Argonne scientists discover networks of metal nanoparticles are culprits in alloy corrosion
Oxide scales are supposed to protect alloys from extensive corrosion, but scientists at U.S. Department of Energy's Argonne National Laboratory have discovered metal nanoparticle chinks in this armor. Oxide scales develop on the outer surface of alloys at high temperatures creating a protective barrier that keeps destructive carbon-bearing molecules from slipping into the alloy. The diffusion of carbon into oxide scales should be negligible, but studies have shown that carbon can sneak through the oxide line of defense leading to brittleness and corrosion.
"The United States loses four percent of the gross national product due to alloy corrosion," Argonne Distinguished Fellow Ken Natesan said. "A network of continuous metal nanoparticles allow the carbon to dissolve and diffuse through the protective oxide scales without the need of a crack or a pore."
It was commonly believed that carbon-containing molecules escaped into cracks or pores in the oxide scales, but using three separate techniques -- nanobeam x-ray analysis at the Advanced Photon Source, magnetic force microscopy at the Center for Nanoscale Materials and scanning electron microscopy at the Electron Microscopy Center -- Natesan, along with Argonne scientists Zuotao Zeng, Seth Darling and Zhonghou Cai, discovered networks of iron and nickel nanoparticles embedded within the oxide scales.
Carbon can easily diffuse through the metals and create a path for carbon atom transport which does not involve defects in the scale.
"By examining the oxide scale, we find the metal nanoparticles," Zeng said. "If they are eliminated we can create a more corrosion-resistant and longer lasting alloy."
Based on the study, ANL has developed laboratory size batches of materials that exhibit as much as ten times longer life than commercial alloys with similar chromium contents, Natesan said. At present, 50-lb batches of the alloys have been cast successfully by an alloy manufacturer and will be commercialized in due course. The ANL-developed alloys are of considerable interest to the chemical, petrochemical, and refining industry.
The findings might also have broad influence on not only metal dusting and carburization, but also in other research areas such as alloy development and surface coatings for high-temperature fuel cell applications.
Source: DOE/Argonne National Laboratory
- Argonne scientists reveal secret of nanoparticle crystallization in real timeMon, 17 May 2010, 16:55:47 EDT
- The nanoscale secret to stronger alloysSun, 7 Aug 2011, 15:32:55 EDT
- Metal-organic frameworks feel the pressure of Argonne scientistsThu, 25 Sep 2008, 14:08:26 EDT
- Argonne scientists uncover a photosynthetic puzzleFri, 25 May 2012, 15:33:39 EDT
- Under pressure, atoms make unlikely alloysWed, 11 Mar 2009, 11:32:47 EDT
- Scientists discover networks of metal nanoparticles are culprits in alloy corrosionfrom PhysorgMon, 4 Aug 2008, 14:42:18 EDT
- Researchers discover networks of metal nanoparticles are culprits in alloy corrosionfrom Science CentricMon, 4 Aug 2008, 13:49:04 EDT
- Scientists Discover Networks of Metal Nanoparticles Are Culprits in Alloy Corrosionfrom Newswise - ScinewsMon, 4 Aug 2008, 13:35:22 EDT
- Networks Of Metal Nanoparticles Are Culprits In Alloy Corrosionfrom Science DailyMon, 4 Aug 2008, 13:35:08 EDT
Latest Science NewsletterGet the latest and most popular science news articles of the week in your Inbox! It's free!
Learn more about
Check out our next project, Biology.Net
From other science news sites
Popular science news articles
No popular news yet
No popular news yet
- Stem cell transplant restores memory, learning in mice
- 2 landmark studies report on success of using image-guided brachytherapy to treat cervical cancer
- Researchers discover mushrooms can provide as much vitamin D as supplements
- Cutting back on sleep harms blood vessel function and breathing control
- Study: Low-dose aspirin stymies proliferation of 2 breast cancer lines