Your search keyword '"Atomic force microscopy"' showing total 109,700 results

1. On the mechanism for work function change of gold electrodes by ultrathin polyethyleneimine (PEI) films: Effect of molecular order.

Author

Ferreira, Claudia S. G., Sousa, Marcos S., Günther, Florian S., and Miranda, Paulo B.

Subjects

*MONOMOLECULAR films, *THIN films, *ATOMIC spectra, *ATOMIC force microscopy, *SUBSTRATES (Materials science)

Abstract

Polyethyleneimine (PEI) is a widely used cationic polyelectrolyte. In organic electronics, it is a universal surface modifier for shifting the electrode work function (Φ) and improving charge injection into electronic devices. This effect may depend on the conformation and dipolar order of the PEI ultrathin film, but their detailed experimental evaluation has not yet been reported. Thus, we used sum-frequency generation (SFG) spectroscopy to probe the net orientation of polar groups of PEI films on glass and gold. The films were fabricated by spin-coating from alcoholic solutions or by dip-coating from aqueous solutions of various pH values, with both branched (b-PEI) and linear (l-PEI) structures. The obtained SFG spectra and atomic force microscopy (AFM) images indicated that the conformational ordering of the PEI layers increases over the period of 14 days after fabrication, being slightly more pronounced for l-PEI vs b-PEI, and for dip-coating vs spin coating fabrication. Furthermore, both the pH of the dip-coating solutions and the substrate nature influence the final morphology and order of the adsorbed films. On glass, they are optimized at an intermediate pH 5, while on gold, the greatest homogeneity is observed at pH 2 and the largest dipolar order is observed at pH 10. The pH dependence of changes in the work function of gold by PEI (|ΔΦ|) suggests that the electronic contribution is dominant. Nevertheless, the evolution of the PEI dipolar ordering was accompanied by small variations of |ΔΦ|, suggesting that it does have a significant contribution, especially at conditions for which the electronic contribution is reduced. [ABSTRACT FROM AUTHOR]

Published

2024

2. Synergistic corrosion inhibition of 4-hydroxypyridine and halogen ions: Insights from interfacial nonlinear spectroscopy.

Author

Hu, Huihui, Feng, Rongjuan, Ren, Xiaorui, Wang, Dong, Guo, Yuan, and Zhang, Zhen

Subjects

*SECOND harmonic generation, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *SUSTAINABLE chemistry, *METALLIC surfaces, *MILD steel

Abstract

4-Hydroxypiridine (4-HPy) is a green chemistry corrosion inhibitor for low-carbon steel, valued for its environmental compatibility and low toxicity. Despite lower initial effectiveness than 4-mercapto/4-aminopyridine, 4-HPy's performance is markedly enhanced by halogen ions. By employing second harmonic generation (SHG) spectroscopy combined with electrochemical methods, Raman spectroscopy, atomic force microscopy, x-ray photoelectron spectroscopy, and in situ UV spectroscopy, this study elucidates the synergistic enhancement mechanism of 4-HPy with Cl−, Br−, and I− in 0.5 mol/L HCl solution. Time-dependent SHG measurements showed a two-step process of rapid adsorption and subsequent orientation change, with a proposed mechanism to interpret the temporal changes in SHG intensity. Deducing the adsorption kinetic equations and their application to the experimental data yields the adsorption rate (kad) and orientation change rate (Kre). Halogens reduce the orientation angle of 4-HPy, facilitating its adsorption on the substrate surface and effectively inhibiting corrosion via distinct mechanisms. Cl− and Br− ions primarily adsorb onto the metal surface, forming an adsorption film that not only enhances the subsequent adsorption of 4-HPy but also provides a protective effect for the metal surface. Conversely, I− forms mainly complexes with 4-HPy in solution, co-adsorbs onto the metal surface, and demonstrates a significant synergistic effect. This study revealed the synergistic efficacy hierarchy among halogen ions, with the order 4HPy + NaCl < 4HPy + NaBr < 4HPy + NaI. This study enhances our molecular-level understanding of the synergistic mechanism between halogen ions and corrosion inhibitors and provides valuable insights for designing and developing effective corrosion inhibitors. [ABSTRACT FROM AUTHOR]

Published

2024

3. Resistance behavior of Sb7Se3 thin films based on flexible mica substrate.

Author

Wang, Yukun and Hu, Yifeng

Subjects

*ATOMIC force microscopy, *TRANSMISSION electron microscopy, *TRANSITION temperature, *SUBSTRATES (Materials science), *THIN films

Abstract

In this paper, we explored the resistivity behavior of Sb7Se3 thin films on flexible mica. The films maintained their resistance characteristics through various thicknesses and bending cycles. With increasing bends, resistivity and phase transition temperature of both amorphous and crystalline states rose, while the resistance drift coefficient gradually increased. Raman and near infrared experiments confirmed the internal structural changes and bandgap enhancement after bending. Transmission electron microscopy showed enhanced crystallization and uniform element distribution after annealing. Atomic force microscopy observed cracks, explaining the property changes. Additionally, we developed a flexible Sb7Se3 thin-film resistive device with swift reversibility (∼10 ns) regardless of bending, opening new avenues for flexible information storage. [ABSTRACT FROM AUTHOR]

Published

2024

4. Characterization of dielectric diffraction gratings on multilayer structures by spectroscopic ellipsometry.

Author

Henn, Sebastian, Grundmann, Marius, and Sturm, Chris

Subjects

*SCANNING force microscopy, *DIFFRACTION gratings, *ATOMIC force microscopy, *BLOCH waves, *DIELECTRIC properties

Abstract

Gratings are widely used for coupling into and out of evanescent and propagating electromagnetic modes, which are otherwise not accessible due to their large in-plane wave vector. A precise description of the optical response requires the knowledge of the grating geometry. Here, we present an investigation of the optical properties of dielectric gratings of sub-micron periodicity fabricated on a multilayer structure, which supports Bloch surface waves, by means of spectroscopic ellipsometry. Taking into account non-idealities, such as the finite spectral bandwidth, in the modeling process is shown to be a necessity for an accurate description of the observed spectra. The grating geometry determined from the analysis of ellipsometry data agrees very well with atomic force microscopy scans. Thus, our ellipsometric model is corroborated. [ABSTRACT FROM AUTHOR]

Published

2024

5. A new mechanical engineering strategy based on microsphere probe and its application in transition metal dichalcogenides.

Author

Yang, Rui, Cui, Yi, Yang, Zicong, Qin, Feng, Rao, Junhao, Yuan, Hongtao, and Qiu, Caiyu

Subjects

*ATOMIC force microscopy, *STRAINS & stresses (Mechanics), *MECHANICAL engineering, *ELECTRONIC modulation, *TRANSITION metals

Abstract

Mechanical engineering of 2D materials allows continuous and reversible modulation of their electronic and photonic properties. Although photoluminescence (PL) measurement is an effective way to monitor the effects of mechanical forces on 2D semiconductors, there is currently a lack of techniques to enhance PL signals during stress application. This study presents an innovative mechanical engineering approach that integrates a dielectric microsphere as an atomic force microscopy (AFM) probe into a Raman-AFM system. Force–distance curve tests and COMSOL simulations were performed to analyze and estimate the compressive stress exerted by the microsphere. Importantly, the PL signals of transition metal dichalcogenides subjected to microsphere probe's force were enhanced and reveal distinct mechanical responses depending on the substrate rigidity: compressive pressures for rigid substrates and tensile strains for flexible ones. Notably, this strategy not only amplifies spectral signals in real time but also achieves fine stress modulation in the precise targeted material region, demonstrating its superiority in sensitive mechanical engineering applications. Our work offers a new avenue for the deliberate design of mechanical strains in 2D materials, which is crucial for optimizing the performance of related devices. [ABSTRACT FROM AUTHOR]

Published

2024

6. Investigations of the adsorbed layer of polysulfone: Influence of the thickness of the adsorbed layer on the glass transition of thin films.

Author

Omar, Hassan, Ahamadi, Shayan, Hülagü, Deniz, Hidde, Gundula, Hertwig, Andreas, Szymoniak, Paulina, and Schönhals, Andreas

Subjects

*GLASS transition temperature, *ATOMIC force microscopy, *GLASS transitions, *SUBSTRATES (Materials science), *THIN films

Abstract

This work studies the influence of the adsorbed layer on the glass transition of thin films of polysulfone. Therefore, the growth kinetics of the irreversibly adsorbed layer of polysulfone on silicon substrates was first investigated using the solvent leaching approach, and the thickness of the remaining layer was measured with atomic force microscopy. Annealing conditions before leaching were varied in temperature and time (0–336 h). The growth kinetics showed three distinct regions: a pre-growth step where it was assumed that phenyl rings align parallel to the substrate at the shortest annealing times, a linear growth region, and a crossover from linear to logarithmic growth observed at higher temperatures for the longest annealing times. No signs of desorption were observed, pointing to the formation of a strongly adsorbed layer. Second, the glass transition of thin polysulfone films was studied in dependence on the film thickness using spectroscopic ellipsometry. Three annealing conditions were compared: two with only a tightly bound layer formed in the linear growth regime and one with both tightly bound and loosely adsorbed layers formed in the logarithmic growth regime. The onset thickness and increase in the glass transition temperature increases with annealing time and temperature. These differences were attributed to the distinct conformations of the formed adsorbed layers. [ABSTRACT FROM AUTHOR]

Published

2024

7. Effects of electron beam irradiation on CrMnV and CrMnTiV high entropy alloys: Nano-mechanical, structural, and thermodynamic perspectives.

Author

Sultana, N. A., Mohammed, Y. S., Pendleton, S. J., Vennekate, J., Ciovati, G., Li, X., Baumgart, H., and Elmustafa, A. A.

