[{"doi":"10.1002/mawe.202000288","date_updated":"2023-06-01T14:38:03Z","volume":52,"author":[{"full_name":"Hein, Maxwell","id":"52771","last_name":"Hein","orcid":"0000-0002-3732-2236","first_name":"Maxwell"},{"first_name":"Kay-Peter","id":"48411","full_name":"Hoyer, Kay-Peter","last_name":"Hoyer"},{"first_name":"Mirko","id":"43720","full_name":"Schaper, Mirko","last_name":"Schaper"}],"page":"703-716","intvolume":" 52","citation":{"chicago":"Hein, Maxwell, Kay-Peter Hoyer, and Mirko Schaper. “Additively Processed TiAl6Nb7 Alloy for Biomedical Applications.” Materialwissenschaft Und Werkstofftechnik 52 (2021): 703–16. https://doi.org/10.1002/mawe.202000288.","ieee":"M. Hein, K.-P. Hoyer, and M. Schaper, “Additively processed TiAl6Nb7 alloy for biomedical applications,” Materialwissenschaft und Werkstofftechnik, vol. 52, pp. 703–716, 2021, doi: 10.1002/mawe.202000288.","ama":"Hein M, Hoyer K-P, Schaper M. Additively processed TiAl6Nb7 alloy for biomedical applications. Materialwissenschaft und Werkstofftechnik. 2021;52:703-716. doi:10.1002/mawe.202000288","apa":"Hein, M., Hoyer, K.-P., & Schaper, M. (2021). Additively processed TiAl6Nb7 alloy for biomedical applications. Materialwissenschaft Und Werkstofftechnik, 52, 703–716. https://doi.org/10.1002/mawe.202000288","bibtex":"@article{Hein_Hoyer_Schaper_2021, title={Additively processed TiAl6Nb7 alloy for biomedical applications}, volume={52}, DOI={10.1002/mawe.202000288}, journal={Materialwissenschaft und Werkstofftechnik}, author={Hein, Maxwell and Hoyer, Kay-Peter and Schaper, Mirko}, year={2021}, pages={703–716} }","mla":"Hein, Maxwell, et al. “Additively Processed TiAl6Nb7 Alloy for Biomedical Applications.” Materialwissenschaft Und Werkstofftechnik, vol. 52, 2021, pp. 703–16, doi:10.1002/mawe.202000288.","short":"M. Hein, K.-P. Hoyer, M. Schaper, Materialwissenschaft Und Werkstofftechnik 52 (2021) 703–716."},"publication_identifier":{"issn":["0933-5137","1521-4052"]},"publication_status":"published","article_type":"original","_id":"24086","department":[{"_id":"158"}],"user_id":"43720","status":"public","type":"journal_article","title":"Additively processed TiAl6Nb7 alloy for biomedical applications","date_created":"2021-09-09T15:40:08Z","year":"2021","quality_controlled":"1","keyword":["Laser beam melting","titanium alloy","TiAl6Nb7","biomedical engineering","implants"],"language":[{"iso":"eng"}],"abstract":[{"text":"Laser beam melting (LBM) is an advanced manufacturing technology providing\r\nspecial features and the possibility to produce complex and individual parts directly\r\nfrom a CAD model. TiAl6V4 is the most common used titanium alloy particularly\r\nin biomedical applications. TiAl6Nb7 shows promising improvements especially\r\nregarding biocompatible properties due to the substitution of the hazardous\r\nvanadium. This work focuses on the examination of laser beam melted TiAl6Nb7.\r\nFor microstructural investigation scanning electron microscopy including energydispersive\r\nx-ray spectroscopy as well as electron backscatter diffraction are utilized.\r\nThe laser beam melted related acicular microstructure as well as the corresponding\r\nmechanical properties, which are determined by hardness measurements\r\nand tensile tests, are investigated. The laser beam melted alloy meets,\r\nexcept of breaking elongation A, the mechanical demands like ultimate tensile\r\nstrength Rm, yield strength Rp0.2, Vickers hardness HV of international standard\r\nISO 5832-11. Next steps contain comparison between TiAl6Nb7 and TiAl6V4 in\r\ndifferent conditions. Further investigations aim at improving mechanical properties\r\nof TiAl6Nb7 by heat treatments and assessment of their influence on the microstructure\r\nas well as examination regarding the corrosive behavior in human bodylike\r\nconditions.","lang":"eng"}],"publication":"Materialwissenschaft und Werkstofftechnik"},{"publication":"Microscopy and Microanalysis","keyword":["Instrumentation"],"language":[{"iso":"eng"}],"quality_controlled":"1","issue":"S2","year":"2021","publisher":"Cambridge University Press (CUP)","date_created":"2022-02-11T17:33:29Z","title":"High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-situ SEM and STEM","type":"journal_article","status":"public","_id":"29813","department":[{"_id":"158"}],"user_id":"43720","publication_identifier":{"issn":["1431-9276","1435-8115"]},"publication_status":"published","intvolume":" 27","page":"79-80","citation":{"ama":"Cieslar M, Králík R, Bajtošová L, et al. High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-situ SEM and STEM. Microscopy and Microanalysis. 