| Nov 02, 2020 |
Artificial intelligence helps to identify correct atomic structures
(Nanowerk News) Functional materials are commonly employed in emerging technologies, such as green energy solutions and new electronic devices. These materials are typically blends of different organic and inorganic components and have many advantageous properties for novel applications. To achieve their full potential, we need precise knowledge on their atomic structure.
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State-of-the-art experimental tools, such as atomic force microscopy (AFM), can be used to investigate organic molecular adsorbates on metallic surfaces. However, interpreting the actual structure from microscopy images is often difficult. Computational simulations can help to estimate the most probable structures, but with complex materials, accurate structure search is computationally intractable with conventional methods.
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Recently, CEST group has developed new tools for automated structure prediction using machine learning algorithms from computer science.
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In this most recent work (Beilstein Journal of Nanotechnology, "Detecting Stable Adsorbates of (1S)-camphor on Cu(111) with Bayesian Optimization"), they demonstrate the accuracy and efficiency of our own Bayesian Optimization Structure Search (BOSS) artificial intelligence method.
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| The stable structures of camphor on Cu(111) are identified in the minima of the 6D adsorption energy surface, which is modeled as a function of molecular orientation and translations. (Image courtesy of the researchers) (click on image to enlarge)
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With BOSS, the scientists identify the adsorbate configurations of a camphor molecule on a Cu(111) surface. This material has been previously studied with AFM, but inferring the structures from those images was inconclusive.
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Here, the team shows that BOSS can successfully identify not only the most probable structure, but also eight stable adsorbate configurations that camphor can have on Cu(111). They used these model structures to better interpret the AFM experiments and concluded that the images likely feature camphor which is chemically bound to the Cu surface via an oxygen atom.
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Analyzing single molecular adsorbates in this way is only the first step towards studying more complex assemblies of several molecules on surfaces and subsequently the formation of monolayers. The acquired insight on interface structures can help to optimize the functional properties of these materials.
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