References
- CortellinoF. HydeT. H. SunW. PappalettereC. : ‘Finite element calculation of contour integral parameters for a cracked P91 pipe weld’, Mater. Res. Innov., 2013, 17, (5), 300–305.
- YaghiA. H. HydeT. H. BeckerA. A. SunW. : ‘Finite element simulation of welding residual stresses in martensitic steel pipes’, Mater. Res. Innov., 2013, 17, (5), 306–311.
- BrettS. J. MitchellK. C. : ‘Weld repair of grade 91 steel without post-weld heat treatment’, Mater. Res. Innov., 2013, 17, (5), 312–317.
- ZhouH. MehmanparastA. DaviesC. M. NikbinK. M. : ‘Evaluation of fracture mechanics parameters for bi-material compact tension specimens’, Mater. Res. Innov., 2013, 17, (5), 318–322.
- HarrisonW. J. WhittakerM. T. DeenC. : ‘Creep behaviour of Waspaloy under non-constant stress and temperature’, Mater. Res. Innov., 2013, 17, (5), 323–326.
- EhrhardtF. HoldsworthS. R. KühnI. MazzaE. : ‘Creep–fatigue crack development in dissimilar metal welded joints between steels and a nickel base alloy’, Mater. Res. Innov., 2013, 17, (5), 327–331.
- KimK.-C. MaY.-W. KongB.-O. KimM.-S. KangS.-T. : ‘Effect of strain rate on low cycle fatigue with hold time in 9Cr rotor steel’, Mater. Res. Innov., 2013, 17, (5), 332–336.
- GorashY. ChenH. : ‘Application of the linear matching method to creep-fatigue failure analysis of cruciform weldment manufactured of the austenitic steel AISI type 316N(L)’, Mater. Res. Innov., 2013, 17, (5), 337–343.
- DeanD. W. AllportL. : ‘Difficulties in interpreting data from creep crack growth tests on type 316H weldments’, Mater. Res. Innov., 2013, 17, (5), 344–349.
- SandströmR. ÖstlingH. JinL.-Z. : ‘Modelling of creep in friction stir welded copper’, Mater. Res. Innov., 2013, 17, (5), 350–354.
- SandströmR. FarooqM. ZurekJ. : ‘Basic models for creep deformation in stainless steels’, Mater. Res. Innov., 2013, 17, (5), 355–359.