2021;27(S2):79-80. doi:10.1017/s1431927621013398","ieee":"M. Cieslar et al., “High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-situ SEM and STEM,” Microscopy and Microanalysis, vol. 27, no. S2, pp. 79–80, 2021, doi: 10.1017/s1431927621013398.","chicago":"Cieslar, Miroslav, Rostislav Králík, Lucia Bajtošová, Barbora Křivská, Michal Hájek, Sára Belejová, Olexandr Grydin, Mykhailo Stolbchenko, and Mirko Schaper. “High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-Situ SEM and STEM.” Microscopy and Microanalysis 27, no. S2 (2021): 79–80. https://doi.org/10.1017/s1431927621013398.","short":"M. Cieslar, R. Králík, L. Bajtošová, B. Křivská, M. Hájek, S. Belejová, O. Grydin, M. Stolbchenko, M. Schaper, Microscopy and Microanalysis 27 (2021) 79–80.","mla":"Cieslar, Miroslav, et al. “High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-Situ SEM and STEM.” Microscopy and Microanalysis, vol. 27, no. S2, Cambridge University Press (CUP), 2021, pp. 79–80, doi:10.1017/s1431927621013398.","bibtex":"@article{Cieslar_Králík_Bajtošová_Křivská_Hájek_Belejová_Grydin_Stolbchenko_Schaper_2021, title={High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-situ SEM and STEM}, volume={27}, DOI={10.1017/s1431927621013398}, number={S2}, journal={Microscopy and Microanalysis}, publisher={Cambridge University Press (CUP)}, author={Cieslar, Miroslav and Králík, Rostislav and Bajtošová, Lucia and Křivská, Barbora and Hájek, Michal and Belejová, Sára and Grydin, Olexandr and Stolbchenko, Mykhailo and Schaper, Mirko}, year={2021}, pages={79–80} }","apa":"Cieslar, M., Králík, R., Bajtošová, L., Křivská, B., Hájek, M., Belejová, S., Grydin, O., Stolbchenko, M., & Schaper, M. (2021). High Temperature Annealing of Twin-Roll Cast Al-Li-Based Alloy Studied by In-situ SEM and STEM. Microscopy and Microanalysis, 27(S2), 79–80. https://doi.org/10.1017/s1431927621013398"},"date_updated":"2023-06-01T14:38:37Z","volume":27,"author":[{"first_name":"Miroslav","full_name":"Cieslar, Miroslav","last_name":"Cieslar"},{"first_name":"Rostislav","last_name":"Králík","full_name":"Králík, Rostislav"},{"first_name":"Lucia","last_name":"Bajtošová","full_name":"Bajtošová, Lucia"},{"full_name":"Křivská, Barbora","last_name":"Křivská","first_name":"Barbora"},{"first_name":"Michal","last_name":"Hájek","full_name":"Hájek, Michal"},{"first_name":"Sára","full_name":"Belejová, Sára","last_name":"Belejová"},{"last_name":"Grydin","id":"43822","full_name":"Grydin, Olexandr","first_name":"Olexandr"},{"first_name":"Mykhailo","last_name":"Stolbchenko","full_name":"Stolbchenko, Mykhailo"},{"full_name":"Schaper, Mirko","id":"43720","last_name":"Schaper","first_name":"Mirko"}],"doi":"10.1017/s1431927621013398"},{"publication":"Journal of Alloys and Compounds","keyword":["Materials Chemistry","Metals and Alloys","Mechanical Engineering","Mechanics of Materials"],"language":[{"iso":"eng"}],"quality_controlled":"1","year":"2021","publisher":"Elsevier BV","date_created":"2023-02-02T14:34:42Z","title":"Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation","type":"journal_article","status":"public","_id":"41514","user_id":"43720","department":[{"_id":"9"},{"_id":"158"}],"article_number":"159544","publication_status":"published","publication_identifier":{"issn":["0925-8388"]},"citation":{"short":"J.T. Krüger, K.-P. Hoyer, V. Filor, S. Pramanik, M. Kietzmann, J. Meißner, M. Schaper, Journal of Alloys and Compounds 871 (2021).","mla":"Krüger, Jan Tobias, et al. “Novel AgCa and AgCaLa Alloys for Fe-Based Bioresorbable Implants with Adapted Degradation.” Journal of Alloys and Compounds, vol. 871, 159544, Elsevier BV, 2021, doi:10.1016/j.jallcom.2021.159544.","bibtex":"@article{Krüger_Hoyer_Filor_Pramanik_Kietzmann_Meißner_Schaper_2021, title={Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation}, volume={871}, DOI={10.1016/j.jallcom.2021.159544}, number={159544}, journal={Journal of Alloys and Compounds}, publisher={Elsevier BV}, author={Krüger, Jan Tobias and Hoyer, Kay-Peter and Filor, Viviane and Pramanik, Sudipta and Kietzmann, Manfred and Meißner, Jessica and Schaper, Mirko}, year={2021} }","apa":"Krüger, J. T., Hoyer, K.-P., Filor, V., Pramanik, S., Kietzmann, M., Meißner, J., & Schaper, M. (2021). Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation. Journal of Alloys and Compounds, 871, Article 159544. https://doi.org/10.1016/j.jallcom.2021.159544","ama":"Krüger JT, Hoyer K-P, Filor V, et al. Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation. Journal of Alloys and Compounds. 