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Philosophical Magazine A Volume 77, 1998 - Issue 4
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Original Articles

The effective threshold of fatigue crack propagation in aluminium alloys. I. The influence of yield stress and chemical composition

Reinhard Pippan Erich-Schmid-Institut für Festkörperphysik der Österreichischen Akademie der Wissenschaften, A-8700 Leoben, Austria
Pages 861-873 | Received 04 Mar 1997, Accepted 18 Jul 1997, Published online: 12 Aug 2009

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H P Shinde, Nikhil Sonawane, M G Karnik & Prashant Kumar. (2023) Effect of patch length and elevated temperature on fatigue behaviour of repaired aluminium panels with a CFRP patch. The Journal of Adhesion 99:10, pages 1678-1694.
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Articles from other publishers (39)

Ilaria Roveda, Itziar Serrano-Munoz, Jan Haubrich, Guillermo Requena & Mauro Madia. (2023) Influence of post-process heat treatments on the fatigue crack propagation behaviour of a PBF-LB/M AlSi10Mg alloy. International Journal of Fatigue 175, pages 107808.
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Matthias Oberreiter, Michael Horvath, Michael Stoschka & Stefan Fladischer. (2023) Effect of Surface Finishing State on Fatigue Strength of Cast Aluminium and Steel Alloys. Materials 16:13, pages 4755.
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Rohan N. Taware, Prakash S. Shinde & Prashant Kumar. (2023) Fatigue performance of edge cracked aluminium alloy repaired with asymmetrical CFRP patches. Materials Today: Proceedings 72, pages 1110-1116.
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Arthur Lintner, Reinhard Pippan, Martin Schloffer & Anton Hohenwarter. (2022) Effect of a single overload on the cyclic R-curve behaviour of a γ-TiAl TNM alloy. International Journal of Fatigue 163, pages 107083.
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H. P. Shinde, P. Kumar, M. G. Karnik & S. D. Shinde. (2022) Suitable CFRP Patches to Arrest Crack Growth in Thin Alloy Aluminium Panels. Journal of The Institution of Engineers (India): Series C 103:5, pages 1243-1249.
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Kebin Alberto Medina Bernal & Libardo Vicente Vanegas Useche. (2022) Sobre la determinación del umbral del rango del factor de intensidad de tensiones y los factores que lo afectan. Ingeniería 27:3, pages e18453.
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Mingjie Zhao, Wenjia Gu & Derek H. Warner. (2022) Atomic mechanism of near threshold fatigue crack growth in vacuum. Nature Communications 13:1.
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Wenjia Gu & Derek H. Warner. (2021) Dissolution at a Ductile Crack Tip. Physical Review Letters 127:14.
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Kunio Hasegawa, David Dvořák, Vratislav Mareš, Bohumir Strnadel & Saburo Usami. (2021) Suitability of fatigue crack growth thresholds at negative stress ratios for ferritic steels and aluminum alloys in flaw evaluation procedures. Engineering Fracture Mechanics 248, pages 107670.
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D. Görzen, H. Schwich, B. Blinn, W. Song, U. Krupp, W. Bleck & T. Beck. (2021) Influence of Cu precipitates and C content on the defect tolerance of steels. International Journal of Fatigue 144, pages 106042.
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M. Oberreiter, R. Aigner, S. Pomberger, M. Leitner & M. Stoschka. (2021) Impact of microstructural properties on the crack threshold of aluminium castings. Engineering Fracture Mechanics 241, pages 107431.
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I. Serrano-Munoz, D. Shiozawa, S. Dancette, C. Verdu & J.-Y. Buffiere. (2020) Torsional fatigue mechanisms of an A357-T6 cast aluminium alloy. Acta Materialia 201, pages 435-447.
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T. Vojtek, P. Pokorný, I. Kuběna, L. Náhlík, R. Fajkoš & P. Hutař. (2019) Quantitative dependence of oxide-induced crack closure on air humidity for railway axle steel. International Journal of Fatigue 123, pages 213-224.
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R. Aigner, S. Pusterhofer, S. Pomberger, M. Leitner & M. Stoschka. (2019) A probabilistic Kitagawa-Takahashi diagram for fatigue strength assessment of cast aluminium alloys. Materials Science and Engineering: A 745, pages 326-334.
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Tomáš Vojtek, Stanislav Žák & Jaroslav Pokluda. 2019. Mechanical Fatigue of Metals. Mechanical Fatigue of Metals 161 167 .
Martin Leitner, Roman Aigner, Sebastian Pomberger, Michael Stoschka, Christian Garb & Stefan Pusterhofer. 2019. Mechanical Fatigue of Metals. Mechanical Fatigue of Metals 139 145 .
Tomáš Vojtek, Stanislav Žák & Jaroslav Pokluda. (2018) Quantitative analysis of intrinsic mode III fatigue thresholds in bcc metals. International Journal of Fatigue 115, pages 35-41.
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Prashant Kumar, Prakash S. Shinde & Kuldeep Pawar. (2018) A model to predict fatigue crack initiation in plates with a pre-crack. Strength, Fracture and Complexity 11:1, pages 19-29.