Subjects

*FIELD emission electron microscopy, *ENERGY dispersive X-ray spectroscopy, *MECHANICAL loads, *ATOMIC force microscopy, *EXPOSURE dose, *ELECTRON field emission, *ELECTRON beams

Abstract

Beam exit windows are crucial components of any particle accelerator as they provide an interface between the beamline vacuum and target material at atmospheric media. For high beam power machines, special materials and designs are required to withstand high radiation and mechanical loads, while minimizing energy loss during transition and maximizing window lifetime. This research investigates the impact of electron beam exposure to bulk CrMnV and CrMnTiV high entropy alloys (HEAs) with the primary goal of identifying suitable candidate materials for the design of robust and durable exit window settings. The selection criteria include intrinsic characteristics, power dissipation, and mechanical responses. According to the thermodynamic calculations, both equiatomic CrMnV and the addition of 7% of Ti with equiatomic CrMnV yield solid-solutions phases. The structural and mechanical properties of CrMnV and CrMnTiV samples were tested using field emission scanning electron microscopy, atomic force microscopy, scanning electron microcopy with energy dispersive x-ray spectroscopy, x-ray diffraction, and nanoindentation before and after exposure to a dose of ∼66 kGy from a 10 MeV e-beam accelerator. Despite exhibiting beam transmission characteristics comparable to Cr and V, the indentation hardness of HEAs exceeded that of the Cr and V samples by five to six times. The examination of the CrMnTiV irradiated samples revealed organized deformation patterns depicting new features, which we suspect twinning and twin boundaries due to the addition of Ti to CrMnV. Ti, a hexagonal-close-packed crystal structure, is commonly known for deformation twinning behavior. [ABSTRACT FROM AUTHOR]

Published

2024

8. The role of carbon segregation in the electrical activity of dislocations in carbon doped GaN.

Author

Scales, Ze F., Koller, Christian, Lymperakis, Liverios, Nelhiebel, Michael, and Stoeger-Pollach, Michael

Subjects

*SCANNING transmission electron microscopy, *ATOMIC force microscopy, *POWER semiconductors, *DOPING agents (Chemistry), *DENSITY functional theory, *ELECTRON energy loss spectroscopy

Abstract

Dislocations have been proposed to affect the performance and reliability of GaN power semiconductors by being conductive pathways for leakage current. However, no direct evidence of a link between their electrical behavior and physical nature in carbon-doped semi-insulating GaN buffer layers has been obtained. Therefore, we investigate the electrical activity of dislocations by conductive atomic force microscopy and electron beam induced current to distinguish electrically active dislocations from non-active ones. We investigated six electrically active dislocations and discovered distinct carbon enrichment in the vicinity of all six dislocations, based on cross-sectional scanning transmission electron microscopy using electron energy loss spectrometry. Electrically non-active dislocations, which are the vast majority, sometimes also showed carbon enrichment, however, in only two out of seven cases. Consequently, carbon segregation seems to be a requirement for electrical activity, but a carbon surplus is not sufficient for electrical activity. We also performed first-principles total-energy calculations for mixed type threading dislocations, which validates carbon accumulation in the dislocation vicinity. The electrical and physical characterization results, complemented by density functional theory simulations, support the previously hypothesized existence of a carbon defect band and add new details. [ABSTRACT FROM AUTHOR]

Published

2024

9. Characterization of quantum dot-like emitters in programmable arrays of nanowrinkles of 1L-WSe2.

Author

Strasbourg, Matthew C., Yanev, Emanuil S., Darlington, Thomas P., Faagau, Kavika, Holtzman, Luke N., Barmak, Katayun, Hone, James C., Schuck, P. James, and Borys, Nicholas J.

Subjects

*PHOTONS, *LIGHT emitting diodes, *ATOMIC force microscopy, *THERMOCYCLING, *QUANTUM states

Abstract

When combined with nanostructured substrates, two-dimensional semiconductors can be engineered with strain to tailor light–matter interactions on the nanoscale. Recently, room-temperature nanoscale exciton localization with controllable wrinkling in 1L-WSe2 was achieved using arrays of gold nanocones. Here, the characterization of quantum dot-like states and single-photon emitters in the 1L-WSe2/nanocone system is reported. The nanocones induce a wide range of strains, and as a result, a diverse ensemble of narrowband, potential single-photon emitters is observed. The distribution of emitter energies reveals that most reside in two spectrally isolated bands, leaving a less populated intermediate band that is spectrally isolated from the ensembles. The spectral isolation is advantageous for high-purity quantum light emitters, and anti-bunched emission from one of these states is confirmed up to 25 K. Although the spatial distribution of strain is expected to influence the orientation of the transition dipoles of the emitters, multimodal emission polarization anisotropy and atomic force microscopy reveal that the macroscopic orientation of the wrinkles is not a good predictor of dipole orientation. Finally, the emission is found to change with thermal cycling from 4 to 290 K and back to 4 K, highlighting the need to control factors such as temperature-induced strain to enhance the robustness of this quantum emitter platform. The initial characterization here shows that controlled nanowrinkles of 1L-WSe2 generate quantum light in addition to uncovering potential challenges that need to be addressed for their adoption into quantum photonic technologies. [ABSTRACT FROM AUTHOR]

Published

2024

10. Characterization of quantum dot-like emitters in programmable arrays of nanowrinkles of 1L-WSe2.

Author

Strasbourg, Matthew C., Yanev, Emanuil S., Darlington, Thomas P., Faagau, Kavika, Holtzman, Luke N., Barmak, Katayun, Hone, James C., Schuck, P. James, and Borys, Nicholas J.

Subjects

PHOTONS, LIGHT emitting diodes, ATOMIC force microscopy, THERMOCYCLING, QUANTUM states

Abstract

When combined with nanostructured substrates, two-dimensional semiconductors can be engineered with strain to tailor light–matter interactions on the nanoscale. Recently, room-temperature nanoscale exciton localization with controllable wrinkling in 1L-WSe2 was achieved using arrays of gold nanocones. Here, the characterization of quantum dot-like states and single-photon emitters in the 1L-WSe2/nanocone system is reported. The nanocones induce a wide range of strains, and as a result, a diverse ensemble of narrowband, potential single-photon emitters is observed. The distribution of emitter energies reveals that most reside in two spectrally isolated bands, leaving a less populated intermediate band that is spectrally isolated from the ensembles. The spectral isolation is advantageous for high-purity quantum light emitters, and anti-bunched emission from one of these states is confirmed up to 25 K. Although the spatial distribution of strain is expected to influence the orientation of the transition dipoles of the emitters, multimodal emission polarization anisotropy and atomic force microscopy reveal that the macroscopic orientation of the wrinkles is not a good predictor of dipole orientation. Finally, the emission is found to change with thermal cycling from 4 to 290 K and back to 4 K, highlighting the need to control factors such as temperature-induced strain to enhance the robustness of this quantum emitter platform. The initial characterization here shows that controlled nanowrinkles of 1L-WSe2 generate quantum light in addition to uncovering potential challenges that need to be addressed for their adoption into quantum photonic technologies. [ABSTRACT FROM AUTHOR]

Published

2024

11. The interface between ice and alcohols analyzed by atomic force microscopy.

Author

Yanagisawa, Ryo, Ueda, Tadashi, Nakamoto, Kei-ichi, Lu, Zhengxi, Onishi, Hiroshi, and Minato, Taketoshi

Subjects

*ATOMIC force microscopy, *ORGANIC solvents, *YOUNG'S modulus, *SURFACE phenomenon, *SURFACE roughness

Abstract

This study investigates the interface between ice and organic solvents using atomic force microscopy (AFM). Atomically flat ice surfaces were prepared and observed by AFM in 1-octanol, 1-hexanol, and 1-butanol. The results show differences in surface roughness influenced by the interaction of ice and alcohols. Young's modulus of ice was analyzed by force curve measurements, providing valuable insights into the properties of ice in liquid environments. The results showed the characteristics of the ice surface in different solvents, suggesting potential applications in understanding surface and interface phenomena associated with ice under realistic conditions. [ABSTRACT FROM AUTHOR]

Published

2024

12. Interplay between photoinduced charge and energy transfer in manganese doped perovskite quantum dots.

Author

Panigrahi, Aradhana, Mishra, Leepsa, Dubey, Priyanka, Dutta, Soumi, Mondal, Sankalan, and Sarangi, Manas Kumar

Subjects

*ENERGY transfer, *CHARGE transfer, *QUANTUM dots, *ENERGY levels (Quantum mechanics), *ATOMIC force microscopy, *OPTOELECTRONIC devices, *MANGANESE

Abstract

A comprehensive study on the photo-excited relaxation dynamics in semiconducting perovskite quantum dots (PQDs) is pivotal in realizing their extensive potential for optoelectronics applications. Among different competing photoinduced relaxation kinetics, energy transfer and charge transfer (CT) in PQDs need special attention, as they often influence the device efficacy, particularly with the donor–acceptor hybrid architecture. In this work, we explore a detailed investigation into photoinduced CT dynamics in mixed halide undoped CsPb(Br/Cl)3 and Mn2+ doped CsPb(Br/Cl)3 PQDs with a quinone molecule, p-benzoquinone (BQ). The energy level alignment of undoped PQDs with BQ allows an efficient CT, whereas Mn2+ doping reduces the CT efficiency, experiencing a competition between energy transfer from host to dopant and CT to BQ. The conductive atomic force microscopy measurements unveil a direct correlation with the spectroscopic studies by showing a significant improvement in the conductance of undoped PQDs in the presence of BQ, while an inappreciable change is observed for doped PQDs. A much-reduced transition voltage and barrier height in the presence of BQ further validate faster CT for undoped PQD than the doped one. Furthermore, Mn2+ doping in PQDs is observed to enhance their stability, showing better air and thermal stability compared to their undoped counterparts. These results reveal that doping strategy can regulate the CT dynamics in these PQDs and increase their stability, which will be beneficial for the development of desired optoelectronic devices with long-term stability. [ABSTRACT FROM AUTHOR]

Published

2024

13. Strain engineering of the transition metal dichalcogenide chalcogen-alloy WSSe.

Author

Cianci, Salvatore, Blundo, Elena, Tuzi, Federico, Cecchetti, Daniele, Pettinari, Giorgio, Felici, Marco, and Polimeni, Antonio

Subjects

*TRANSITION metals, *ATOMIC force microscopy, *SEMICONDUCTOR materials, *TRANSITION metal alloys, *ENGINEERING

Abstract

Alloying has been a powerful and practical strategy to widen the palette of physical properties available to semiconductor materials. Thanks to recent advances in the synthesis of van der Waals semiconductors, this strategy can be extended to monolayers (MLs) of transition metal dichalcogenides (TMDs). Due to their extraordinary flexibility and robustness, strain is another powerful means to engineer the electronic properties of two-dimensional (2D) TMDs. In this article, we combine these two approaches in an exemplary metal dichalcogenide chalcogen-alloy, WSSe. Highly strained WSSe MLs are obtained through the formation of micro-domes filled with high-pressure hydrogen. Such structures are achieved by hydrogen-ion irradiation of the bulk material, a technique successfully employed in TMDs and h-BN. Atomic force microscopy studies of the WSSe ML domes show that the dome morphology can be reproduced in terms of the average of the elastic parameters and adhesion energy of the end compounds WSe 2 and WS 2. Micro-photoluminescence measurements of the WSSe domes demonstrate that the exceedingly high strains (ε ∼ 4 %) achieved in the domes trigger a direct-to-indirect exciton transition, similarly to WSe 2 and WS 2. Our findings heighten the prospects of 2D alloys as strain- and composition-engineerable materials for flexible optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2024

14. Comparison of electrical characteristics of thin tellurium layers obtained from chemical solution and by thermal evaporation in vacuum.