2021;871. doi:10.1016/j.jallcom.2021.159544","chicago":"Krüger, Jan Tobias, Kay-Peter Hoyer, Viviane Filor, Sudipta Pramanik, Manfred Kietzmann, Jessica Meißner, and Mirko Schaper. “Novel AgCa and AgCaLa Alloys for Fe-Based Bioresorbable Implants with Adapted Degradation.” Journal of Alloys and Compounds 871 (2021). https://doi.org/10.1016/j.jallcom.2021.159544.","ieee":"J. T. Krüger et al., “Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation,” Journal of Alloys and Compounds, vol. 871, Art. no. 159544, 2021, doi: 10.1016/j.jallcom.2021.159544."},"intvolume":" 871","date_updated":"2023-06-01T14:35:36Z","author":[{"first_name":"Jan Tobias","full_name":"Krüger, Jan Tobias","id":"44307","orcid":"0000-0002-0827-9654","last_name":"Krüger"},{"first_name":"Kay-Peter","id":"48411","full_name":"Hoyer, Kay-Peter","last_name":"Hoyer"},{"full_name":"Filor, Viviane","last_name":"Filor","first_name":"Viviane"},{"first_name":"Sudipta","full_name":"Pramanik, Sudipta","last_name":"Pramanik"},{"full_name":"Kietzmann, Manfred","last_name":"Kietzmann","first_name":"Manfred"},{"last_name":"Meißner","full_name":"Meißner, Jessica","first_name":"Jessica"},{"full_name":"Schaper, Mirko","id":"43720","last_name":"Schaper","first_name":"Mirko"}],"volume":871,"doi":"10.1016/j.jallcom.2021.159544"},{"keyword":["Instrumentation"],"language":[{"iso":"eng"}],"publication":"Microscopy and Microanalysis","title":"Intermetallic Phase Growth in Al-steel Clad Strip during In-situ Heating in TEM","publisher":"Cambridge University Press (CUP)","date_created":"2022-02-11T17:39:16Z","year":"2021","quality_controlled":"1","issue":"S2","_id":"29814","department":[{"_id":"158"}],"user_id":"43720","status":"public","type":"journal_article","doi":"10.1017/s1431927621013453","date_updated":"2023-06-01T14:38:28Z","volume":27,"author":[{"first_name":"Barbora","full_name":"Křivská, Barbora","last_name":"Křivská"},{"first_name":"Michaela","full_name":"Šlapáková, Michaela","last_name":"Šlapáková"},{"first_name":"Peter","full_name":"Minárik, Peter","last_name":"Minárik"},{"last_name":"Fekete","full_name":"Fekete, Klaudia","first_name":"Klaudia"},{"last_name":"Králík","full_name":"Králík, Rostislav","first_name":"Rostislav"},{"full_name":"Stolbchenko, Mykhailo","last_name":"Stolbchenko","first_name":"Mykhailo"},{"last_name":"Schaper","full_name":"Schaper, Mirko","id":"43720","first_name":"Mirko"},{"first_name":"Olexandr","last_name":"Grydin","id":"43822","full_name":"Grydin, Olexandr"}],"page":"91-92","intvolume":" 27","citation":{"apa":"Křivská, B., Šlapáková, M., Minárik, P., Fekete, K., Králík, R., Stolbchenko, M., Schaper, M., & Grydin, O. (2021). Intermetallic Phase Growth in Al-steel Clad Strip during In-situ Heating in TEM. Microscopy and Microanalysis, 27(S2), 91–92. https://doi.org/10.1017/s1431927621013453","short":"B. Křivská, M. Šlapáková, P. Minárik, K. Fekete, R. Králík, M. Stolbchenko, M. Schaper, O. Grydin, Microscopy and Microanalysis 27 (2021) 91–92.","mla":"Křivská, Barbora, et al. “Intermetallic Phase Growth in Al-Steel Clad Strip during In-Situ Heating in TEM.” Microscopy and Microanalysis, vol. 27, no. S2, Cambridge University Press (CUP), 2021, pp. 91–92, doi:10.1017/s1431927621013453.","bibtex":"@article{Křivská_Šlapáková_Minárik_Fekete_Králík_Stolbchenko_Schaper_Grydin_2021, title={Intermetallic Phase Growth in Al-steel Clad Strip during In-situ Heating in TEM}, volume={27}, DOI={10.1017/s1431927621013453}, number={S2}, journal={Microscopy and Microanalysis}, publisher={Cambridge University Press (CUP)}, author={Křivská, Barbora and Šlapáková, Michaela and Minárik, Peter and Fekete, Klaudia and Králík, Rostislav and Stolbchenko, Mykhailo and Schaper, Mirko and Grydin, Olexandr}, year={2021}, pages={91–92} }","chicago":"Křivská, Barbora, Michaela Šlapáková, Peter Minárik, Klaudia Fekete, Rostislav Králík, Mykhailo Stolbchenko, Mirko Schaper, and Olexandr Grydin. “Intermetallic Phase Growth in Al-Steel Clad Strip during In-Situ Heating in TEM.” Microscopy and Microanalysis 27, no. S2 (2021): 91–92. https://doi.org/10.1017/s1431927621013453.","ieee":"B. Křivská et al., “Intermetallic Phase Growth in Al-steel Clad Strip during In-situ Heating in TEM,” Microscopy and Microanalysis, vol. 27, no. S2, pp. 91–92, 2021, doi: 10.1017/s1431927621013453.","ama":"Křivská B, Šlapáková M, Minárik P, et al. Intermetallic Phase Growth in Al-steel Clad Strip during In-situ Heating in TEM. Microscopy and Microanalysis. 