Exploring Metal Nanocluster Catalysts for Ammonia Synthesis Using Informatics Methods: A Concerted Effort of Bayesian Optimization, Swarm Intelligence, and First-Principles Computation

Tsuji, Yuta; Yoshioka, Yuta; Okazawa, Kazuki; Yoshizawa, Kazunari

doi:10.1021/acsomega.3c03456

Cited by 2 publications

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“…In many theoretical studies using periodic DFT, it is assumed that no interaction works between atoms more than 15 Å apart. 27 Therefore, it is unlikely that atoms in the silicon wafer in Figure 1c would affect the adhesion strength of the epoxy resin to the SAM surface. That is why we decided not to include the silicon wafer surface in our model for the DFT calculations.…”

Section: ■ Methodsmentioning

confidence: 99%

“…The thickness of the SAM made from undecyltrichlorosilane is estimated to be about 15 Å. In many theoretical studies using periodic DFT, it is assumed that no interaction works between atoms more than 15 Å apart . Therefore, it is unlikely that atoms in the silicon wafer in Figure c would affect the adhesion strength of the epoxy resin to the SAM surface.…”

Section: Methodsmentioning

confidence: 99%

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Molecular Understanding of the Distinction between Adhesive Failure and Cohesive Failure in Adhesive Bonds with Epoxy Resin Adhesives

Tsuji

2024

Langmuir

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In the development of adhesives, an understanding of the fracture behavior of the bonded joints is inevitable. Two typical failure modes are known: adhesive failure and cohesive failure. However, a molecular understanding of the cohesive failure process is not as advanced as that of the adhesive failure process. In this study, research was developed to establish a molecular understanding of cohesive failure using the example of a system in which epoxy resin is bonded to a hydroxyl-terminated self-assembled monolayer (SAM) surface. Adhesive failure was modeled as a process in which an epoxy molecule is pulled away from the SAM surface. Cohesive failure, on the other hand, was modeled as the process of an epoxy molecule separating from another epoxy molecule on the SAM surface or breaking of a covalent bond within the epoxy resin. The results of the simulations based on the models described above showed that the results of the calculations using the model of cohesive failure based on the breakdown of intermolecular interactions agreed well with the experimental results in the literature. Therefore, it was suggested that the cohesive failure of epoxy resin adhesives is most likely due to the breakdown of intermolecular interactions between adhesive molecules. We further analyzed the interactions at the adhesive failure and cohesive failure interfaces and found that the interactions at the cohesive failure interface are mainly accounted for by dispersion forces, whereas the interactions at the adhesive failure interface involve not only dispersion forces but also various chemical interactions, including hydrogen bonds. The selectivity between adhesive failure and cohesive failure was explained by the fact that varying the functional group density affected the chemical interactions but not the dispersion forces.

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Section: ■ Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%