Author

Norkus, R., Klimas, V., Strazdienė, V., Devenson, J., Bukauskas, V., Niaura, G., Tamulaitis, G., and Krotkus, A.

Subjects

*SOLUTION (Chemistry), *OPTOELECTRONIC devices, *TELLURIUM, *TERAHERTZ spectroscopy, *CHEMICAL solution deposition, *ATOMIC force microscopy, *RAMAN spectroscopy

Abstract

Two-dimensional or other thin materials have high potential for use in next-generation electronic and optoelectronic devices. Recently, tellurium has gained much interest due to its broad applicability prospects. In this work, the physical properties of thin tellurium layers fabricated using two relatively simple and inexpensive technologies based on the deposition from a chemical solution and by thermal evaporation were compared. The morphology of the grown surfaces was analyzed using atomic force microscopy. The chemically deposited tellurium surface consists of nanometer-sized flakes, while polycrystalline layers are formed in the case of deposition by thermal evaporation. Additionally, the characteristics of the fabricated samples varied depending on their thickness, as observed in both Raman spectroscopy and THz spectroscopy measurements. Furthermore, the non-contact optical pump THz probe technique revealed that the layers had different carrier lifetimes and mobilities. The carrier lifetime of samples deposited by thermal evaporation is short, less than 40 ps, with mobility up to a few hundred cm2/V s. In contrast, chemically deposited samples have a longer carrier lifetime, ranging more than 500 ps, and superior mobility up to 1000 cm2/V s. [ABSTRACT FROM AUTHOR]

Published

2024

15. Persistence of Structural Lubricity on Contaminated Graphite: Rejuvenation, Aging, and Friction Switches.

Author

Oo, Wai, Gao, Hongyu, Müser, Martin, and Baykara, Mehmet

Subjects

Atomic force microscopy, Friction mechanisms, Gold nanoislands, Molecular dynamics, Structural lubricity, Surface contamination

Abstract

Using atomic force microscopy experiments and molecular dynamics simulations of gold nanoislands on graphite, we investigate why ultralow friction commonly associated with structural lubricity can be observed even under ambient conditions. Measurements conducted within a few days after sample synthesis reveal previously undiscovered phenomena in structurally lubric systems: rejuvenation, a drop in kinetic friction of an order of magnitude shortly after the onset of sliding; aging, a significant increase in kinetic friction forces after a rest period of 30 min or more; and switches, spontaneous jumps between distinct friction branches. These three effects are drastically suppressed a few weeks later. Imaging of a contamination layer and simulations provide a consistent picture of how single- and double-layer contamination underneath the gold nanoislands as well as contamination surrounding the nanoislands affect structural lubricity without leading to its breakdown.

Published

2024

16. Abrupt ternary III–V metamorphic buffers.

Author

Farinha, Thomas G., Supple, Edwin, Gorman, Brian P., and Richardson, Christopher J. K.

Subjects

*MOLECULAR beam epitaxy, *TERNARY alloys, *LATTICE constants, *ATOMIC force microscopy, *TRANSMISSION electron microscopy, *ELECTRON diffraction

Abstract

Emerging quantum materials as well as novel traditional electronic and photonic materials may enable a new generation of information science devices if they can be synthesized on suitable substrates. Additionally, material and device designs may benefit from tunable properties through engineered epitaxial strain for the manipulation of the electronic character. In this work, three series of III–V ternary alloys, GaInSb, AlInSb, and InAsSb, are grown via molecular beam epitaxy on GaAs (001) substrates to explore the flexibility of abrupt metamorphic epitaxial layers with tunable lattice parameters between 6.135 and 6.479 Å. Their deposition on both homomorphic GaAs and pseudomorphic AlAs buffers is also explored. The structures of these alloys are characterized via reflection high-energy electron diffraction, high-resolution x-ray diffraction, atomic force microscopy, and transmission electron microscopy to assess their suitability as stable buffer layers with wide variability of accessible lattice parameters. [ABSTRACT FROM AUTHOR]

Published

2024

17. NH3 adsorption and competition with H2O on a hydroxylated aluminosilicate surface.

Author

Franceschi, Giada, Conti, Andrea, Lezuo, Luca, Abart, Rainer, Mittendorfer, Florian, Schmid, Michael, and Diebold, Ulrike

Subjects

*X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *ADSORPTION (Chemistry)

Abstract

The interaction between ammonia (NH3) and (alumino)silicates is of fundamental and applied importance, yet the specifics of NH3 adsorption on silicate surfaces remain largely unexplored, mainly because of experimental challenges related to their electrically insulating nature. An example of this knowledge gap is evident in the context of ice nucleation on silicate dust, wherein the role of NH3 for ice nucleation remains debated. This study explores the fundamentals of the interaction between NH3 and microcline feldspar (KAlSi3O8), a common aluminosilicate with outstanding ice nucleation abilities. Atomically resolved non-contact atomic force microscopy, x-ray photoelectron spectroscopy, and density functional theory-based calculations elucidate the adsorption geometry of NH3 on the lowest-energy surface of microcline, the (001) facet, and its interplay with surface hydroxyls and molecular water. NH3 and H2O are found to adsorb molecularly in the same adsorption sites, creating H-bonds with the proximate surface silanol (Si–OH) and aluminol (Al–OH) groups. Despite the closely matched adsorption energies of the two molecules, NH3 readily yields to replacement by H2O, challenging the notion that ice nucleation on microcline proceeds via the creation of an ordered H2O layer atop pre-adsorbed NH3 molecules. [ABSTRACT FROM AUTHOR]

Published

2024

18. MnO(001) thin films on MgO(001) grown by reactive MBE using supersonic molecular beams.

Author

Pedersen, Andrew J., Liu, Junchen, Li, Fanxing, and Lamb, H. Henry

Subjects

*MOLECULAR beam epitaxy, *MOLECULAR beams, *THIN films, *SCANNING transmission electron microscopy, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy

Abstract

MnO(001) thin films were grown on commercial MgO(001) substrates at 520 °C by reactive molecular beam epitaxy (MBE) using Mn vapor and O2-seeded supersonic molecular beams (SMBs) both with and without radio frequency (RF) plasma excitation. For comparison, MnO(001) films were grown by reactive MBE using O2 from a leak valve. X-ray photoelectron spectroscopy confirmed the Mn2+ oxidation state and 10%–15% excess oxygen near the growth surface. Reflection high-energy electron diffraction and x-ray diffraction evidenced that the films were rock salt cubic MnO with very strong (001) orientation. High-angle annular dark field scanning transmission electron microscopy with energy-dispersive x-ray spectroscopy demonstrated abrupt MnO/MgO interfaces and indicated [(001)MnO||(001)MgO] epitaxial growth. Ex situ atomic force microscopy of films deposited without RF excitation revealed smooth growth surfaces. An SMB-grown MnO(001) film was converted to Mn3O4 with strong (110) orientation by post-growth exposure to an RF-discharge (RFD) SMB source providing O atoms; the surface of the resultant film contained elongated pits aligned with the MgO 110 directions. In contrast, using the RFD-SMB source for growth resulted in MnO(001) films with elongated growth pits and square pyramidal hillocks aligned along the MgO 110 and 100 directions, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

19. Plasma assisted remediation of SiC surfaces.

Author

Mathews Jr., M. A., Graves, A. R., Boris, D. R., Walton, S. G., and Stinespring, C. D.

Subjects

*X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *ATOMIC spectroscopy, *HYDROFLUORIC acid, *SURFACE defects

Abstract

This paper describes a three-step process to remediate surface and sub-surface defects on chemo-mechanically polished SiC surfaces. In this process, a CF4-based inductively coupled plasma with reactive ion etch was used to remove material to a depth, which is unaffected by surface and subsurface polishing damage. This produced a planarized but carbon-rich fluorinated surface. This surface was then exposed to a 2 min rapid thermal oxidation in air at 1000 °C to oxidize and volatilize the excess carbon and fluorinated species, respectively. The resulting surface oxide was then stripped using a dilute hydrofluoric acid in water solution. This process, referred to as plasma assisted remediation, reproducibly yielded planarized, stoichiometric surfaces with low levels of carbon and oxygen contamination suitable for subsequent device fabrication. In the supporting studies described here, 4H- and 6H-SiC(0001) surfaces were remediated and characterized by x-ray photoelectron spectroscopy and atomic force microscopy at each stage of the process. Experimental studies under ion-rich and radical-dominant conditions are also reported which provide greater insight into the underlying chemistry and physics of the process. [ABSTRACT FROM AUTHOR]

Published

2024

20. Prevention and characterization of thin film defects induced by contaminant aggregates in initiated chemical vapor deposition.