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Christian Garb, Martin Leitner, Bernhard Stauder, Dirk Schnubel & Florian Grün. (2018) Application of modified Kitagawa-Takahashi diagram for fatigue strength assessment of cast Al-Si-Cu alloys. International Journal of Fatigue 111, pages 256-268.
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P. Pokorný, T. Vojtek, L. Náhlík & P. Hutař. (2017) Crack closure in near-threshold fatigue crack propagation in railway axle steel EA4T. Engineering Fracture Mechanics 185, pages 2-19.
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Tomáš Vojtek, Reinhard Pippan, Anton Hohenwarter & Jaroslav Pokluda. (2017) Prediction of effective mode II fatigue crack growth threshold for metallic materials. Engineering Fracture Mechanics 174, pages 117-126.
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O. Kolednik, J. Zechner & J. Predan. (2016) Improvement of fatigue life by compliant and soft interlayers. Scripta Materialia 113, pages 1-5.
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Uwe Zerbst, Michael Vormwald, Reinhard Pippan, Hans-Peter Gänser, Christine Sarrazin-Baudoux & Mauro Madia. (2016) About the fatigue crack propagation threshold of metals as a design criterion – A review. Engineering Fracture Mechanics 153, pages 190-243.
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B. Li & L.G. Rosa. (2016) Prediction models of intrinsic fatigue threshold in metal alloys examined by experimental data. International Journal of Fatigue 82, pages 616-623.
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R. Pippan & F.O. Riemelmoser. 2016. Reference Module in Materials Science and Materials Engineering. Reference Module in Materials Science and Materials Engineering.
Piyas B. Chowdhury, Huseyin Sehitoglu & Richard G. Rateick. (2014) Predicting fatigue resistance of nano-twinned materials: Part II – Effective threshold stress intensity factor range. International Journal of Fatigue 68, pages 292-301.
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M. Fitzka, H. Mayer, R. Schuller, S. E. Stanzl‐Tschegg, T. Przeorski & P. Krug. (2014) Variable amplitude loading of spray‐formed hypereutectic aluminium silicon alloy DISPAL® S232 in the VHCF regime. Fatigue & Fracture of Engineering Materials & Structures 37:9, pages 945-957.
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Yoshimasa Takahashi, Hiroaki Yoshitake, Ryota Nakamichi, Takuya Wada, Masanori Takuma, Takahiro Shikama & Hiroshi Noguchi. (2014) Fatigue limit investigation of 6061-T6 aluminum alloy in giga-cycle regime. Materials Science and Engineering: A 614, pages 243-249.
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H. Mayer, M. Fitzka & R. Schuller. (2013) Constant and variable amplitude ultrasonic fatigue of 2024-T351 aluminium alloy at different load ratios. Ultrasonics 53:8, pages 1425-1432.
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Jaroslav Pokluda. (2013) Dislocation-based model of plasticity and roughness-induced crack closure. International Journal of Fatigue 46, pages 35-40.
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R. Pippan, H. Weinhandl & H. G. M. Kreuzer. 2010. Multiscale Modelling of Plasticity and Fracture by Means of Dislocation Mechanics. Multiscale Modelling of Plasticity and Fracture by Means of Dislocation Mechanics 149 184 .
J Pokluda, P Šandera & J Horniková. (2005) Analysis of Roughness-Induced Crack-Tip Shielding in Terms of Size Ratio Effect. Journal of ASTM International 2:4, pages 1-15.
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R. Pippan & F.O. Riemelmoser. 2003. Comprehensive Structural Integrity. Comprehensive Structural Integrity 191 207 .
R. PIPPAN, B. TABERNIG, E. GACH & F. RIEMELMOSER. (2002) Non‐propagation conditions for fatigue cracks and fatigue in the very high‐cycle regime. Fatigue & Fracture of Engineering Materials & Structures 25:8-9, pages 805-811.
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H. Mayer, U. Fuchs, S. Tschegg, B. Zettl, Hj. Lipowsky, A. Stich & M. Papakyriacou. (2002) Einfluss von Gussfehlern auf die Dauerfestigkeit von Aluminium- und Magnesiumgusslegierungen. Materialwissenschaft und Werkstofftechnik 33:3, pages 117-127.
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J.Gil Sevillano. (2001) The effective threshold for fatigue crack propagation: a plastic size effect?. Scripta Materialia 44:11, pages 2661-2665.
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Franz Oswald Riemelmoser, Peter Gumbsch & Reinhard Pippan. (2001) Dislocation Modelling of Fatigue Cracks: An Overview. MATERIALS TRANSACTIONS 42:1, pages 2-13.
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B. Zettl, H. Mayer, S.E. Stanzl-Tschegg & H.P. Degischer. (2000) Fatigue properties of aluminium foams at high numbers of cycles. Materials Science and Engineering: A 292:1, pages 1-7.
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JC NewmanJrJr & RS PiascikFO Riemelmoser & R Pippan. 2000. Fatigue Crack Growth Thresholds, Endurance Limits, and Design. Fatigue Crack Growth Thresholds, Endurance Limits, and Design 252 265 .

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