Machine Learning‐Enabled Correlation and Modeling of Multimodal Response of Thin Film to Environment on Macro and Nanoscale Using “Lab‐on‐a‐Crystal”

Muckley, Eric S.; Collins, Liam; Srijanto, Bernadeta; Ivanov, Ilia N.

doi:10.1002/adfm.201908010

Cited by 16 publications

(13 citation statements)

References 72 publications

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“…To ascertain the presence of water in these hydrophobic films (PS and P3HT), we utilized QCM and NR. QCM is a technique that can provide a qualitative understanding of both mass uptake and energy dissipation (change in stiffness) throughout the depth of a film with particular sensitivity towards the interface 53 , 54 . This is accomplished through tracking the response of multiple crystal harmonics ( n ), whereby low n harmonics correspond to regions closer to the film–water interface of interest and higher n harmonics probe the film–substrate interface.…”

Section: Resultsmentioning

confidence: 99%

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SMART transfer method to directly compare the mechanical response of water-supported and free-standing ultrathin polymeric films

et al. 2021

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Intrinsic mechanical properties of sub-100 nm thin films are markedly difficult to obtain, yet an ever-growing necessity for emerging fields such as soft organic electronics. To complicate matters, the interfacial contribution plays a major role in such thin films and is often unexplored despite supporting substrates being a main component in current metrologies. Here we present the shear motion assisted robust transfer technique for fabricating free-standing sub-100 nm films and measuring their inherent structural–mechanical properties. We compare these results to water-supported measurements, exploring two phenomena: 1) The influence of confinement on mechanics and 2) the role of water on the mechanical properties of hydrophobic films. Upon confinement, polystyrene films exhibit increased strain at failure, and reduced yield stress, while modulus is reduced only for the thinnest 19 nm film. Water measurements demonstrate subtle differences in mechanics which we elucidate using quartz crystal microbalance and neutron reflectometry.

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Section: Resultsmentioning

confidence: 99%

“…Gravimetric/viscoelastic response of films was measured, while the film was transferred from air and submerged in Milli-Q water, and then transferred back to air. Values of Δ f and Δ D were calculated by fitting QCM conductance peaks to a Lorentz distribution and extracting position and width 54 , 58 .…”

Section: Methodsmentioning

confidence: 99%

SMART transfer method to directly compare the mechanical response of water-supported and free-standing ultrathin polymeric films

et al. 2021

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“…These results confirmed the previous observations by PF-QNM using Young's modulus maps. Considering that PEDOT has a lower Y compared to PSS [54,60], the quantified softening of the nanospheres could be related to a different distribution of PEDOT and PSS in the resulting nanospheres after reprecipitation. This idea is in line with a possible re-arrangement of the PEDOT and PSS phases in confined geometries, as introduced in the last paragraph.…”

Section: Height Height Heightmentioning

confidence: 99%

Fabrication and Nanoscale Properties of PEDOT:PSS Conducting Polymer Nanospheres

Sanviti¹,

Alegría²,

Martínez-Tong

2021

Preprint

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<div><div><div><p>Electrically conducting nanospheres of poly-(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) with tailored size, were prepared by a one-step method. To fabricate the nanostructures, PEDOT:PSS was dissolved in ethylene glycol using a novel strategy and the solution was precipitated in deionized water. The proposed fabrication route allowed to obtain a water-based dispersion of monodisperse nanospheres with good optical properties. To determine physical properties of the nanospheres, we followed a nanoscale approach, using Atomic Force Microscopy (AFM). Our nanoscale mechanical and electrical investigations showed that the nanospheres preserved good physical properties, compared to the commercial product. Moreover, the local studies indicated that the confinement imposed by the spherical shape can lead into a different arrangement of the PSS and PEDOT phases. In particular, we envisaged nanospheres composed by a PEDOT-rich surface, responsible for the good electrical conductivity of the nanostructures.</p></div></div></div>

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“…To achieve higher conductivity, a number of new annealing methods, including repeated chemical treatments with strong acids, bases, and solvents, have been reported 23 . Informatic approaches have been partially introduced to predict the properties of PEDOT-PSS 24,25 . However, the post-treatment methods have become too long and complex to be analyzed by conventional machine learning approaches or to be understood except by a few specialists (example scheme is shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

Integrating multiple materials science projects in a single neural network

Hatakeyama‐Sato

Oyaizu

2020

Commun Mater

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In data-intensive science, machine learning plays a critical role in processing big data. However, the potential of machine learning has been limited in the field of materials science because of the difficulty in treating complex real-world information as a digital language. Here, we propose to use graph-shaped databases with a common format to describe almost any materials science experimental data digitally, including chemical structures, processes, properties, and natural languages. The graphs can express real world's data with little information loss. In our approach, a single neural network treats the versatile materials science data collected from over ten projects, whereas traditional approaches require individual models to be prepared to process each individual database and property. The multitask learning of miscellaneous factors increases the prediction accuracy of parameters synergistically by acquiring broad knowledge in the field. The integration is beneficial for developing general prediction models and for solving inverse problems in materials science.

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Machine Learning‐Enabled Correlation and Modeling of Multimodal Response of Thin Film to Environment on Macro and Nanoscale Using “Lab‐on‐a‐Crystal”

Cited by 16 publications

References 72 publications

SMART transfer method to directly compare the mechanical response of water-supported and free-standing ultrathin polymeric films

SMART transfer method to directly compare the mechanical response of water-supported and free-standing ultrathin polymeric films

Fabrication and Nanoscale Properties of PEDOT:PSS Conducting Polymer Nanospheres

Integrating multiple materials science projects in a single neural network

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