Author

Shindler, Simon, Franklin, Trevor, and Yang, Rong

Subjects

*CHEMICAL vapor deposition, *THIN films, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *OPTICAL diffraction

Abstract

As initiated Chemical Vapor Deposition (iCVD) finds increasing application in precision industries like electronics and optics, defect prevention will become critical. While studies of non-ideal morphology exist in the iCVD literature, no studies investigate the role of defects. To address this knowledge gap, we show that the buildup of short-chain polymers or oligomers during normal operation of an iCVD reactor can lead to defects that compromise film integrity. We used atomic force microscopy to show that oligomer aggregates selectively prevented film growth, causing these hole-like defects. X-ray diffraction and optical microscopy demonstrated the crystallinity of the aggregates, pointing to a flat-on lamellar or mono-lamellar structure. To understand the origin of the aggregates, spectroscopic ellipsometry showed that samples exposed to the reactor consistently accrued low-volatility contaminants. X-ray photoelectron spectroscopy revealed material derived from polymerization in the contamination, while scanning electron microscopy showed the presence of defect-causing aggregates. We directly linked oligomeric/polymeric contamination with defect formation by showing an increased defect rate when a contaminant polymer was heated alongside the sample. Most importantly, we showed that starting a deposition at a high sample temperature (e.g., 50 °C) before reducing it to the desired setpoint (e.g., 9 °C) unilaterally prevented defects, providing a simple method to prevent defects with minimal impact on operations. [ABSTRACT FROM AUTHOR]

Published

2024

21. Effects of structural defects on optical properties of InxGa1−xN layers and quantum wells.

Author

Liliental-Weber, Z. and dos Reis, Roberto

Subjects

*OPTICAL properties, *QUANTUM wells, *OPTICAL devices, *ATOMIC force microscopy, *PHOTOLUMINESCENCE, *GALLIUM nitride, *OPTICAL constants

Abstract

This review concentrates on the microstructure of InxGa1−xN layers and quantum wells (QWs) in relation to their optical properties. The microstructure of InxGa1−xN, with a constant In(x) concentration, shifts with layer thickness. Only layers below 100 nm for x = 0.1 are nearly defect-free. A photoluminescence peak is observed at 405 nm, in line with ∼10% In, suggesting band-edge luminescence. Layers with greater thickness and In content present a corrugated surface with numerous structural defects, including V-defects, causing redshifts and multi-peaks in photoluminescence up to 490 nm. These defects, resembling those in GaN, lead to a corrugated sample surface. Atomic force microscopy shows a 3.7-fold larger corrugation in samples with 20 QWs compared to those with 5 QWs measured on 2 × 2 μm2 areas. Like in GaN, dual growth on different crystallographic planes results in varied QW thicknesses, influencing optical traits of devices made from InxGa1−xN layers. The purpose of this review and the chosen subject is to highlight the significant contribution of Wladek Walukiewicz and his group to the current research on the properties of InxGa1−xN, which are crucial alloys in the field of optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2024

22. Dynamic Structural Change of Plant Epidermal Cell Walls under Strain

Author

Yu, Jingyi, Del Mundo, Joshua T, Freychet, Guillaume, Zhernenkov, Mikhail, Schaible, Eric, Gomez, Esther W, Gomez, Enrique D, and Cosgrove, Daniel J

Subjects

Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Cell Wall, Plant Epidermis, Microscopy, Atomic Force, Cellulose, Microfibrils, X-Ray Diffraction, Scattering, Small Angle, Onions, Stress, Mechanical, atomic force microscopy, plant epidermal cell walls, small‐angle X‐ray scattering, strain‐hardening, wide‐angle X‐ray scattering, Nanoscience & Nanotechnology

Abstract

The molecular foundations of epidermal cell wall mechanics are critical for understanding structure-function relationships of primary cell walls in plants and facilitating the design of bioinspired materials. To uncover the molecular mechanisms regulating the high extensibility and strength of the cell wall, the onion epidermal wall is stretched uniaxially to various strains and cell wall structures from mesoscale to atomic scale are characterized. Upon longitudinal stretching to high strain, epidermal walls contract in the transverse direction, resulting in a reduced area. Atomic force microscopy shows that cellulose microfibrils exhibit orientation-dependent rearrangements at high strains: longitudinal microfibrils are straightened out and become highly ordered, while transverse microfibrils curve and kink. Small-angle X-ray scattering detects a 7.4 nm spacing aligned along the stretch direction at high strain, which is attributed to distances between individual cellulose microfibrils. Furthermore, wide-angle X-ray scattering reveals a widening of (004) lattice spacing and contraction of (200) lattice spacing in longitudinally aligned cellulose microfibrils at high strain, which implies longitudinal stretching of the cellulose crystal. These findings provide molecular insights into the ability of the wall to bear additional load after yielding: the aggregation of longitudinal microfibrils impedes sliding and enables further stretching of the cellulose to bear increased loads.

Published

2024

23. Method for measuring the diameter of polystyrene latex reference spheres by atomic force microscopy

Author

Dagata, John A.

Subjects

Atomic force microscopy, Polystyrene, Standard reference materials

Abstract

Abstract: This report presents a correlated height and width measurement model for particle size analysis of spherical particles by atomic force microscopy (AFM). It is complementary to more familiar methods based on a single value of the particle height or on a line average obtained from a close-packed particle array. Significant influence quantities affecting the determination of average particle size and its uncertainty are considered for the important case of polystyrene latex (PSL) reference materials. Particlesubstrate deformation, resulting from adhesive contact between particle and substrate during sample preparation, is estimated as a function of particle size. Post-processing of AFM datasets is explored as a means of eliminating bias due to non-steady state measurement conditions. These biases arise from variable particle-tip interaction caused by drift of instrumental parameters from their optimal settings during long acquisition times and inevitable wear of the AFM probe. Changes of the initial probe shape are established using a Si/SiO2 multilayer tip characterizer and are updated periodically during the analysis of sequential data sets for combinations of several particles sizes and different probes. Finally, the capability of this procedure to serve as a statistical error-correction scheme in AFM particle-size metrology is assessed.

Published

2016

24. Deciphering the free energy landscapes of SARS-CoV-2 wild type and Omicron variant interacting with human ACE2.

Author

Lan, Pham Dang, Nissley, Daniel A., O'Brien, Edward P., Nguyen, Toan T., and Li, Mai Suan

Subjects

*SARS-CoV-2 Omicron variant, *ANGIOTENSIN converting enzyme, *SARS-CoV-2, *CELL receptors, *ATOMIC force microscopy

Abstract

The binding of the receptor binding domain (RBD) of the SARS-CoV-2 spike protein to the host cell receptor angiotensin-converting enzyme 2 (ACE2) is the first step in human viral infection. Therefore, understanding the mechanism of interaction between RBD and ACE2 at the molecular level is critical for the prevention of COVID-19, as more variants of concern, such as Omicron, appear. Recently, atomic force microscopy has been applied to characterize the free energy landscape of the RBD–ACE2 complex, including estimation of the distance between the transition state and the bound state, xu. Here, using a coarse-grained model and replica-exchange umbrella sampling, we studied the free energy landscape of both the wild type and Omicron subvariants BA.1 and XBB.1.5 interacting with ACE2. In agreement with experiment, we find that the wild type and Omicron subvariants have similar xu values, but Omicron binds ACE2 more strongly than the wild type, having a lower dissociation constant KD. [ABSTRACT FROM AUTHOR]

Published

2024

25. Interface smoothing in short-period W/B4C multilayers using neon ion beam polishing.

Author

IJpes, D., Yakshin, A. E., Sturm, J. M., and Ackermann, M. D.

Subjects

*ION beams, *MULTILAYERS, *INTERFACIAL roughness, *OPTICAL constants, *ATOMIC force microscopy

Abstract

Short-period 2.5 nm W/B4C multilayers are useful as dispersive Bragg reflectors in wavelength-dispersive x-ray fluorescence. However, high roughness at the W–B4C interfaces deteriorates optical performance. To improve this, low-energy neon ion beam polishing (IBP) has been applied in sputter-deposited 2.5 nm W/B4C multilayers. Two energies, 200 and 50 eV, were investigated to study the effects of polishing by sputter removal (200 eV) and polishing by the mobilization of weakly bound surface atoms (50 eV). Atomic force microscopy and x-ray scattering showed reduced interface roughness for both IBP energies. However, the optical constant profile of 200 eV IBP showed strong W–B4C intermixing and interface asymmetry, leading to significant reflectance loss. In contrast, 50 eV IBP resulted in sharp, symmetric interfaces and increased optical contrast. A 43% peak reflectance at θ = ⁓9.7° grazing for W/B4C with 50 eV IBP was measured at λ = 0.834 nm—a 6.4% increase relative to non-polished W/B4C, corresponding to a 25% increase in integrated reflectance. These results highlight the necessity of using low-energy ion polishing by the mobilization of weakly bound surface atoms in short-period multilayers—rather than polishing by sputter removal. [ABSTRACT FROM AUTHOR]

Published

2023

26. Method of mechanical exfoliation of bismuth with micro-trench structures.

Author

Yu, Oulin, Allgayer, Raphaela, Godin, Simon, Lalande, Jacob, Fossati, Paolo, Hsu, Chunwei, Szkopek, Thomas, and Gervais, Guillaume

Subjects

*BISMUTH, *VAN der Waals forces, *ATOMIC force microscopy, *RAMAN microscopy, *STRESS concentration, *RAMAN spectroscopy

Abstract

The discovery of graphene led to a burst in search for 2D materials originating from layered atomic crystals coupled by van der Waals force. While bulk bismuth crystals share this layered crystal structure, unlike other group V members of the periodic table, its interlayer bonds are stronger such that traditional mechanical cleavage and exfoliation techniques have shown to be inefficient. In this work, we present a novel mechanical cleavage method for exfoliating bismuth by utilizing the stress concentration effect induced by micro-trench SiO 2 structures. As a result, the exfoliated bismuth flakes can achieve thicknesses down to the sub-10 nm range, which are analyzed by atomic force microscopy and Raman spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2023

27. Air stable plasma passivation of GaAs at room temperature.

Author

Kauppinen, Christoffer

Subjects

*PLASMA stability, *PASSIVATION, *NITRIDING, *AUDITING standards, *HYDROGEN plasmas, *NITROGEN plasmas, *GALLIUM arsenide, *ATOMIC force microscopy

Abstract

GaAs surfaces require electrical and chemical passivation for semiconductor devices, but in order to have air stable passivation, high temperatures have been previously required in the passivation step. Here, we demonstrate air-stable, ex situ plasma passivation of GaAs using consecutive hydrogen and nitrogen plasmas at room temperature. No pre-clean using deoxidizing wet chemistry or other means is required. The hydrogen plasma step removes surface oxides and As, which leaves a Ga-rich layer that the nitrogen plasma then turns to GaN. The formed GaN layer efficiently passivates the surface. The plasma-passivated GaAs shows upto 5 × room-temperature photoluminescence after 1 year, and room-temperature time-resolved photoluminescence demonstrates robust passivation even after 3 years, both comparisons to similarly aged unpassivated GaAs. Atomic force microscopy was used to confirm that the passivated surfaces can be made smooth enough for microelectronic applications. Grazing incidence x-ray diffraction indicated that the nitride films are amorphous, and energy-dispersive x-ray spectroscopy was used to estimate the nitrogen content. We used a common inductively coupled plasma reactive ion etching system for plasma passivation, thus enabling the rapid adoption of this technique. [ABSTRACT FROM AUTHOR]

Published

2023

28. Probing chiral discrimination in biological systems using atomic force microscopy: The role of van der Waals and exchange interactions.

