FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4319943002> ?p ?o ?g. }

• W4319943002 endingPage "105222" @default.
• W4319943002 startingPage "105222" @default.
• W4319943002 abstract "The gap test is a new type of fracture test developed in 2020, in which the end supports of a notched beam are installed with gaps that close only after the elasto-plastic pads next to notch introduce a desired constant crack-parallel compression σxx (also called the T-stress). The test uses the size effect method to identify how such a compression alters the material fracture energy, Gf, and the characteristic size cf of the fracture process zone (FPZ). In 2020, experiments showed that a moderate σxx doubled the Gf of a quasibrittle material (concrete) and a high σxx reduced its Gf to almost zero. A preliminary study by Nguyen et al. (2021) showed that the gap test can be extended to plastic-hardening polycrystalline metals. A generalized scaling law with an intermediate asymptote for large-scale yielding in small structures was derived, and limited tests of aluminum alloy showed its applicability. In this study, geometrically scaled gap tests of notched three-point bend fracture specimens of aluminum are conducted at three different levels of σxx. An extended structural strength scaling law that captures the transition from the micrometer-scale FPZ through millimeter-scale yielding zone (YZ) to large-scale structures which follow linear elastic fracture mechanics (LEFM) is derived and then applied to analyze the effect of σxx. Presented here are the gap tests of aluminum alloy, in which three different levels of σxx are applied to scaled notched four-point-bend beams of depths D = 12, 24, 48 and 96 mm. Using an extended size effect law for plastic-hardening metals, it is found that, at crack-parallel stress σxx≈−40% of the yield strength, the critical J-integral value gets roughly quadrupled, not only because of the well-known enlargement of the hardening YZ whose width is of millimeter scale, but also because of the increase of the FPZ width of micrometer scale. These results can be reproduced neither by line crack models, including the LEFM, cohesive crack and phase-field models, nor by peridynamic and various nonlocal models that ignore the tensorial nature of the material stress at the crack tip. The crack band models, being able to represent an FPZ of finite width and a YZ whose size evolves depending on σxx, can capture the effect of crack-parallel stresses provided that a realistic 3D tensorial damage constitutive model is used. Here, Bai–Wierzbicki’s model is shown to capture the σxx effect on the Gf and Jcr qualitatively." @default.
• W4319943002 created "2023-02-11" @default.
• W4319943002 creator A5003025830 @default.
• W4319943002 creator A5012146826 @default.
• W4319943002 creator A5014441025 @default.
• W4319943002 creator A5067387241 @default.
• W4319943002 date "2023-04-01" @default.
• W4319943002 modified "2023-10-18" @default.
• W4319943002 title "Crack-parallel stress effect on fracture energy of plastic hardening polycrystalline metal identified from gap test scaling" @default.
• W4319943002 cites W1009370501 @default.
• W4319943002 cites W1202994963 @default.
• W4319943002 cites W1445910544 @default.
• W4319943002 cites W1652153263 @default.
• W4319943002 cites W1967234875 @default.
• W4319943002 cites W1970815311 @default.
• W4319943002 cites W1971788130 @default.
• W4319943002 cites W1973403390 @default.
• W4319943002 cites W1986114359 @default.
• W4319943002 cites W1988572929 @default.
• W4319943002 cites W1995331582 @default.
• W4319943002 cites W1995876195 @default.
• W4319943002 cites W1997574312 @default.
• W4319943002 cites W1999468163 @default.
• W4319943002 cites W2012740792 @default.
• W4319943002 cites W2014460414 @default.
• W4319943002 cites W2016153792 @default.
• W4319943002 cites W2016463190 @default.
• W4319943002 cites W2027188028 @default.
• W4319943002 cites W2031360112 @default.
• W4319943002 cites W2032768430 @default.
• W4319943002 cites W2033903726 @default.
• W4319943002 cites W2037052590 @default.
• W4319943002 cites W2047655099 @default.
• W4319943002 cites W2048598423 @default.
• W4319943002 cites W2051318805 @default.
• W4319943002 cites W2053079959 @default.
• W4319943002 cites W2057847351 @default.
• W4319943002 cites W2060451222 @default.
• W4319943002 cites W2060845444 @default.
• W4319943002 cites W2065163759 @default.
• W4319943002 cites W2066535285 @default.
• W4319943002 cites W2073008762 @default.
• W4319943002 cites W2073956129 @default.
• W4319943002 cites W2075739118 @default.
• W4319943002 cites W2079251494 @default.
• W4319943002 cites W2084464066 @default.
• W4319943002 cites W2084527378 @default.
• W4319943002 cites W2085260120 @default.
• W4319943002 cites W2086827153 @default.
• W4319943002 cites W2093503975 @default.
• W4319943002 cites W2094097457 @default.
• W4319943002 cites W2094138442 @default.
• W4319943002 cites W2124522426 @default.
• W4319943002 cites W2126960548 @default.
• W4319943002 cites W2129595801 @default.
• W4319943002 cites W2139237847 @default.
• W4319943002 cites W2146902691 @default.
• W4319943002 cites W2150314413 @default.
• W4319943002 cites W2163272368 @default.
• W4319943002 cites W2171476846 @default.
• W4319943002 cites W2213182079 @default.
• W4319943002 cites W2221771258 @default.
• W4319943002 cites W2290644883 @default.
• W4319943002 cites W2594093994 @default.
• W4319943002 cites W2606298429 @default.
• W4319943002 cites W2776289024 @default.
• W4319943002 cites W2805013140 @default.
• W4319943002 cites W2884325010 @default.
• W4319943002 cites W2903843825 @default.
• W4319943002 cites W2969059441 @default.
• W4319943002 cites W3024047905 @default.
• W4319943002 cites W3033000283 @default.
• W4319943002 cites W3096127060 @default.
• W4319943002 cites W3114600144 @default.
• W4319943002 cites W3214451934 @default.
• W4319943002 cites W341039984 @default.
• W4319943002 cites W4245358527 @default.
• W4319943002 doi "https://doi.org/10.1016/j.jmps.2023.105222" @default.
• W4319943002 hasPublicationYear "2023" @default.
• W4319943002 type Work @default.
• W4319943002 citedByCount "1" @default.
• W4319943002 countsByYear W43199430022023 @default.
• W4319943002 crossrefType "journal-article" @default.
• W4319943002 hasAuthorship W4319943002A5003025830 @default.
• W4319943002 hasAuthorship W4319943002A5012146826 @default.
• W4319943002 hasAuthorship W4319943002A5014441025 @default.
• W4319943002 hasAuthorship W4319943002A5067387241 @default.
• W4319943002 hasConcept C127413603 @default.
• W4319943002 hasConcept C137637335 @default.
• W4319943002 hasConcept C156413551 @default.
• W4319943002 hasConcept C159985019 @default.
• W4319943002 hasConcept C191897082 @default.
• W4319943002 hasConcept C192562407 @default.
• W4319943002 hasConcept C2524010 @default.
• W4319943002 hasConcept C2779227376 @default.
• W4319943002 hasConcept C33923547 @default.
• W4319943002 hasConcept C43369102 @default.
• W4319943002 hasConcept C44255700 @default.

• next