Journal Club for January 2019: Nanoprecipitation strengthening in high entropy alloys
Nanoprecipitation strengthening in high entropy alloys
Xiaoyan Li, Jianguo Li
Center for Advanced Mechanics and Materials, Applied Mechanics Laboratory, Department of Engineering Mechanics, Tsinghua University, Beijing 100084, China
Introduction
ParaDis : Discrete Dislocation Dynamics Simulation
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2018 Timoshenko Medal Acceptance Lecture: Academic Family, by Prof. Ares Rosakis
The 2018 Timoshenko Medal Acceptance Speech: Academic Family, by Prof. Ares Rosakis of California Institute of Technology, was just published in Journal of Applied Mechanics. The article is attached.
Stress update scheme in platicity
Hi everybody,
I am studying the plastic deformation of sheet metal. Recently, I study about stress update scheme in finite element analysis using return mapping method. For this problem, we can calculate the increment of stress components, Δσ for a given value of strain components Δε using elastic predictor - plastic correct scheme. Since Δε = Δεe +Δεp, first, we assume Δεp=0 and check the yield criterion. Then, we find Δεp to satisfy the yield criterion as well as the consistent condition.
However, I have a question as the follows
Tailoring porous media for controllable capillary flow
Liu, M., Suo, S., Wu, J., Gan, Y., Hanaor, D. A. H., & Chen, C. Q. Journal of Colloid and Interface Science, 2019, 539: 379-387. https://www.sciencedirect.com/science/article/pii/S0021979718315108#f00…
Hypothesis
Interface-Governed Deformation of Nanobubbles and Nanotents Formed by Two-Dimensional Materials
In this paper, we experimentally characterize a simple and unified power law for the profiles of a variety of nanobubbles and nanotents formed by 2D materials such as graphene and MoS2 layers. https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.121.266101
ABSTRACT
Optimal-Feedback Accelerated Picard Iteration Method and a Fish-Scale Growing Method for Wide-Ranging and Multi-Revolution Perturbed Lambert's Problems
Wide-ranging and multiple-revolution perturbed Lambert’s problems are building blocks for practical missions such as development of cislunar space, interplanetary navigation, orbital rendezvous, etc. However, it is of a great challenge to solve these problems both accurately and efficiently, considering the long transfer time and the complexity of high-fidelity modeling of space environment. For that, a methodology combining Optimal-Feedback Accelerated Picard Iteration methods and Fish-Scale Growing Method is demonstrated.
PDF position in Elastomers @ York University, Toronto, Canada
Vacancy exists for high calibre one postdoctoral fellow to join the Innovative Design and Engineering Analysis Laboratory at York University, starting immediately.
The position’s primary area of research will focus on characterization and modelling of elastomers subject to high strain rates.