Author

Kapon, Yael, Zhu, Qirong, Yochelis, Shira, Naaman, Ron, Gutierrez, Rafael, Cuniberti, Giannaurelio, Paltiel, Yossi, and Mujica, Vladimiro

Subjects

*BIOLOGICAL systems, *SPIN exchange, *INTERMOLECULAR forces, *ELECTRON spin, *SPIN-orbit interactions, *VAN der Waals forces, *ATOMIC force microscopy

Abstract

We analyze from a theoretical perspective recent experiments where chiral discrimination in biological systems was established using Atomic Force Microscopy (AFM). Even though intermolecular forces involved in AFM measurements have different origins, i.e., electrostatic, bonding, exchange, and multipole interactions, the key molecular forces involved in enantiospecific biorecognition are electronic spin exchange and van der Waals (vdW) dispersion forces, which are sensitive to spin–orbit interaction (SOI) and space-inversion symmetry breaking in chiral molecules. The vdW contribution to chiral discrimination emerges from the inclusion of SOI and spin fluctuations due to the chiral-induced selectivity effect, a result we have recently demonstrated theoretically. Considering these two enantiospecific contributions, we show that the AFM results regarding chiral recognition can be understood in terms of a simple physical model that describes the different adhesion forces associated with different electron spin polarization generated in the (DD), (LL), and (DL) enantiomeric pairs, as arising from the spin part of the exchange and vdW contributions. The model can successfully produce physically reasonable parameters accounting for the vdW and exchange interaction strength, accounting for the chiral discrimination effect. This fact has profound implications in biorecognition where the relevant intermolecular interactions in the intermediate-distance regime are clearly connected to vdW forces. [ABSTRACT FROM AUTHOR]

Published

2023

29. High electrical characteristics through graphene oxide doping process on physicochemically reformed inorganic thin films.

Author

Yang, Da-Bin, Oh, Jin Young, Choi, Bo-Kyeong, Lee, Dong Wook, Kim, Dong Hyun, and Seo, Dae-Shik

Subjects

*GRAPHENE oxide, *THIN films, *VAN der Waals forces, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *ELECTRO-optical effects

Abstract

This study investigated the improvement of the electro-optical properties of a liquid crystal (LC) cell fabricated through brush coating using graphene oxide (GO) doping. The physical deformation of the surface was analyzed using atomic force microscopy. The size of the groove increased as the GO dopant concentration increased, but the direction of the groove along the brush direction was maintained. X-ray photoelectron spectroscopy analysis confirmed that the number of C–C and O–Sn bonds increased as the GO concentration increased. Since the van der Waals force on the surface increases as the number of O–metal bonds increases, we were able to determine why the anchoring energy of the LC alignment layer increased. This was confirmed by residual DC voltage and anchoring energy measurements that were later performed. As the GO concentration increased, the width of the hysteresis curve decreased, indicating that the residual DC voltage decreased. Additionally, the 15% GO-doped sample exhibited a significant increase in its anchoring energy up to 1.34 × 10−3 J/m2, which is similar to that of rubbed polyimide. It also secured a high level of electro-optical properties and demonstrated potential as a next-generation thin-film display despite being produced via a simple brush-coating process. [ABSTRACT FROM AUTHOR]

Published

2023

30. Spontaneous pattern of orthogonal ferroelectric domains in epitaxial KNN films.

Author

Groppi, C., Maspero, F., Asa, M., Pavese, G., Rinaldi, C., Albisetti, E., Badillo-Avila, M., and Bertacco, R.

Subjects

*ATOMIC force microscopy, *STRONTIUM titanate, *THIN films, *EPITAXY, *STRAY currents, *ELECTRON microscopy

Abstract

Lead-free piezoelectric (K, Na)NbO3 (KNN) is considered one of the promising candidates for the replacement of Pb(ZrxTi1−x)O3. Several studies underlined the issue of K and Na volatility with increasing deposition temperatures, leading to high leakage currents in thin films, which still represents a major drawback for applications. This paper shows how epitaxial growth with concomitant preferred orientation of KNN films on niobium-doped strontium titanate (Nb:STO) depends on growth temperature and substrate strain. A preferred out-of-plane polar (001) orientation of KNN is obtained at high temperatures (>600 °C), while (100) orientation is dominant for lower ones. The (001) orientation is forced out-of-plane due to the sizeable in-plane stress derived from a negative lattice mismatch of pseudo-cubic KNN with respect to the underlying cubic (001) Nb:STO substrate. Moreover, we show that K-Na deficiency and high leakage of epitaxial KNN films deposited at high temperatures are accompanied by the appearance of a pattern of orthogonal spontaneous ferroelectric domains aligned to the [100] and [010] directions of Nb:STO. This pattern, visible in secondary electron microscopy, piezoforce response microscopy, and conductive atomic force microscopy images, is uncorrelated to the surface morphology. Supported by reciprocal space mapping by x-ray diffraction, this phenomenon is interpreted as the result of strain relaxation via ferroelectric domain formation related to K-Na deficient films displaying a sizable and increasing compressive strain when grown on Nb:SrTiO3. Our findings suggest that strain engineering strategies in thin films could be used to stabilize specific configurations of piezo- and ferroelectric domains. [ABSTRACT FROM AUTHOR]

Published

2023

31. Recombination activity of threading dislocations in MOVPE-grown AlN/Si {111} films etched by phosphoric acid.

Author

Pongrácz, Jakub, Vacek, Petr, and Gröger, Roman

Subjects

*TRANSMISSION electron microscopes, *ATOMIC force microscopy, *EPITAXY, *ELECTRON-hole recombination, *SECONDARY electron emission, *ETCHING, *ELECTRON beams

Abstract

Epitaxial growth of wurtzite AlN films on Si {111} results in 19% lattice misfit, which gives rise to a large density of threading dislocations with different recombination rates of electron–hole pairs. Here, we investigate types and distributions of threading dislocations of the MOVPE-grown 200 nm AlN/Si {111} film, whereby the dislocations are visualized using the technique of wet chemical etching. Atomic force microscopy suggests the existence of four different types of etch pits without any topological differences. Cross-sectional transmission electron microscope studies on etched samples are employed to associate the types of dislocations with the shapes of their etch pits. The recombination activity of individual dislocations was quantified by measuring the electron beam induced current and by correlative measurement of topography, secondary electron imaging, and the electron beam absorbed current. The strongest recombination activity was obtained for the m + c-type (mixed), c-type (screw), and a + c-type (mixed) threading dislocations, whereas the a-type (edge) threading dislocations were nearly recombination-inactive. [ABSTRACT FROM AUTHOR]

Published

2023

32. Fewer polymer chains but higher adhesion: How gradient-stiffness hydrogel layers mediate adhesion through network stretch.

Author

Hasan, Md Mahmudul and Dunn, Alison C.

Subjects

*POLYMER networks, *HYDROGELS, *NANOINDENTATION, *POLYOXYMETHYLENE, *POLYMERS, *MOLDING materials, *ATOMIC force microscopy

Abstract

The presence of gradient softer outer layers, commonly observed in biological systems (such as cartilage and ocular tissues), as well as synthetic crosslinked hydrogels, profoundly influences their interactions with opposing surfaces. Our prior research demonstrated that gradient-stiffness hydrogel layers, characterized by increasing elasticity with depth, control contact mechanics, particularly in proximity to the layer thickness. We postulate that the distribution of polymers within these gradient layers imparts extraordinary stretch and adhesion characteristics due to network adaptability and stress-induced reorganization. To investigate this phenomenon, we utilized Atomic Force Microscopy nanoindentation to assess the depth-dependent adhesion behavior of polyacrylamide hydrogels with varying gradient layer thicknesses. Two gradient layer thicknesses were achieved by employing different molding materials: glass and polyoxymethylene (POM). Glass-molded hydrogels exhibited a thinner gradient layer alongside a stiffer bulk layer compared to their POM-molded counterparts. In indentation experiments, the POM-molded hydrogel had larger adhesion compared to glass-molded hydrogel. We find that indenting within the gradient layer engenders increased load-unload hysteresis due to heightened fluid transport in the sparse outer polymer network. Consequently, this led to augmented adhesion and work of separation at shallow depths. We suggest that the prominent stretching capability of the sparse outer polymer network during probe retraction contributes to enhanced adhesion. The Maugis–Dugdale adhesive model only fits well to indentations on the thin layer or indentations which engage significantly with the bulk. These results facilitate a comprehensive characterization of adhesion mechanics in gradient-stiffness hydrogels, which could foster their application across emerging contexts in health science and environmental domains. [ABSTRACT FROM AUTHOR]

Published

2023

33. Influence of growth temperature on the properties of aluminum nitride thin films prepared by magnetron sputter epitaxy.

Author

Sundarapandian, Balasubramanian, Yassine, Ali, Kirste, Lutz, Baeumler, Martina, Straňák, Patrik, Fisslthaler, Evelin, Prescher, Mario, Yassine, Mohamed, Nair, Akash, Raghuwanshi, Mohit, and Ambacher, Oliver

Subjects

*ALUMINUM nitride films, *ACOUSTIC surface waves, *SCANNING transmission electron microscopy, *CRYSTAL texture, *SECONDARY ion mass spectrometry, *ATOMIC force microscopy, *MAGNETRON sputtering

Abstract

High quality, uni-polar, epitaxial AlN with minimum oxygen content promises excellent surface acoustic wave and bulk acoustic wave resonator characteristics such as high electromechanical coupling coefficient and power handling capabilities, which is particularly useful for RF filter applications. By systematically varying the growth temperature, the study investigates its impact on the oxygen levels, defect states, and crystallographic texture of the AlN thin films using a combination of atomic force microscopy, X-ray diffraction, time-of-flight secondary ion mass spectrometry, spectroscopic ellipsometry, scanning transmission electron microscopy, as well as room temperature and temperature dependent I–V measurements. The research demonstrates that the films grown at a temperature of 700 ° C exhibit the most favorable results. These films exhibit the lowest oxygen levels, possess epitaxial growth, and display the highest crystalline quality (XRD AlN 0002 ω − FWHM = 1.3 °). Additionally, these films demonstrate a significant reduction in sub-bandgap absorption. By comparing the cathode current measured during deposition, we suggest that the presence of an impurity layer formed during idle time between depositions as a possible source of oxygen in the sputter chamber. In addition, the study presents a possible model to explain the mixed polarity observed in AlN and proposes various ways to achieve uni-polar AlN on silicon substrates. [ABSTRACT FROM AUTHOR]

Published

2023

34. Electrochemical AFM/STM with a qPlus sensor: A versatile tool to study solid-liquid interfaces.

Author

Auer, Andrea, Eder, Bernhard, and Giessibl, Franz J.

