The eventual failure of metals, such as the aluminum in ships and airplanes, can often be blamed on breaks, or voids, in the material’s atomic lattice. They’re at first invisible, only microns in size, but once enough of them link up, the metal eventually splits apart.
- Medicine - May 23
The art of holistic health care - Literature - May 23 Stanford scholar sheds light on Greek immigrant’s rags-to- riches story
- Medicine - May 23 How the EU could help more children survive cancer
- Medicine - May 23 Key vildagliptin data in The Lancet show for the first time individualized HbA1c treatment goals can be reached in elderly type 2 diabetes patients with no major tolerability issues
- Medicine - May 23 Smart drugs - smart decisions?
- Medicine - May 23 Breakthrough on Huntington’s disease
- Medicine - May 23
Depression raises diabetics’ risk of severe low blood sugar episodes - Environmental Sciences - May 23 World’s top scientists: California & nations must act now on environment
- Business - May 23 Software Assurance Marketplace to host exposition
- Medicine - May 23 Can you put a price on health?
- Medicine - May 23 New hope for treating persistent anorexia treatment
- Life Sciences - May 22 The Norway spruce genome sequenced
- Medicine - May 22 Key find for early bladder cancer treatment
- Astronomy - May 22 Watching for hazards: ESA opens asteroid centre
- Environmental Sciences - May 22 GPS, camera traps and dung expose the secret life of endangered elephants
Researchers provide new insight into how metals fail
23 January 2012
Related Stories
Cornell engineers, trying to better understand this process, have discovered that nanoscale voids behave differently than the larger ones that are hundreds of thousands of atoms in scale, studied through traditional physics. This insight could lead to improved ability to predict how cracks grow in metals, and how to engineer better materials.
Graduate student Linh Nguyen and Derek Warner, assistant professor of civil and environmental engineering, reported their findings in the journal Physical Review Letters, Jan. 20. Using new atomistic simulation techniques, they concluded that the smallest voids in these materials, those having nanometer dimensions, don’t contribute in the same way as microscale voids do in material failure at ordinary room temperatures and pressures.
When metals fail, a physical phenomenon known as plasticity often occurs, permanently deforming, or changing the shape of the material. Previously, it was theorized that both nanometer and microscale voids grow via plasticity as the material fails, but the new research says otherwise.
"While this was something amenable to study with traditional atomistic modeling approaches, the interpretation of previous results was difficult due to a longstanding challenge of time scaling," Warner said. "We’ve come up with a technique to better address that.
Last job offers
- Social Sciences - 23.5
Dozentin / Dozenten und Projektleiterin / Projektleiter mit Schwerpunkt Theorie und Methodik der Sozialarbeit... - Business - 22.5
Wissenschaftliche Mitarbeitende / Doktorandinnen & Doktoranden (50-100%) - Business - 22.5
Senior wissenschaftliche Mitarbeitende / Dozierende (70-100%) - Medicine - 21.5
Professeur-e ordinaire ou associé-e et responsable de l’Unité de neurochirurgie pédiatrique - Arts - 21.5
SNF-Doktorand/in (50%) - Arts - 21.5
Wissenschaftliche/r Mitarbeiter/in (50%) - Pedagogy - 23.5
Senior Lecturer / associate Professor - Associate Director of Teaching and Learning - Administration - 23.5
Research Support Officer - Business - 23.5
Professur für Volkswirtschaftslehre - Media Sciences - 23.5
Professur für Medieninformatik - History - 23.5
Professor of Modern Political Thought and Ethics - Event - 23.5
Distinction awards for non clinical professors and readers - Medicine - 23.5
Medical Oncology - Assistant, Associate, or Full Professor WOT (AA3464) - Media Sciences - 23.5
Political Science - Assistant or Associate Professor (AA3462)
» Share this page: