Deformation and failure in extreme regimes by high-energy pulsed lasers: A review

Deformation and failure in extreme regimes by high-energy pulsed lasers: A review

The use of high-power pulsed lasers to probe the response of materials at pressures of hundreds of GPa up to several TPa, time durations of nanoseconds, and strain rates of 106–101°s−1 is revealing novel mechanisms of plastic deformation, phase transformations, and even amorphization. This unique ex...

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Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 688; no. C; pp. 429 - 458
Main Authors: Remington, Tane P., Remington, Bruce A., Hahn, Eric N., Meyers, Marc A.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 14-03-2017
Elsevier BV
Elsevier
Subjects:
Amorphization
Computer simulation
Deformation mechanisms
Diamonds
Dislocations
Experiments
Lasers
Materials science
Molecular dynamics
Phase transitions
Phonon drag
Plastic deformation
Pulsed lasers
Shock waves
Simulation
Strain rate
Tantalum
Twinning
Twins
Ultimate tensile strength
Shock waves
Twins
Lasers
Phase transitions
Dislocations
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Summary:The use of high-power pulsed lasers to probe the response of materials at pressures of hundreds of GPa up to several TPa, time durations of nanoseconds, and strain rates of 106–101°s−1 is revealing novel mechanisms of plastic deformation, phase transformations, and even amorphization. This unique experimental tool, aided by advanced diagnostics, analysis, and characterization, allows us to explore these new regimes that simulate those encountered in the interiors of planets. Fundamental Materials Science questions such as dislocation velocity regimes, the transition between thermally-activated and phonon drag regimes, the slip-twinning transition, the ultimate tensile strength of metals, the dislocation mechanisms of void growth are being answered through this powerful tool. In parallel with experiments, molecular dynamics simulations provide modeling and visualization at comparable strain rates (108–1010s−1) and time durations (hundreds of picoseconds). This powerful synergy is illustrated in our past and current work, using representative face-centered cubic (fcc) copper, body-centered cubic (bcc) tantalum and diamond cubic silicon as model structures.
Bibliography:USDOE
NA0002080; FG52-09NA29043; 09-LR-06–118456-MEYM
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2017.01.114