Subjects

*SOLID-liquid interfaces, *SCANNING tunneling microscopy, *ATOMIC force microscopy, *ULTRAHIGH vacuum, *ELECTRIC batteries

Abstract

Atomic force microscopy (AFM) that can be simultaneously performed with scanning tunneling microscopy (STM) using metallic tips attached to self-sensing quartz cantilevers (qPlus sensors) has advanced the field of surface science by allowing for unprecedented spatial resolution under ultrahigh vacuum conditions. Performing simultaneous AFM and STM with atomic resolution in an electrochemical cell offers new possibilities to locally image both the vertical layering of the interfacial water and the lateral structure of the electrochemical interfaces. Here, a combined AFM/STM instrument realized with a qPlus sensor and a home-built potentiostat for electrochemical applications is presented. We demonstrate its potential by simultaneously imaging graphite with atomic resolution in acidic electrolytes. Additionally, we show its capability to precisely measure the interfacial solvent layering along the surface normal as a function of the applied potential. [ABSTRACT FROM AUTHOR]

Published

2023

35. High-density and high-uniformity InAs quantum nanowires on Si(111) substrates.

Author

Nakagawa, Ryusuke, Watanabe, Rikuta, Miyashita, Naoya, and Yamaguchi, Koichi

Subjects

*NANOWIRES, *SILICON nanowires, *MOLECULAR beam epitaxy, *ELECTRON beams, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *TRANSMISSION electron microscopy

Abstract

InAs nanowires (NWs) were grown on SiOx pinholes formed on Si(111) substrates by molecular beam epitaxy. Influences of electron-beam (EB) irradiation on the SiOx layer on the pinhole formation and the subsequent InAs NW growth were studied. As the EB irradiation dose increased, the pinhole density in the SiOx layer decreased. From atomic force microscopy, transmission electron microscopy, and x-ray photoelectron spectroscopy results, it was found that the pinhole etching of the SiOx layer by Ga droplets was suppressed by carbon adsorption due to the EB irradiation. By forming high-density pinholes on the SiOx layer without the EB irradiation, high-density InAs NWs with 1–2 × 1010 cm−2 were grown successfully, and the uniformity in the NW diameter improved. The standard deviation of the NW diameter was 1.8 nm (8.8%) for high-density NWs. In addition, the NW diameter decreased with decreasing EB dose, and the NW diameter was controlled by adjusting the diameter of Ga droplets forming the pinholes. As the NW diameter decreased, photoluminescence spectra of the NWs shifted to higher energies than the bandgap energy of the wurtzite InAs bulk. From these results, we successfully fabricated high-density and high-uniformity InAs NWs with quantum size effects on EB-unirradiated SiOx/Si(111). [ABSTRACT FROM AUTHOR]

Published

2023

36. Structural properties and epitaxial relation of cubic rock salt ScxAl1−xN/ScN/Si.

Author

Mihalic, S., Wade, E., Lüttich, C., Hörich, F., Sun, C., Fu, Z., Christian, B., Dadgar, A., Strittmatter, A., and Ambacher, O.

Subjects

*ROCK salt, *SCANNING force microscopy, *ATOMIC force microscopy, *ELECTRIC properties, *ZINC oxide films, *SCANNING electron microscopy, *MODULATION-doped field-effect transistors

Abstract

ScN in the rock salt structure is a well-investigated material due to its desirable properties like the high hardness or large thermal conductivity. Recent computations by Adamski et al. [Appl. Phys. Lett. 115, 232103 (2019)] showed that ScN/GaN heterostructures exhibit an outstanding polarization gradient which would be beneficial for polarization induced electron gases. The pseudobinary semiconductor Sc x Al 1 − x N, when maintaining the cubic rock salt structure, could be beneficial for tailoring the polarization gradient using the Sc dependency of material properties. The structural properties of rs-Sc x Al 1 − x N are not fully discovered yet, thus in this work, DC-magnetron sputtered cubic rock salt Sc x Al 1 − x N thin films with 0.55 < x < 1.00 were grown and analyzed on ScN(111)/Si(111). The epitaxial relation of ScN(111) thin films on the Si(111) substrate is determined to be ScN[110] ∥ Si[100]. Furthermore, concentration dependent properties like the lattice parameter of Sc x Al 1 − x N were measured [a(ScN) = 4.50 Å, a(Sc0.55Al0.45N) = 4.30 Å] and the stress σ within the layers was determined. The crystal quality was evaluated using ω -scans, revealing FWHM = 1.14 ° for Sc0.95Al0.05N. The diameters of the columns were determined by atomic force microscopy and scanning electron microscopy and they are range from 34 to 59 nm for 0.55 < x < 1.00. At x = 0.55 , Sc x Al 1 − x N columns in the hexagonal wurtzite as well as cubic rock salt structure were detected. This information about the structural specifications of Sc x Al 1 − x N in the rock salt structure forms the basis for further investigations and experimental confirmation of the electric properties of ScN/GaN heterostructures or even a Sc x Al 1 − x N/GaN based approach for improved structures for high-electron-mobility transistors. [ABSTRACT FROM AUTHOR]

Published

2023

37. Three-dimensional photoinduced force microscopy reveals artifacts from photothermal tip vibrations.

Author

Ritz, Christian, Lu, Bin, Theiler, Pius M., and Stemmer, Andreas

Subjects

*ATOMIC force microscopy, *MICROSCOPY, *GOLD nanoparticles, *DATA analysis

Abstract

Photoinduced force microscopy (PiFM) is a technique for nanoscale characterization of optically active materials. For correct data analysis, it is important to understand and recognize potential artifacts. In this study, we provide a Fourier-based framework for the different origins of the photoinduced force, including the photothermal motion of the atomic force microscopy (AFM) tip in PiFM measurements. We use individual gold nanoparticles as a model system to explore such tip-related phenomena and to demonstrate the benefits of three-dimensional analysis of the photoinduced force. Comparison of the in-phase heterodyne PiFM signal and the derivative of the tip–sample interaction, ∂ ⟨ k ts ⟩ / ∂ z c , directly reveals a photothermal origin for the PiFM signal in our experiments. Furthermore, we observe a lateral photothermal vibration of the tip apex induced by tip asymmetry. This lateral vibration emphasizes the importance of considering the motion of the AFM tip during data analysis. The improved lateral resolution conferred by ∂ ⟨ k ts ⟩ / ∂ z c can lead to misinterpretation. Our findings highlight that meticulous data analysis is required to ensure the correct interpretation of PiFM data. [ABSTRACT FROM AUTHOR]

Published

2023

38. Multiscale computational framework to investigate integrin mechanosensing and cell adhesion.

Author

Montes, Andre R., Gutierrez, Gabriela, Buganza Tepole, Adrian, and Mofrad, Mohammad R. K.

Subjects

*INTEGRINS, *CELL adhesion, *FLUORESCENCE resonance energy transfer, *MOLECULAR structure, *AMINO acid residues, *ATOMIC force microscopy

Abstract

Integrin mechanosensing plays an instrumental role in cell behavior, phenotype, and fate by transmitting mechanical signals that trigger downstream molecular and cellular changes. For instance, force transfer along key amino acid residues can mediate cell adhesion. Disrupting key binding sites within α 5 β 1 integrin's binding partner, fibronectin (FN) diminishes adhesive strength. While past studies have shown the importance of these residues in cell adhesion, the relationship between the dynamics of these residues and how integrin distributes force across the cell surface remains less explored. Here, we present a multiscale mechanical model to investigate the mechanical coupling between integrin nanoscale dynamics and whole-cell adhesion mechanics. Our framework leverages molecular dynamics simulations to investigate residues within α 5 β 1 -FN during stretching and the finite element method to visualize the whole-cell adhesion mechanics. The forces per integrin across the cell surface of the whole-cell model were consistent with past atomic force microscopy and Förster resonance energy transfer measurements from the literature. The molecular dynamics simulations also confirmed past studies that implicate two key sites within FN that maintain cell adhesion: the synergy site and arginine-glycine-aspartic acid (RGD) motif. Our study contributed to our understanding of molecular mechanisms by which these sites collaborate to mediate whole-cell integrin adhesion dynamics. Specifically, we showed how FN unfolding, residue binding/unbinding, and molecular structure contribute to α 5 β 1 -FN's nonlinear force–extension behavior during stretching. Our computational framework could be used to explain how the dynamics of key residues influence cell differentiation or how uniquely designed protein structures could dynamically limit the spread of metastatic cells. [ABSTRACT FROM AUTHOR]

Published

2023

39. Spin-dependent charge transmission through chiral 2T3N self-assembled monolayer on Au.

Author

Stefani, Andrea, Innocenti, Massimo, Giurlani, Walter, Calisi, Nicola, Pedio, Maddalena, Felici, Roberto, Favaretto, Laura, Melucci, Manuela, Zanardi, Chiara, Jones, Andrew C., Mishra, Suryakant, Zema, Nicola, and Fontanesi, Claudio

Subjects

*PHOTOELECTRON spectroscopy, *CIRCULAR dichroism, *ATOMIC force microscopy, *SPIN polarization, *CHARGE transfer, *CYCLIC voltammetry, *CHIRALITY of nuclear particles, *ETHANOL, *DIAMINES

Abstract

A gold surface is functionalized by chemisorption of the enantiopure N,N′-bis-[2,2′;5′,2″]tert-thiophene-5-yl methylcyclohexane-1,2-diamine (2T3N), a chiral oligothiophene derivative, via overnight incubation in a 2T3N ethanol solution. The Au|2T3N interface is characterized by x-ray photoelectron circular dichroism and comparing x-ray photoemission spectroscopy and electro-desorption results. Charge transmission at the Au|2T3N| solution interface is characterized by recording the cyclic voltammetry of the Fe(III)/Fe(II) reversible redox couple, finding a charge transfer rate constant, k°, variation from 1 × 10−1 to 3.3 × 10−2 cm s−1, when comparing the bare Au and the Au|2T3N interfaces, respectively. The "anomalous" high value of k° found for the chiral Au|2T3N interface can be rationalized on the basis of the chiral-induced spin selectivity effect, as further proved by magnetic–conductive atomic force microscopy measurements at room temperature. A spin polarization of about 30% is found. [ABSTRACT FROM AUTHOR]

Published

2023

40. Non-linear pH responses of passivated graphene-based field-effect transistors.

Author

Fuhr, Nicholas E., Azize, Mohamed, and Bishop, David J.