2021;27(S2):91-92. doi:10.1017/s1431927621013453"},"publication_identifier":{"issn":["1431-9276","1435-8115"]},"publication_status":"published"},{"department":[{"_id":"9"},{"_id":"158"}],"user_id":"43720","_id":"41515","language":[{"iso":"eng"}],"keyword":["Industrial and Manufacturing Engineering","Engineering (miscellaneous)","General Materials Science","Biomedical Engineering"],"article_number":"102087","publication":"Additive Manufacturing","type":"journal_article","status":"public","volume":46,"date_created":"2023-02-02T14:35:02Z","author":[{"full_name":"Pramanik, Sudipta","last_name":"Pramanik","first_name":"Sudipta"},{"first_name":"Lennart","id":"71508","full_name":"Tasche, Lennart","last_name":"Tasche"},{"last_name":"Hoyer","full_name":"Hoyer, Kay-Peter","id":"48411","first_name":"Kay-Peter"},{"first_name":"Mirko","last_name":"Schaper","full_name":"Schaper, Mirko","id":"43720"}],"publisher":"Elsevier BV","date_updated":"2023-06-01T14:35:58Z","doi":"10.1016/j.addma.2021.102087","title":"Investigating the microstructure of an additively manufactured FeCo alloy: an electron microscopy study","publication_identifier":{"issn":["2214-8604"]},"quality_controlled":"1","publication_status":"published","intvolume":" 46","citation":{"apa":"Pramanik, S., Tasche, L., Hoyer, K.-P., & Schaper, M. (2021). Investigating the microstructure of an additively manufactured FeCo alloy: an electron microscopy study. Additive Manufacturing, 46, Article 102087. https://doi.org/10.1016/j.addma.2021.102087","mla":"Pramanik, Sudipta, et al. “Investigating the Microstructure of an Additively Manufactured FeCo Alloy: An Electron Microscopy Study.” Additive Manufacturing, vol. 46, 102087, Elsevier BV, 2021, doi:10.1016/j.addma.2021.102087.","bibtex":"@article{Pramanik_Tasche_Hoyer_Schaper_2021, title={Investigating the microstructure of an additively manufactured FeCo alloy: an electron microscopy study}, volume={46}, DOI={10.1016/j.addma.2021.102087}, number={102087}, journal={Additive Manufacturing}, publisher={Elsevier BV}, author={Pramanik, Sudipta and Tasche, Lennart and Hoyer, Kay-Peter and Schaper, Mirko}, year={2021} }","short":"S. Pramanik, L. Tasche, K.-P. Hoyer, M. Schaper, Additive Manufacturing 46 (2021).","ieee":"S. Pramanik, L. Tasche, K.-P. Hoyer, and M. Schaper, “Investigating the microstructure of an additively manufactured FeCo alloy: an electron microscopy study,” Additive Manufacturing, vol. 46, Art. no. 102087, 2021, doi: 10.1016/j.addma.2021.102087.","chicago":"Pramanik, Sudipta, Lennart Tasche, Kay-Peter Hoyer, and Mirko Schaper. “Investigating the Microstructure of an Additively Manufactured FeCo Alloy: An Electron Microscopy Study.” Additive Manufacturing 46 (2021). https://doi.org/10.1016/j.addma.2021.102087.","ama":"Pramanik S, Tasche L, Hoyer K-P, Schaper M. Investigating the microstructure of an additively manufactured FeCo alloy: an electron microscopy study. Additive Manufacturing. 2021;46. doi:10.1016/j.addma.2021.102087"},"year":"2021"},{"date_created":"2021-09-09T15:50:21Z","author":[{"full_name":"Pramanik, Sudipta","last_name":"Pramanik","first_name":"Sudipta"},{"full_name":"Tasche, Lennart","last_name":"Tasche","first_name":"Lennart"},{"id":"48411","full_name":"Hoyer, Kay-Peter","last_name":"Hoyer","first_name":"Kay-Peter"},{"first_name":"Mirko","last_name":"Schaper","full_name":"Schaper, Mirko","id":"43720"}],"date_updated":"2023-06-01T14:39:50Z","doi":"10.1007/s11665-021-06065-9","title":"Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy","quality_controlled":"1","publication_identifier":{"issn":["1059-9495","1544-1024"]},"publication_status":"published","citation":{"chicago":"Pramanik, Sudipta, Lennart Tasche, Kay-Peter Hoyer, and Mirko Schaper. “Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy.” Journal of Materials Engineering and Performance, 2021. https://doi.org/10.1007/s11665-021-06065-9.","ieee":"S. Pramanik, L. Tasche, K.-P. Hoyer, and M. Schaper, “Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy,” Journal of Materials Engineering and Performance, 2021, doi: 10.1007/s11665-021-06065-9.","ama":"Pramanik S, Tasche L, Hoyer K-P, Schaper M. Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy. Journal of Materials Engineering and Performance. Published online 2021. doi:10.1007/s11665-021-06065-9","mla":"Pramanik, Sudipta, et al. “Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy.” Journal of Materials Engineering and Performance, 2021, doi:10.1007/s11665-021-06065-9.","short":"S. Pramanik, L. Tasche, K.-P. Hoyer, M. Schaper, Journal of Materials Engineering and Performance (2021).","bibtex":"@article{Pramanik_Tasche_Hoyer_Schaper_2021, title={Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy}, DOI={10.1007/s11665-021-06065-9}, journal={Journal of Materials Engineering and Performance}, author={Pramanik, Sudipta and Tasche, Lennart and Hoyer, Kay-Peter and Schaper, Mirko}, year={2021} }","apa":"Pramanik, S., Tasche, L., Hoyer, K.