Curt A. Lavender scite author profile

Lightweighting of automobiles by use of novel low-cost, high strength-to-weight ratio structural materials can reduce the consumption of fossil fuels and in turn CO2 emission. Working towards this goal we achieved high strength in a low cost β-titanium alloy, Ti–1Al–8V–5Fe (Ti185), by hierarchical nanostructure consisting of homogenous distribution of micron-scale and nanoscale α-phase precipitates within the β-phase matrix. The sequence of phase transformation leading to this hierarchical nanostructure is explored using electron microscopy and atom probe tomography. Our results suggest that the high number density of nanoscale α-phase precipitates in the β-phase matrix is due to ω assisted nucleation of α resulting in high tensile strength, greater than any current commercial titanium alloy. Thus hierarchical nanostructured Ti185 serves as an excellent candidate for replacing costlier titanium alloys and other structural alloys for cost-effective lightweighting applications.

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Formation mechanism of gas bubble superlattice in UMo metal fuels: Phase-field modeling investigation

Hu¹,

Burkes²,

Lavender³

et al. 2016

Journal of Nuclear Materials

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Nano-gas bubble superlattices are often observed in irradiated UMo nuclear fuels. However, the formation mechanism of gas bubble superlattices is not well understood. A number of physical processes may affect the gas bubble nucleation and growth; hence, the morphology of gas bubble microstructures including size and spatial distributions. In this work, a phase-field model integrating a first-passage Monte Carlo method to investigate the formation mechanism of gas bubble superlattices was developed. Six physical processes are taken into account in the model: 1) heterogeneous generation of gas atoms, vacancies, and interstitials informed from atomistic simulations; 2) one-dimensional (1-D) migration of interstitials; 3) irradiation-induced dissolution of gas atoms; 4) recombination between vacancies and interstitials; 5) elastic interaction; and 6) heterogeneous nucleation of gas bubbles. We found that the elastic interaction doesn't cause the gas bubble alignment, and fast 1-D migration of interstitials along <110> directions in the body-centered cubic U matrix causes the gas bubble alignment along <110> directions. It implies that 1-D interstitial migration along [110] direction should be the primary mechanism of an fcc gas bubble superlattice which is observed in bcc UMo alloys. Simulations also show that fission rates, saturated gas concentration, and elastic interaction all affect the morphology of gas bubble microstructures.

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Magnesium alloy ZK60 tubing made by Shear Assisted Processing and Extrusion (ShAPE)

Whalen

Overman

Joshi

et al. 2019

Materials Science and Engineering: A

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Superplastic behavior in a commercial 5083 aluminum alloy

Vetrano

Lavender

Hamilton

et al. 1994

Scripta Metallurgica et Materialia

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Kinetics of cellular transformation and competing precipitation mechanisms during sub-eutectoid annealing of U10Mo alloys

Jana

Devaraj

Kovařík

et al. 2017

Journal of Alloys and Compounds

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Curt A. Lavender

A low-cost hierarchical nanostructured beta-titanium alloy with high strength

Formation mechanism of gas bubble superlattice in UMo metal fuels: Phase-field modeling investigation

Magnesium alloy ZK60 tubing made by Shear Assisted Processing and Extrusion (ShAPE)

Superplastic behavior in a commercial 5083 aluminum alloy

Kinetics of cellular transformation and competing precipitation mechanisms during sub-eutectoid annealing of U10Mo alloys

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