Subjects

*FIELD-effect transistors, *BORON nitride, *ATOMIC layer deposition, *ATOMIC force microscopy, *ATOMIC beams, *ALUMINUM oxide

Abstract

Graphene-based field-effect transistors (FETs) are suitable for pH sensors due to their outstanding surface chemical properties and its biocompatibility. To improve the devices' stability and pH sensitivity, different sets of dielectric passivation layers composed of monolayer hexagonal boron nitride with and without aluminum oxide layers were evaluated. Non-linearities of the pH response were observed. Heterostructure FETs were derived from subtractive manufacturing of commercially transferred two-dimensional materials on four-inch SiO2/Si wafers via stainless steel and polypropylene masking. Phosphate solutions (10 mM) of varying pH were incubated on bare devices, whereby liquid-gating elucidated linear changes in the Dirac voltage of hBN/graphene (−40 mV/pH) that was smaller than a device consisting only of monolayer graphene (−47 mV/pH). Graphene-based FETs were passivated with aluminum oxide nanofilms via electron beam or atomic layer deposition and were observed to have distinct Raman spectral properties and atomic force microscopy topologies corroborating the hypothesis that morphological differences of the deposited aluminum oxide influence the pH-dependent electrical properties. Atomic layer deposition of aluminum oxide on the 2D sensing areas resulted in non-linear shifting of the Dirac voltage with respect to pH that evolved as a function of deposition thickness and was distinct between graphene with and without hexagonal boron nitride as a capping monolayer. The non-linear response of varying thickness of AlxOy on graphene-based FETs was progressively reduced upon basic wet etching of the AlxOy. Overall, passivated graphene-based transistors exhibit deposition-dependent pH responses. [ABSTRACT FROM AUTHOR]

Published

2023

41. Oxidative aggregation of hemoglobin–a mechanism for low-temperature plasma-mediated wound healing.

Author

Oganesyan, Irina, Begley, Alina, Mrđenović, Dušan, Harrison, Julian A, and Zenobi, Renato

Subjects

*WOUND healing, *COLD atmospheric plasmas, *ERYTHROCYTES, *ION mobility spectroscopy, *GEL permeation chromatography, *ATOMIC force microscopy

Abstract

Plasma medicine is a field that utilizes reactive species generated from atmospheric low-temperature plasmas for applications such as sterilization, blood coagulation, and cancer therapy. Commercial plasma devices are available for wound healing, but research on the chemical modifications induced by these plasmas is scarce. This study explores the chemical modifications in hemoglobin when exposed to a helium plasma dielectric barrier discharge, with the aim of explaining the potential mechanisms through which it contributes to blood coagulation and enhances wound healing. Optical microscopy of cold atmospheric plasma (CAP) treated whole capillary blood showed an increase in red blood cell (RBC) size and the formation of rouleaux structures. The treatment of whole blood leads to hemolysis of RBCs and the release of intracellular protein content. We then treated purified hemoglobin protein at physiological concentrations, which led to the formation of aggregates that could be observed using ion mobility mass spectrometry (IM–MS), size exclusion chromatography, and optical microscopy. The aggregates formed fibril-like structures as observed using atomic force microscopy. The formation of hemoglobin aggregates is hypothesized to be the result of new intermolecular interactions formed following the CAP-mediated protein oxidation. We studied the changes to hemoglobin structure after treatment with a CAP using high-resolution MS and found that the hemoglobin subunits are oxidized with the addition of at least 4 oxygen atoms each. The intact tetrameric hemoglobin structure remains unchanged; however, the monomeric and dimeric proteins adopt a more compact structure, as observed by IM–MS. We propose that CAP treatment of fresh blood leads to hemolysis, and that the extracellular protein, primarily hemoglobin, is oxidized leading to the formation of aggregates. [ABSTRACT FROM AUTHOR]

Published

2024

42. Low-temperature plasma jet treatment generates reactive oxygen species in solution that leads to peptide oxidation and protein aggregation.

Author

Begley, Alina, Oganesyan, Irina, Mrđenović, Dušan, Smok, Izabela, Leitner, Alexander, and Zenobi, Renato

Subjects

*PEPTIDES, *PLASMA jets, *REACTIVE oxygen species, *GEL permeation chromatography, *ATOMIC force microscopy, *ION mobility spectroscopy, *AMINO acids

Abstract

Low-temperature plasma (LTP) jets are Food and Drug Administration (FDA)-approved medical devices to remove cancerous tissue and aid in wound healing. However, reports on their reaction with proteins are conflicting, ranging from fragmentation, oxidation, aggregation, or a combination thereof. In this study we bridge the gap between plasma-treatment of short peptides to proteins at physiologically relevant concentrations. The LTP in this study is based on a helium dielectric barrier discharge that forms a plasma-jet, which is directed at the solution without direct contact with the plasma, and results in the formation of reactive oxygen species (ROS) OH• and O2•− in solution. The longer the solution is treated, the more solution-phase ROS form. Treating peptide- and protein-containing solutions leads to extensive oxidation. The ROS led to the same oxidative modifications for peptide M with increasing chain length (9, 18, 37, 76 amino acids), which could be identified with high-resolution mass spectrometry. Oxidized species M + x O led to conformational changes such as compaction and elongation, while the unmodified peptide M remained unaltered, as found by ion mobility spectrometry and size exclusion chromatography. For proteins at high concentration, insoluble aggregates formed and could be identified by UV/V is light scattering and atomic force microscopy. The formation of aggregates is dependent on the amino acid chain length, the peptide concentration, and the time for aggregate formation. These findings highlight the importance of both peptide chain length and concentration in determining the fate of peptides following the exposure to LTP, while also offering valuable insights for the field of plasma medicine. [ABSTRACT FROM AUTHOR]

Published

2024

43. Raman spectroscopy of large extracellular vesicles derived from human microvascular endothelial cells to detect benzo[a]pyrene exposure.

Author

Raizada, Geetika, Brunel, Benjamin, Guillouzouic, Joan, Aubertin, Kelly, Shigeto, Shinsuke, Nishigaki, Yuka, Lesniewska, Eric, Le Ferrec, Eric, Boireau, Wilfrid, and Elie-Caille, Céline

Subjects

*RAMAN microscopy, *MOLECULAR spectroscopy, *SURFACE plasmon resonance, *EXTRACELLULAR vesicles, *ATOMIC force microscopy

Abstract

Extracellular vesicles (EVs) have shown great potential as biomarkers since they reflect the physio-pathological status of the producing cell. In the context of cytotoxicity, it has been found that exposing cells to toxicants leads to changes in protein expression and the cargo of the EVs they produce. Here, we studied large extracellular vesicles (lEVs) derived from human microvascular endothelial cells (HMEC-1) to detect the modifications induced by cell exposure to benzo[a]pyrene (B[a]P). We used a custom CaF2-based biochip which allowed hyphenated techniques of investigation: surface plasmon resonance imaging (SPRi) to monitor the adsorption of objects, atomic force microscopy (AFM) to characterise EVs' size and morphology, and Raman spectroscopy to detect molecular modifications. Results obtained on EVs by Raman microscopy and tip-enhanced Raman spectroscopy (TERS) showed significant differences induced by B[a]P in the high wavenumber region of Raman spectra (2800 to 3000 cm−1), corresponding mainly to lipid modifications. Two types of spectra were detected in the control sample. A support vector machine (SVM) model was trained on the pre-processed spectral data to differentiate between EVs from cells exposed or not to B[a]P at the spectrum level; this model could achieve a sensitivity of 88% and a specificity of 99.5%. Thus, this experimental setup facilitated the distinction between EVs originating from two cell culture conditions and enabled the discrimination of EV subsets within one cell culture condition. [ABSTRACT FROM AUTHOR]

Published

2024

44. Effect of in situ thermal treatment on ABS parts produced by fused deposition modeling (FDM).

Author

Nguyen, Khanh Q., Vuillaume, Pascal Y., Hu, Lei, Vachon, Andro, Diouf-Lewis, Audrey, Marcoux, Pier-Luc, Robert, Mathieu, and Elkoun, Saïd

Subjects

*RADIANT heating, *FUSED deposition modeling, *X-ray computed microtomography, *DYNAMIC mechanical analysis, *ATOMIC force microscopy

Abstract

Fused deposition modeling (FDM), an economical additive manufacturing (AM) technique, is widely used for extruding thermoplastic filaments. Acrylonitrile butadiene styrene (ABS) is a widely used polymer for FDM technique due to its inexpensive cost, strong impact strength, great durability, and intriguing uses. ABS materials are used for interior parts of automotive applications, drug-delivery systems, tracheal tubes, valves for ventilators, and medical masks. Nonetheless, shrinkage and warping are the primary weaknesses of ABS during the FDM process, affecting the dimensional stability of printed parts. In this context, a patent-pending radiant heating system has been developed to improve the overall performance of printed parts. This study aimed to evaluate the effect of in situ thermal treatment on the interlayer adhesion and mechanical properties of printed ABS parts. The thermal treatment was carried out on a radiant heating system at 240 °C and a printing speed of 35 mm·s−1. The physical and mechanical properties of ABS parts printed with and without radiant heating were then characterized. Various techniques, including tensile tests, X-ray microtomography (µ-CT), optical profilometry (OP), atomic force microscopy (AFM), and dynamic mechanical analysis (DMA), were conducted to investigate mechanical, microstructural, and topological properties of printed ABS parts. The results show that treated samples exhibit better interlayer adhesion than untreated ones. In addition, the treated samples had a lower porosity (1.6%) than the untreated samples (3%). Furthermore, the tensile strength, elastic modulus, and elongation at break of treated samples increased by 62%, 6%, and 110%, respectively, compared to untreated ones. [ABSTRACT FROM AUTHOR]

Published

2024

45. Electrochemical and imaging evaluations of electrochemically activated screen-printed gold electrodes.

Author

Zakaria, Nor Dyana, Salih, Ibrahim Luqman, Hamzah, Hairul Hisham, Sönmez, Turgut, Omar, Muhamad Huzaifah, Nor, Noorhashimah Mohamad, Razak, Khairunisak Abdul, and Balakrishnan, Venugopal

Subjects

*GOLD electrodes, *MASS transfer kinetics, *ATOMIC force microscopy, *SCANNING electron microscopy, *SURFACE conductivity

Abstract

Sulfuric acid is commonly used to electrochemically activate gold electrodes in a variety of electrochemical applications. This work provides the first evaluations of the electrochemical behaviors and a 3D image of an activated screen-printed gold electrode (SPGE, purchased commercially) through electrochemical and imaging analyses. The activated SPGE surface appears rougher than the unactivated SPGE surface when viewed through microtopography images using scanning electron microscopy (SEM) and atomic force microscopy (AFM). Nevertheless, the roughened microscopy structure does not exhibit any substantial changes in roughness factor for the activated SPGE, as indicated by capacitive current analyses. The significant improvement in electrochemical responsiveness of the activated SPGE is mainly attributed to the presence of surface pores created in the microscopic structure as a result of gold oxide layer formation. The presence of surface pores on the activated surface has significantly improved its conductivity by 10-fold. As a result, electron transfer kinetics and mass transports of the activated SPGE are greatly improved. The results presented in this work indicate that the surface of the activated SPGE greatly increased its intrinsic surface pores, and conductivity of the electrode surface and uncovered the electrocatalytic active sites. This significantly improves the activated SPGE's performance in electrochemical applications such as oxygen reduction reaction (ORR). An activated SPGE considerably enhanced limiting current density as well as ∼172 mV versus Ag shifted onset potential to more positive potentials compared to unactivated SPGE. [ABSTRACT FROM AUTHOR]

Published

2024

46. Production of recombinant human type I collagen homotrimers in CHO cells and their physicochemical and functional properties.

