describe the role of this dynamic mosaicity both i) on the long-range organization of mesomorphic domains and ii) onto ion transport at the meso-/macro-scopic scale. Within mesophases formed by the K+-cation conducting C-TILC, the Cubbi mesophase presents conductivity values two orders of magnitude greater than those associated to the Colhex mesophase. As the Cubbi mesophase does not require specific defect management strategies (low density of defects/homophasic interfaces), it turns out that polar subdomains can thus percolate efficiently according to an intrinsically 3D mechanism. In contrast, the long-range ordering of the (dynamic) SmAd mesomorphic domains of the C18C18Im+/N(CN)2- A-TILC, induced by the application of an external stimulus (here, a magnetic field of 1 T), results in a ca. x1.6 increase (from 92 to 145 nm) of the average size of mesomorphic domains at 80°C. Due to the reduction of the disorder and of the number of homophasic interfaces (which can penalize the transport of anions), a natural (expected) increase in conductivity values by a factor ca. x2.6 (9 to 25 µS·cm-1) is observed.Ultimately, TILCs, i.e. 2.0 electrolytic materials encoding ionic transport properties and (bioinspired) dynamic self-assembly/repairing functionalities, are consisting in an original class of stimuli-sensitive functional materials for the electrochemical conversion and storage of energy
Book chapters on the topic "Dynamic hierarchical self-Assembly"
Reber, Arthur S., František Baluška, and William B. Miller. "The Structural and Bioelectrical Basis of Cells." In The Sentient Cell, 67–76. Oxford University PressOxford, 2023. http://dx.doi.org/10.1093/oso/9780198873211.003.0005.
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