2018-Sustainable Industrial Processing Summit
SIPS2018 Volume 5. Zehetbauer Intl. Symp. / SISAM

Editors:F. Kongoli, S. Kobe, M. Calin, J.-M. Dubois, T. Turna
Publisher:Flogen Star OUTREACH
Publication Year:2018
Pages:154 pages
ISBN:978-1-987820-90-4
ISSN:2291-1227 (Metals and Materials Processing in a Clean Environment Series)
CD-SIPS2018_Volume1
CD shopping page

    Effect of Hydrogen on Generation of Lattice Defects and Defect Hardening of Plastically Deformed Palladium

    Yuzeng Chen1; Daria Setman2; Jakub Cizek3; Christine Borchers4; Reiner Kirchheim5; Martin Deutges6;
    1NORTHWESTERN POLYTECHNIC UNIVERSITY, Xi'an, China; 2UNIVERSITY OF VIENNA, Vienna, Austria; 3CHARLES UNIVERSITY IN PRAGUE, Prague, Czech Republic; 4UNIVERSITäT GöTTINGEN, Goettingen, Germany; 5UNIVERSITäT GöTTINGEN, 37077 Goettingen, Germany; 6UNIVERSITäT GöTTINGEN, Göttingen, Germany;
    Type of Paper: Invited
    Id Paper: 312
    Topic: 42

    Abstract:

    Palladium-hydrogen system is widely used as a model system for investigating behaviors of hydrogen in metals. In this work, we applied different ways of loading on palladium-hydrogen alloys to investigate the effect of hydrogen on generation of lattice defects in palladium subjected to plastic deformation. In cold-rolled palladium-hydrogen alloys, it is shown that hydrogen solute significantly enhances the multiplication of dislocations during deformation, which will give rise to dislocation densities in the cold-rolled metals and results in hardening of the metals. Under the severely plastic deformation condition, the hydrogen solute is found to increase both the densities of deformation induced vacancy agglomerates and of dislocations, while the former also contribute significantly to hardening of the metals. When the alloys are subjected to ultra-fast loading (strain rate up to 10<sup>3</sup> s<sup>-1</sup>) exerted by a Split-Hopkinson apparatus, the addition of hydrogen leads to the increase in vacancy concentration and dislocation density, too. In this case, the increase in dislocation density is believed to play a major role in hardening palladium.

    Keywords:

    Alloys; H2 Storage; Severe Plastic Deformation (SPD);

    References:

    [1] Y.Z. Chen, X.Y. Ma, X.H. Shi, T. Suo, C. Borchers, K.H. Zhang, F. Liu, R. Kirchheim. Hardening effects in plastically deformed Pd with the addition of Hi. Scripta Materialia. 2015. 98. 48-51
    [2] M. Deutges, H.P. Barth, Y.Z. Chen, C. Borchers, R. Kirchheim, Hydrogen diffusivities as a measure of relative dislocation densities in palladium and increase of the density by plastic deformation in the presence of dissolved hydrogen, Acta Materialia 82 (2015) 266-274.
    [3] Y.Z. Chen, H. P. Barth, M. Deutges, C. Borchers, F. Liu, R. Kirchheim*. Increase in dislocation density in cold-deformed Pd using H as a temporary alloying addition. Scripta Materialia. 2013, 68(9): 743-746
    [4] Melikhova, O.,Cizek, J., Chen, Y.Z., Suo, T., Prochazka, I., Liu, F, Effect of hydrogen on generation of lattice defects in shock-loaded Pd, Journal of Alloys and Compounds, 2015, Vol. 645: S472-S475

    Cite this article as:

    Chen Y, Setman D, Cizek J, Borchers C, Kirchheim R, Deutges M. (2018). Effect of Hydrogen on Generation of Lattice Defects and Defect Hardening of Plastically Deformed Palladium. In F. Kongoli, S. Kobe, M. Calin, J.-M. Dubois, T. Turna (Eds.), Sustainable Industrial Processing Summit SIPS2018 Volume 5. Zehetbauer Intl. Symp. / SISAM (pp. 73-74). Montreal, Canada: FLOGEN Star Outreach