Scientists used environmental TEM to uncover the atomic-level secrets of how water vapor interacts with metals, leading to either corrosion or passivation. Their research offers insights into improving corrosion management and clean-energy solutions, with broad economic and environmental benefits. Credit: SciTechDaily.com
Groundbreaking research reveals new details about water vapor’s interaction with metals at an atomic level, with implications for corrosion management and clean-energy development.
When water vapor meets metal, the resulting corrosion can lead to mechanical problems that harm a machine’s performance. Through a process called passivation, it also can form a thin inert layer that acts as a barrier against further deterioration.
Either way, the exact chemical reaction is not well understood on an atomic level, but that is changing thanks to a technique called environmental transmission electron microscopy (TEM), which allows researchers to directly view molecules interacting on the tiniest possible scale.
Revolutionary Research in Atomic Reactions
Professor Guangwen Zhou — a faculty member at Binghamton University’s Thomas J. Watson College of Engineering and Applied Science — has been probing the secrets of atomic reactions since joining the Department of Mechanical Engineering in 2007. Along with collaborators from the University of Pittsburgh and the Brookhaven National Laboratory, he has studied the structural and functional properties of metals and the process of making “green” steel.
Their latest research, “Atomistic mechanisms of water vapor induced surface passivation,” was published recently in the journal Science Advances<em>Science Advances</em> is a peer-reviewed, open-access scientific journal that is published by the American Association for the Advancement of Science (AAAS). It was launched in 2015 and covers a wide range of topics in the natural sciences, including biology, chemistry, earth and environmental sciences, materials science, and physics.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]” tabindex=”0″ role=”link”>Science Advances. Co-authors included Binghamton PhD students Xiaobo Chen, Dongxiang Wu, Chaoran Li, Shuonan Ye and Shyam Bharatkumar Patel, MS ‘21; Na Cai, PhD ’12; Zhao Liu, PhD ’20; Weitao Shan, MS ’16, and Guofeng Wang from the University of Pittsburgh; and Sooyeon Hwang, Dmitri N. Zakharov and Jorge Anibal Boscoboinik from the Brookhaven National Laboratory.
A transmission electron microscopy image of the oxidized aluminum surface shows that the passivating oxide film formed in water vapor consists of an inner amorphous aluminum oxide layer and an outer crystalline aluminum hydroxide layer. Credit: Provided
In the paper, Zhou and his team introduced water vapor to clean aluminum samples and observed the surface reactions.
“This phenomenon is well-known because it happens in our daily lives,” he said. “But how do water molecules react with aluminum to form this passivation layer? If you look at the [research] literature, there’s not much work about how this happens at an atomic scale. If we want to use it for good, we must know, because then we will have some way to control it.”
They discovered something that had never been observed before: In addition to the aluminum hydroxide layer that formed on the surface, a second amorphous layer developed underneath it, which indicates there is a transport mechanism that diffuses oxygen into the substrate.
“Most corrosion studies focus on the growth of the passivation layer and how it slows down the corrosion process,” Zhou said. “To look at it from an atomic scale, we feel we can bridge the knowledge gap.”
Guangwen Zhou is a professor of mechanical engineering at the Watson College of Engineering and Applied Science. Credit: Jonathan Cohen
Economic and Environmental Impacts of Corrosion StudiesEconomic and Environmental Impacts of Corrosion Studies
The cost of repairing corrosion worldwide is estimated at $2.5 trillion a year, which is more than 3% of the global GDP — so developing better ways to manage oxidation would be an economic boon.
Additionally, understanding how a water molecule’s hydrogen and oxygen atoms break apart to interact with metals could lead to clean-energy solutions, which is why the U.S. Department of Energy funded this research and Zhou’s similar projects in the past.
“If you break water into oxygen and hydrogen, when you recombine it, it’s just water again,” he said. “It doesn’t have the contamination of fossil fuels, and it doesn’t produce carbon dioxide.”
Because of the clean-energy implications, the DOE regularly has renewed Zhou’s grant funding over the past 15 years.
“I greatly appreciate the long-term support for this research,” Zhou said. “It’s a very important issue for energy devices or energy systems, because you have a lot of metallic alloys that are used as structural material.”
Reference: “Atomistic mechanisms of water vapor–induced surface passivation” by Xiaobo Chen, Weitao Shan, Dongxiang Wu, Shyam Bharatkumar Patel, Na Cai, Chaoran Li, Shuonan Ye, Zhao Liu, Sooyeon Hwang, Dmitri N. Zakharov, Jorge Anibal Boscoboinik, Guofeng Wang and Guangwen Zhou, 1 November 2023, Science Advances.
DOI: 10.1126/sciadv.adh5565
Source: SciTechDaily