Author

Wang, Chuan, Guo, Xiaolei, Fan, Mingtao, Yue, Long, Wang, Hang, Wang, Jiadao, Zha, Zhengqi, and Yin, Hongping

Subjects

*ATOMIC force microscopy, *CHO cell, *TRANSMISSION electron microscopy, *AFFINITY chromatography, *MOLECULAR spectra, *COLLAGEN

Abstract

Collagen is the most abundant protein in human and mammalian structures and is a component of the mammalian extracellular matrix (ECM). Recombinant collagen is a suitable alternative to native collagen extracted from animal tissue for various biomaterials. However, due to the limitations of the expression system, most recombinant collagens are collagen fragments and lack triple helix structures. In this study, Chinese hamster ovary (CHO) cells were used to express the full-length human type I collagen α1 chain (rhCol1α1). Moreover, Endo180 affinity chromatography and pepsin were used to purify pepsin-soluble rhCol1α1 (PSC1). The amino acid composition of PSC1 was closer to that of native human type I collagen, and PSC1 contained 9.1 % hydroxyproline. Analysis of the CD spectra and molecular weight distribution results revealed that PSC1 forms a stable triple helix structure that is resistant to pepsin hydrolysis and has some tolerance to MMP1, MMP2 and MMP8 hydrolysis. Atomic force microscopy (AFM), transmission electron microscopy (TEM), and scanning electron microscopy (SEM) revealed that PSC1 can self-assemble into fibers at a concentration of 1 mg/ml; moreover, PSC1 can promote the proliferation and migration of NIH 3T3 cells. In conclusion, our data suggest that PSC1 is a highly similar type of recombinant collagen that may have applications in biomaterials and other medical fields. • CHO cells were used to express full-length human type I collagen α1 chain (rhCol1α1). • Endo180 affinity chromatography and pepsin were used to purify rhCol1α1. • PSC1 can self-assemble into larger fibers at the suitable concentration and temperature. • PSC1 have stable structure and can promote the proliferation and migration of NIH 3T3 cells. [ABSTRACT FROM AUTHOR]

Published

2024

47. Boosting corrosion resistance of Mg-Li alloy: Implanting bioinspired superhydrophobic surfaces into MAO matrix for enhanced protection.

Author

Ouyang, Yibo, Zhou, Zhihao, Guo, Enyu, Qiu, Ri, Chen, Zongning, Kang, Huijun, and Wang, Tongmin

Subjects

*SUPERHYDROPHOBIC surfaces, *ATOMIC force microscopy, *SALINE solutions, *ELECTROLYTIC corrosion, *SUBSTRATES (Materials science)

Abstract

The corrosion problem has significantly impeded the practical application of Mg-Li alloys. In this report, a method that combines micro-arc oxidation (MAO) with electrochemical deposition is developed to create a superhydrophobic matrix on Mg-Li substrate. The combination approach harnesses the superiority of both coverages, including MAO as the dense, firmly bonded ceramic oxide layer on the metal substrate and the superhydrophobic surface (SHS) implanted into MAO matrix. The MAO-SHS coating exhibits high mechanical stability, maintaining the superhydrophobicity due to the "implanting effect" even after a long distance of friction effect. For corrosion inhibition, compared to the bare Mg-Li with i corr of 9.26 × 10−5 A/cm2, the i corr for MAO and MAO-SHS is 7.83 × 10−6 A/cm2 and 7.50 × 10−9 A/cm2, respectively, representing the reduction of approximately one and four orders of magnitude. Focusing the atmospheric corrosion inhibition, MAO-SHS proves to manipulate the dynamic evolution of saline solution evaporation and salt particle deliquation. The salt particle crystalized from saline solution on MAO-SHS is found to have significantly smaller contact area than that of the bare Mg-Li and MAO. By employing atomic force microscopy, the adhesion force of salt particle is revealed as ca. 45 nN, 13 nN, and 2 nN for salt particle on Mg-Li, MAO, and MAO-SHS, respectively. This suggests that the salt can be more easily removed from the MAO-SHS surface, thereby reducing the susceptibility to corrosion. The in situ deliquation is conducted to understand the formation of the droplet on different surfaces. The air in the SHS layer hinders chloride ingress and the SHS layer seals the pores in MAO layer, proving the synergistic effect afforded by MAO-SHS to achieve superior corrosion resistance. [ABSTRACT FROM AUTHOR]

Published

2024

48. Synergizing empirical and AI methods to examine nano-silica's microscale contribution to epoxy coating corrosion resistance.

Author

Hussain, Zahoor, Lin, Zhibin, Pan, Hong, Huang, Ying, Tang, Fujian, and Jiang, Long

Subjects

*SALT spray testing, *ARTIFICIAL intelligence, *PROTECTIVE coatings, *ATOMIC force microscopy, *INFRASTRUCTURE (Economics), *EPOXY coatings

Abstract

Epoxy-nanomaterials offer a promising solution to combat corrosion threatening civil infrastructure. To examine the impact of nano silica on corrosion resistance, varying amounts of nano silica, ranging from 0.0 to 3 wt%, were introduced into the epoxy matrix. Mechanical properties were studied through studying the dog-bone tensile strength and tribological aspects were assessed through mass loss abrasion tests. Corrosion resistance performance was studied using electrochemical impedance spectroscopy (EIS) and salt spray tests. Nano structure of the coated specimens was studied after salt spray tests using SEM-EDX analysis. Micro Chromatography (M-Ct) technique was employed to investigate the pore formation in the epoxy matrix. Besides, atomic force microscopy (AFM) was introduced to study surface roughness. The test results displayed a notable improvement (5–10 %) in tensile strength upon the introduction of nano silica. Taber tester results showed a reduction in mass loss with the addition of nano silica. Electrochemical impedance spectroscopy (EIS) studies further established a significant increase in corrosion resistance, having an impedance of 12 GOhm.cm2 for epoxy matrix samples containing 2.5 % nano silica after a 768-h salt spray test. SEM-EDX analysis revealed the absence of iron content in the epoxy matrix reinforced with uniformly distributed nano silica. Surface roughness assessments illustrated that nanolaminates contributed to an increase in overall roughness, minimizing surface irregularities in the epoxy matrix. Micro-CT scanning results proposed a decrease in epoxy matrix porosity upon the addition of nano silica. AI based prediction model helped to understand the relationship between surface roughness and corrosion. In summary, the experimental findings suggest valuable insights for future advancements in the development of protective coatings for worldwide civil infrastructures. [ABSTRACT FROM AUTHOR]

Published

2024

49. Coral-inspired fabrication of Ag-Cu2O-zwitterionic polymers-phosphor films with day and night antifouling properties.

Author

Tang, Junxiao, Wang, Rongjie, Wang, Yanze, Fu, Qiang, Wei, Jingjiang, Zou, Ji, Wang, Weimin, Xie, Jingjing, Zeng, Hui, and Fu, Zhengyi

Subjects

*POLYZWITTERIONS, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *REACTIVE oxygen species, *CONTACT angle

Abstract

Inspired by the antifouling process observed in fluorescent corals, this study introduces a novel functional antifouling film consisting of Ag-Cu 2 O nanocomposites, zwitterionic polymers, and a phosphor substrate. Zwitterionic polymers serve as a dispersive medium for Ag-Cu 2 O nanocomposites, enabling a uniform coating and optimal structural through spin-coating. During daylight hours, visible light irradiation excites Ag-Cu 2 O nanocomposites to produce reactive oxygen species (ROS), which cooperates with the hydration layer, exhibit a high-level antifouling effect. Notably, the unique structural coating can emit a weak coral-like fluorescence at night, sustaining ROS release and further enhancing antifouling performance. The assembly structure of the composite film was studied by scanning electron microscopy (SEM), atomic force microscopy (AFM), X-ray photoelectron spectroscopy (XPS) and water contact angle (WCA), while its antifouling performance was evaluated through antibacterial tests and a 30-day light-dark cycle anti-algae attachment experiment. The distinct nighttime antifouling capability contributes to 97.30 % anti-algae settled rate over a 30-day diurnal cycle. Moreover, we also investigated the effect of phosphor color on the composite film's antifouling properties. The blue phosphor group exhibited greater antifouling performance than the green or transparent phosphor group. The composite film created with multiple synergistic mechanisms exhibited auspicious antifouling performance. Further improvement and development of this composite film could unlock even greater potential for its antifouling properties. [ABSTRACT FROM AUTHOR]

Published

2024

50. Influence of curing temperature on shape memory performance of polyethylenimine‐based shape memory polymer coated cotton fabric.

Author

Garg, Hema, Mohanty, Jayashree, Das, Apurba, Tripathi, Bijay P., and Kumar, Bipin

Subjects

ELECTROTEXTILES, COTTON textiles, ATOMIC force microscopy, SCANNING electron microscopy, COATED textiles, SHAPE memory polymers

Abstract

This research investigates the effect of curing temperature on the shape memory behavior and coating adhesion of polyethylenimine‐based shape memory polyurethane (PEI‐SMPU) to cotton fabric. The study utilized a dip‐coating process to apply a PEI‐SMPU solution to cotton fabrics, followed by curing at temperatures ranging from 100 to 160°C. Scanning electron microscopy confirmed uniform coating, and significant adhesion, and surface roughness was substantially reduced as evidenced by atomic force microscopy. The fabric's shape memory performance improved with increasing cure temperature, exhibiting excellent recovery (90%) at lower SMPU concentrations (1%). The results indicated that the tear strength of the fabric decreased with increasing curing temperature, attributed to constrained yarn mobility due to increased SMPU cross‐linking. The study successfully correlates the thermal and mechanical properties of SMPU‐coated fabrics with the interaction between SMPU and fabric, emphasizing the preservation of their laundering durability after multiple wash cycles. These findings contribute to the development of smart textiles with improved performance and longevity. [ABSTRACT FROM AUTHOR]

Published

2024