-P., & Schaper, M. (2021). Correlation between Taylor Model Prediction and Transmission Electron Microscopy-Based Microstructural Investigations of Quasi-In Situ Tensile Deformation of Additively Manufactured FeCo Alloy. Journal of Materials Engineering and Performance. https://doi.org/10.1007/s11665-021-06065-9"},"year":"2021","department":[{"_id":"158"}],"user_id":"43720","_id":"24090","language":[{"iso":"eng"}],"publication":"Journal of Materials Engineering and Performance","type":"journal_article","status":"public","abstract":[{"text":"AbstractWithin this research, the multiscale microstructural evolution before and after the tensile test of a FeCo alloy is addressed. X-ray µ-computer tomography (CT), electron backscattered diffraction (EBSD), and transmission electron microscopy (TEM) are employed to determine the microstructure on different length scales. Microstructural evolution is studied by performing EBSD of the same area before and after the tensile test. As a result, $$\\langle$$\r\n ⟨\r\n 001$$\\rangle$$\r\n ⟩\r\n ||TD, $$\\langle$$\r\n ⟨\r\n 011$$\\rangle$$\r\n ⟩\r\n ||TD are hard orientations and $$\\langle$$\r\n ⟨\r\n 111$$\\rangle$$\r\n ⟩\r\n ||TD is soft orientations for deformation accommodation. It is not possible to predict the deformation of a single grain with the Taylor model. However, the Taylor model accurately predicts the orientation of all grains after deformation. {123}$$\\langle$$\r\n ⟨\r\n 111$$\\rangle$$\r\n ⟩\r\n is the most active slip system, and {112}$$\\langle$$\r\n ⟨\r\n 111$$\\rangle$$\r\n ⟩\r\n is the least active slip system. Both EBSD micrographs show grain subdivision after tensile testing. TEM images show the formation of dislocation cells. Correlative HRTEM images show unresolved lattice fringes at dislocation cell boundaries, whereas resolved lattice fringes are observed at dislocation cell interior. Since Schmid’s law is unable to predict the deformation behavior of grains, the boundary slip transmission accurately predicts the grain deformation behavior.","lang":"eng"}]},{"citation":{"ama":"Garthe K-U, Hoyer K-P, Hagen L, Tillmann W, Schaper M. Correlation between pre- and post-treatments of additively manufactured 316L parts and the resulting low cycle fatigue behavior. Rapid Prototyping Journal. Published online 2021. doi:10.1108/rpj-01-2021-0017","ieee":"K.-U. Garthe, K.-P. Hoyer, L. Hagen, W. Tillmann, and M. Schaper, “Correlation between pre- and post-treatments of additively manufactured 316L parts and the resulting low cycle fatigue behavior,” Rapid Prototyping Journal, 2021, doi: 10.1108/rpj-01-2021-0017.","chicago":"Garthe, Kai-Uwe, Kay-Peter Hoyer, Leif Hagen, Wolfgang Tillmann, and Mirko Schaper. “Correlation between Pre- and Post-Treatments of Additively Manufactured 316L Parts and the Resulting Low Cycle Fatigue Behavior.” Rapid Prototyping Journal, 2021. https://doi.org/10.1108/rpj-01-2021-0017.","apa":"Garthe, K.-U., Hoyer, K.-P., Hagen, L., Tillmann, W., & Schaper, M. (2021). Correlation between pre- and post-treatments of additively manufactured 316L parts and the resulting low cycle fatigue behavior. Rapid Prototyping Journal. https://doi.org/10.1108/rpj-01-2021-0017","short":"K.-U. Garthe, K.-P. Hoyer, L. Hagen, W. Tillmann, M. Schaper, Rapid Prototyping Journal (2021).","mla":"Garthe, Kai-Uwe, et al. “Correlation between Pre- and Post-Treatments of Additively Manufactured 316L Parts and the Resulting Low Cycle Fatigue Behavior.” Rapid Prototyping Journal, 2021, doi:10.1108/rpj-01-2021-0017.","bibtex":"@article{Garthe_Hoyer_Hagen_Tillmann_Schaper_2021, title={Correlation between pre- and post-treatments of additively manufactured 316L parts and the resulting low cycle fatigue behavior}, DOI={10.1108/rpj-01-2021-0017}, journal={Rapid Prototyping Journal}, author={Garthe, Kai-Uwe and Hoyer, Kay-Peter and Hagen, Leif and Tillmann, Wolfgang and Schaper, Mirko}, year={2021} }"},"year":"2021","quality_controlled":"1","publication_identifier":{"issn":["1355-2546","1355-2546"]},"publication_status":"published","doi":"10.1108/rpj-01-2021-0017","title":"Correlation between pre- and post-treatments of additively manufactured 316L parts and the resulting low cycle fatigue behavior","date_created":"2021-11-17T10:00:23Z","author":[{"first_name":"Kai-Uwe","last_name":"Garthe","orcid":"0000-0003-0741-3812","id":"11199","full_name":"Garthe, Kai-Uwe"},{"first_name":"Kay-Peter","id":"48411","full_name":"Hoyer, Kay-Peter","last_name":"Hoyer"},{"full_name":"Hagen, Leif","last_name":"Hagen","first_name":"Leif"},{"last_name":"Tillmann","full_name":"Tillmann, Wolfgang","first_name":"Wolfgang"},{"full_name":"Schaper, Mirko","id":"43720","last_name":"Schaper","first_name":"Mirko"}],"date_updated":"2023-06-01T14:39:00Z","status":"public","abstract":[{"lang":"eng","text":"\r\nPurpose\r\nThe currently existing restrictions regarding the deployment of additively manufactured components because of poor surface roughness, porosity and residual stresses as well as their influence on the low-cycle fatigue (LCF) strength are addressed in this paper.