Visualizing Molecular-Scale Adsorption Structures of Anti-freezing Surfactants on Sapphire (0001) Surfaces at Different Concentrations by 3D Scanning Force Microscopy

Ikarashi, Takahiko; Nakayama, Kyosuke; Nakajima, N.; Miyata, Kazuki; Miyazawa, Keisuke; Fukuma, Takeshi

doi:10.1021/acsami.2c10475

Cited by 3 publications

(4 citation statements)

References 58 publications

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“…The FM‐AFM technique has recently emerged as a highly effective tool for obtaining unique structural information at molecular and atomic scales, offering unprecedented detail for a wide range of surfaces, interfaces, and nanostructures. [ 36–39 ] In the present study, the peptides are assembled in pure water, with pH ≈7.0, and therefore, the hydropathy and pI values shown in Figure 1 are expected to be the true values of the peptides. In general, the broad traits of the self‐organization are similar for each of the peptides, i.e., first forming monomolecular‐thick nanowires, oriented at 60° and 120° to each other, following homogeneous nucleation (i.e., isolated locations on the surface) and subsequent growth, both longitudinally and transverse to the peptide nanowire.…”

Section: Resultsmentioning

confidence: 93%

Dynamics of Molecular Self‐Assembly of Short Peptides at Liquid–Solid Interfaces – Effect of Charged Amino Acid Point Mutations

Yurtsever,

Hirata,

Kojima

et al. 2024

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Self‐organizing solid‐binding peptides on atomically flat solid surfaces offer a unique bio/nano hybrid platform, useful for understanding the basic nature of biology/solid coupling and their practical applications. The surface behavior of peptides is determined by their molecular folding, which is influenced by various factors and is challenging to study. Here, the effect of charged amino acids is studied on the self‐assembly behavior of a directed evolution selected graphite‐binding dodecapeptide on graphite surface. Two mutations, M6 and M8, are designed to introduce negatively and positively charged moieties, respectively, at the anchoring domain of the wild‐type (WT) peptide, affecting both binding and assembly. The questions addressed here are whether mutant peptides exhibit molecular crystal formation and demonstrate molecular recognition on the solid surface based on the specific mutations. Frequency‐modulated atomic force microscopy is used for observations of the surface processes dynamically in water at molecular resolution over several hours at the ambient. The results indicate that while the mutants display distinct folding and surface behavior, each homogeneously nucleates and forms 2D self‐organized patterns, akin to the WT peptide. However, their growth dynamics, domain formation, and crystalline lattice structures differ significantly. The results represent a significant step toward the rational design of bio/solid interfaces, potent facilitators of a variety of future implementations.

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Section: Resultsmentioning

confidence: 93%

Dynamics of Molecular Self‐Assembly of Short Peptides at Liquid–Solid Interfaces – Effect of Charged Amino Acid Point Mutations

Yurtsever,

Hirata,

Kojima

et al. 2024

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“…3D-SOSs) may be visualized by 3D-AFM. Recently, we have made tremendous efforts to explore this possibility and succeeded in demonstrating it for various 3D-SOSs, including the hydration structures on the CNCs, 21) the molecular adsorption structures of the anti-freezing surfactants, 27) the cellular components inside the living cells, 28) and the charge distributions inside the EDLs. 29) These examples demonstrated the effectiveness of this method in various in-liquid sciences, including interface sciences, life sciences and electrochemistry.…”

Section: Discussionmentioning

confidence: 99%

“…Among our recent 3D-AFM studies on the interfacial molecular structures, here we review the study on molecular-scale adsorption structures of anti-freezing surfactants on sapphire (0001) surface. 27) Car coolant is used to remove the heat generated by the engine from the car system. For using a car in a cold area, the car coolant's freezing point (T fp ) should be kept at less than −35 °C.…”

Section: Adsorption Structures Of Anti-freezing Surfactants On Sapphi...mentioning

confidence: 99%

“…Recently, we have made tremendous efforts to explore such possibilities and demonstrated direct 3D imaging of various 3D-SOSs, including hydration structures, 21) swollen polymers, 19) adsorbed molecules, 27) intra-cellular structures 28) and potential distribution inside an EDL. 29) Here, we review recent progresses in our 3D-AFM studies on various 3D-SOSs.…”

Section: Introductionmentioning

confidence: 99%

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Visualizing the inside of three-dimensional self-organizing systems by three-dimensional atomic force microscopy

Fukuma

2023

Jpn. J. Appl. Phys.

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The development of three-dimensional atomic force microscopy (3D-AFM) enabled the direct visualization of 3D hydration structures at solid-liquid interfaces with subnanometer resolution. Such imaging is possible because the hydration structure, once disorganized by the tip scan, can recover its original state through self-organization. Based on the same concept, the interior of any 3D self-organizing systems (3D-SOSs) may be visualized by 3D-AFM. To pursue this possibility, we have explored 3D-AFM imaging of various 3D-SOSs in interface sciences, life sciences and electrochemistry. Here, we review our recent progress in such 3D-AFM studies on 3D-SOSs, including hydration structures on cellulose nanocrystals, adsorption structures of anti-freezing surfactants on sapphire (0001) surfaces, intra-cellular components inside living cells, and charges accumulated inside an electric double layer. These examples demonstrate the effectiveness of 3D-AFM for understanding the nanoscale structures, properties and functions of various 3D-SOSs.

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Revealing the Mechanism Underlying 3D‐AFM Imaging of Suspended Structures by Experiments and Simulations

Alam,

Penedo,

Sumikama

et al. 2024

Small Methods

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The invention of 3D atomic force microscopy (3D‐AFM) has enabled visualizing subnanoscale 3D hydration structures. Meanwhile, its applications to imaging flexible molecular chains have started to be experimentally explored. However, the validity and principle of such imaging have yet to be clarified by comparing experiments and simulations or cross‐observations with an alternative technique. Such studies are impeded by the lack of an appropriate model. Here, this difficulty is overcome by fabricating 3D carbon nanotube (CNT) structures flexible enough for 3D‐AFM, large enough for scanning electron microscopy (SEM), and simple enough for simulations. SEM and 3D‐AFM observations of the same model provide unambiguous evidence to support the possibility of imaging overlapped nanostructures, such as suspended CNT and underlying platinum (Pt) nanodots. Langevin dynamics simulations of such 3D‐AFM imaging clarify the imaging mechanism, where the flexible CNT is laterally displaced to allow the AFM probe access to the underlying structures. These results consistently show that 3D‐AFM images are affected by the friction between the CNT and AFM nanoprobe, yet it can be significantly suppressed by oscillating the cantilever. This study reinforces the theoretical basis of 3D‐AFM for imaging various 3D self‐organizing systems in diverse fields, from life sciences to interface sciences.

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Visualizing Molecular-Scale Adsorption Structures of Anti-freezing Surfactants on Sapphire (0001) Surfaces at Different Concentrations by 3D Scanning Force Microscopy

Cited by 3 publications

References 58 publications

Dynamics of Molecular Self‐Assembly of Short Peptides at Liquid–Solid Interfaces – Effect of Charged Amino Acid Point Mutations

Dynamics of Molecular Self‐Assembly of Short Peptides at Liquid–Solid Interfaces – Effect of Charged Amino Acid Point Mutations

Visualizing the inside of three-dimensional self-organizing systems by three-dimensional atomic force microscopy

Revealing the Mechanism Underlying 3D‐AFM Imaging of Suspended Structures by Experiments and Simulations

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