This is the same as going from having potential energy to having none! Thus the system will see no motion, and you won't be able to provoke it unless you added more energy. If you think of a closed system, as points with different pressures, they will eventually diffuse into a equilibrium with a single pressure over all points. Does this made the things clearer (the message had high entropy to receive.) or more ambiguous (the message had low entropy to receive).Ĭould you do a definition from the information theory point of view? that would be cool. When thinking about this you have to take into account whether you are talking about the sender or the receiver of the message.įor example, let's say the sender sends the message with lots of information (high entropy from sender's point of view). Higher entropy means the message contain more information and vice versa. when we add more energy to the system it gets more chaotic.įrom an information theory point of view, "entropy" is how much information the message contains. Higher entropy means less chaos (energy in the system has dissipated, we are close to the death of the universe, close to equilibrium). Looking ahead, the group hopes to expand this platform into practical electrocatalysis by using Pt-HEA-nanoparticles that seek to increase electrochemical surface areas.No the opposite. The platform is applicable not only to electrocatalysis but also in various fields of functional nanomaterials." It is valid for clarifying the precise correlations among the atomic-level, surface microstructure and electrocatalytic properties of HEAs of any constituent elements and ratios and, thus, would provide reliable training datasets for materials informatics. "Our newly constructed experimental study platform provides us with a powerful tool to elucidate the detailed relationship between multi-component alloy surface microstructures and their catalytic properties. Wadayama and his group stress the wide applicability of their findings, both for any constituent elements and to other nanomaterials. This indicates that the atomic arrangement and distribution of elements near the surface, which creates a 'pseudo-core-shell-like structure,' contributes to the excellent catalytic properties of Pt-HEAs. They discovered that the Pt-HEAs' surfaces performed better in ORR compared to surfaces made of a platinum-cobalt alloy. Using advanced imaging techniques, the group examined the atomic-level structure of the Pt-HEAs' surfaces and studied their ORR properties. "This produced a model surface for studying a specific reaction called the oxygen reduction reaction (ORR)." "In our study we made thin layers of an alloy called a Cantor alloy, which contains a mix of elements (Cr-Mn-Fe-Co-Ni), on platinum (Pt) substrates," explains Toshimasa Wadayama, co-author of the paper and a professor at Tohoku University's Graduate School of Environmental Studies. Their breakthrough was reported in the journal Nature Communications on July 26, 2023. Now, a collaborative research team has created a new experimental platform that enables the control of the atomic-level structure of HEAs' surfaces and the ability to test their catalytic properties. Hence why researchers are seeking to understand the correlation between the atomic arrangement and the catalytic properties exhibited by HEAs. But unravelling this complexity is crucial, since the surface properties of materials often dictate their catalytic activity. Because they are made up of differing constituent elements, HEAs' atomic-level surface designs can be complex.
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