\r\n\r\n\r\nDesign/methodology/approach\r\nThis study aims to evaluating the effect of different pre- and post-treatments on the LCF strength of additively manufactured 316L parts. Therefore, 316L specimens manufactured by laser powder bed fusion were examined in their as-built state as well as after grinding, or coating with regard to the surface roughness, residual stresses and LCF strength. To differentiate between topographical effects and residual stress-related phenomena, stress-relieved 316L specimens served as a reference throughout the investigations. To enable an alumina coating of the 316L components, atmospheric plasma spraying was used, and the near-surface residual stresses and the surface roughness are measured and investigated.\r\n\r\n\r\nFindings\r\nThe results have shown that the applied pre- and post-treatments such as stress-relief heat treatment, grinding and alumina coating have each led to an increase in LCF strength of the 316L specimens. In contrast, the non-heat-treated specimens predominantly exhibited coating delamination.\r\n\r\n\r\nOriginality/value\r\nTo the best of the authors’ knowledge, this is the first study of the correlation between the LCF behavior of additively manufactured uncoated 316L specimens in comparison with additively manufactured 316L specimens with an alumina coating.\r\n"}],"publication":"Rapid Prototyping Journal","type":"journal_article","language":[{"iso":"eng"}],"department":[{"_id":"9"},{"_id":"158"}],"user_id":"43720","_id":"27509"},{"doi":"10.1016/j.jallcom.2021.159544","title":"Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation","author":[{"id":"44307","full_name":"Krüger, Jan Tobias","orcid":"0000-0002-0827-9654","last_name":"Krüger","first_name":"Jan Tobias"},{"full_name":"Hoyer, Kay-Peter","id":"48411","last_name":"Hoyer","first_name":"Kay-Peter"},{"full_name":"Filor, Viviane","last_name":"Filor","first_name":"Viviane"},{"full_name":"Pramanik, Sudipta","last_name":"Pramanik","first_name":"Sudipta"},{"first_name":"Manfred","last_name":"Kietzmann","full_name":"Kietzmann, Manfred"},{"full_name":"Meißner, Jessica","last_name":"Meißner","first_name":"Jessica"},{"first_name":"Mirko","id":"43720","full_name":"Schaper, Mirko","last_name":"Schaper"}],"date_created":"2021-09-09T15:40:39Z","date_updated":"2023-06-01T14:39:34Z","citation":{"ama":"Krüger JT, Hoyer K-P, Filor V, et al. Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation. Journal of Alloys and Compounds. Published online 2021. doi:10.1016/j.jallcom.2021.159544","chicago":"Krüger, Jan Tobias, Kay-Peter Hoyer, Viviane Filor, Sudipta Pramanik, Manfred Kietzmann, Jessica Meißner, and Mirko Schaper. “Novel AgCa and AgCaLa Alloys for Fe-Based Bioresorbable Implants with Adapted Degradation.” Journal of Alloys and Compounds, 2021. https://doi.org/10.1016/j.jallcom.2021.159544.","ieee":"J. T. Krüger et al., “Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation,” Journal of Alloys and Compounds, Art. no. 159544, 2021, doi: 10.1016/j.jallcom.2021.159544.","apa":"Krüger, J. T., Hoyer, K.-P., Filor, V., Pramanik, S., Kietzmann, M., Meißner, J., & Schaper, M. (2021). Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation. Journal of Alloys and Compounds, Article 159544. https://doi.org/10.1016/j.jallcom.2021.159544","short":"J.T. Krüger, K.-P. Hoyer, V. Filor, S. Pramanik, M. Kietzmann, J. Meißner, M. Schaper, Journal of Alloys and Compounds (2021).","mla":"Krüger, Jan Tobias, et al. “Novel AgCa and AgCaLa Alloys for Fe-Based Bioresorbable Implants with Adapted Degradation.” Journal of Alloys and Compounds, 159544, 2021, doi:10.1016/j.jallcom.2021.159544.","bibtex":"@article{Krüger_Hoyer_Filor_Pramanik_Kietzmann_Meißner_Schaper_2021, title={Novel AgCa and AgCaLa alloys for Fe-based bioresorbable implants with adapted degradation}, DOI={10.1016/j.jallcom.2021.159544}, number={159544}, journal={Journal of Alloys and Compounds}, author={Krüger, Jan Tobias and Hoyer, Kay-Peter and Filor, Viviane and Pramanik, Sudipta and Kietzmann, Manfred and Meißner, Jessica and Schaper, Mirko}, year={2021} }"},"year":"2021","publication_status":"published","quality_controlled":"1","publication_identifier":{"issn":["0925-8388"]},"language":[{"iso":"eng"}],"article_number":"159544","user_id":"43720","department":[{"_id":"158"}],"_id":"24087","status":"public","abstract":[{"text":"Resorbable implants are highly beneficial to reduce patient burden since they need not be removed after a defined period. Currently, magnesium (Mg) and polymers are being applied as bioresorbable materials. However, for some applications the insufficient mechanical properties and high degradation rate of Mg cause the need for new materials. Iron (Fe)-based alloys are promising due to their biocompatibility and good mechanical properties, but their degradation rate is too low and needs to be adapted eg. via alloying with manganese (Mn). Besides, phases with high electrochemical potential lead to increased degradation of residual material with lower potential based on the galvanic coupling. Here, silver (Ag) is promising for the formation of such phases due to its high electrochemical potential (+0.8 V vs. SHE), immiscibility with Fe, biocompatibility, and anti-bacterial properties. Since remaining silver particles can lead to adverse consequences as thrombosis, these particles need to dissolve after the matrix material. Thus a silver alloy with high electrochemical potential, biocompatibility, and adjusted degradation behavior is required as an additive for iron-based bioresorbable materials. Several silver alloying systems are possible, but regarding the electrochemical potential and degradation behavior of binary alloys, calcium (Ca) and lanthanum (La) are best-suited considering their biocompatibility. Accordingly, this research addresses AgCa and AgCaLa alloys as additives for iron-based degradable materials with adapted degradation behavior.","lang":"eng"}],"type":"journal_article","publication":"Journal of Alloys and Compounds"},{"article_number":"1304","article_type":"original","language":[{"iso":"eng"}],"_id":"23913","department":[{"_id":"321"}],"user_id":"43720","abstract":[{"lang":"eng","text":"Implementing the concept of mixed construction in modern automotive engineering requires the joining of sheet metal or extruded profiles with cast components made from different materials. As weight reduction is desired, these cast components are usually made from high-strength aluminium alloys of the Al-Si (Mn, Mg) system, which have limited weldability. The mechanical joinability of the cast components depends on their ductility, which is influenced by the microstructure. High-strength cast aluminium alloys have relatively low ductility, which leads to cracking of the joints. This limits the range of applications for cast aluminium alloys. In this study, an aluminium alloy of the Al-Si system AlSi9 is used to investigate relationships between solidification conditions during the sand casting process, microstructure, mechanical properties, and joinability. The demonstrator is a stepped plate with a minimum thickness of 2.0 mm and a maximum thickness of 4.0 mm, whereas the thickness difference between neighbour steps amounts to 0.5 mm. During casting trials, the solidification rates for different plate steps were measured. The microscopic investigations reveal a correlation between solidification rates and microstructure parameters such as secondary dendrite arm spacing. Furthermore, mechanical properties and the mechanical joinability are investigated."}],"status":"public","publication":"Metals","type":"journal_article","title":"Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy","doi":"10.3390/met11081304","date_updated":"2023-06-01T14:40:09Z","author":[{"last_name":"Neuser","full_name":"Neuser, Moritz","first_name":"Moritz"},{"id":"43822","full_name":"Grydin, Olexandr","last_name":"Grydin","first_name":"Olexandr"},{"last_name":"Andreiev","full_name":"Andreiev, Anatolii","id":"50215","first_name":"Anatolii"},{"last_name":"Schaper","id":"43720","full_name":"Schaper, Mirko","first_name":"Mirko"}],"date_created":"2021-09-08T07:48:28Z","year":"2021","citation":{"mla":"Neuser, Moritz, et al. “Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy.” Metals, 1304, 2021, doi:10.3390/met11081304.","bibtex":"@article{Neuser_Grydin_Andreiev_Schaper_2021, title={Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy}, DOI={10.3390/met11081304}, number={1304}, journal={Metals}, author={Neuser, Moritz and Grydin, Olexandr and Andreiev, Anatolii and Schaper, Mirko}, year={2021} }","short":"M. Neuser, O. Grydin, A. Andreiev, M. Schaper, Metals (2021).","apa":"Neuser, M., Grydin, O., Andreiev, A., & Schaper, M. (2021). Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy. Metals, Article 1304. https://doi.org/10.3390/met11081304","chicago":"Neuser, Moritz, Olexandr Grydin, Anatolii Andreiev, and Mirko Schaper. “Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy.” Metals, 2021. https://doi.org/10.3390/met11081304.","ieee":"M. Neuser, O. Grydin, A. Andreiev, and M. Schaper, “Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy,” Metals, Art. no. 1304, 2021, doi: 10.3390/met11081304.","ama":"Neuser M, Grydin O, Andreiev A, Schaper M. Effect of Solidification Rates at Sand Casting on the Mechanical Joinability of a Cast Aluminium Alloy. Metals. Published online 2021. doi:10.3390/met11081304"},"publication_identifier":{"issn":["2075-4701"]},"quality_controlled":"1","publication_status":"published"},{"title":"Time efficient laser modification of steel surfaces for advanced bonding in hybrid materials","doi":"10.1007/s11740-020-01006-2","date_updated":"2023-06-01T14:39:15Z","volume":15,"date_created":"2021-09-16T15:50:59Z","author":[{"first_name":"Dietrich","full_name":"Voswinkel, Dietrich","id":"52634","last_name":"Voswinkel"},{"first_name":"D.","full_name":"Kloidt, D.","last_name":"Kloidt"},{"last_name":"Grydin","full_name":"Grydin, Olexandr","id":"43822","first_name":"Olexandr"},{"id":"43720","full_name":"Schaper, Mirko","last_name":"Schaper","first_name":"Mirko"}],"year":"2021","intvolume":" 15","page":"263-270","citation":{"apa":"Voswinkel, D., Kloidt, D., Grydin, O., & Schaper, M. (2021). Time efficient laser modification of steel surfaces for advanced bonding in hybrid materials. Production Engineering, 15(2), 263–270. https://doi.org/10.1007/s11740-020-01006-2","short":"D. Voswinkel, D. Kloidt, O. Grydin, M. Schaper, Production Engineering 15 (2021) 263–270.","bibtex":"@article{Voswinkel_Kloidt_Grydin_Schaper_2021, title={Time efficient laser modification of steel surfaces for advanced bonding in hybrid materials}, volume={15}, DOI={10.1007/s11740-020-01006-2}, number={2}, journal={Production Engineering}, author={Voswinkel, Dietrich and Kloidt, D. and Grydin, Olexandr and Schaper, Mirko}, year={2021}, pages={263–270} }","mla":"Voswinkel, Dietrich, et al. “Time Efficient Laser Modification of Steel Surfaces for Advanced Bonding in Hybrid Materials.” Production Engineering, vol. 15, no. 2, 2021, pp. 263–70, doi:10.1007/s11740-020-01006-2.","chicago":"Voswinkel, Dietrich, D. Kloidt, Olexandr Grydin, and Mirko Schaper. “Time Efficient Laser Modification of Steel Surfaces for Advanced Bonding in Hybrid Materials.” Production Engineering 15, no. 2 (2021): 263–70. https://doi.org/10.1007/s11740-020-01006-2.","ieee":"D. Voswinkel, D. Kloidt, O. Grydin, and M. Schaper, “Time efficient laser modification of steel surfaces for advanced bonding in hybrid materials,” Production Engineering, vol. 15, no. 2, pp. 263–270, 2021, doi: 10.1007/s11740-020-01006-2.","ama":"Voswinkel D, Kloidt D, Grydin O, Schaper M. Time efficient laser modification of steel surfaces for advanced bonding in hybrid materials. Production Engineering. 2021;15(2):263-270. doi:10.1007/s11740-020-01006-2"},"publication_identifier":{"issn":["0944-6524","1863-7353"]},"quality_controlled":"1","publication_status":"published","issue":"2","article_type":"original","language":[{"iso":"eng"}],"_id":"24565","department":[{"_id":"158"}],"user_id":"43720","abstract":[{"lang":"eng","text":"AbstractLaser surface treatment of metals is one option to improve their properties for adhesive bonding. In this paper, a pulsed YVO4 Laser source with a wavelength of 1064 nm and a maximum power of 25 W was utilized to increase the surface area of the steel HCT490X in order to improve its bonding properties with a carbon fibre reinforced polymer (CFRP). Investigated was the influence of the scanning speed of the laser source on the bonding properties. For this purpose, the steel surfaces were ablated at a scanning speed between 1500 and 4500 mm/s. Afterwards the components were bonded with the adhesive HexBond™ 677. After lap shear tests were carried out on the specimen, the surfaces were inspected using scanning electron microscopy (SEM). The experiments revealed that the bonding quality can be improved with a high scanning speed, even when the surface is not completely ablated."}],"status":"public","publication":"Production Engineering","type":"journal_article"},{"language":[{"iso":"eng"}],"article_type":"review","user_id":"43720","department":[{"_id":"158"},{"_id":"301"}],"_id":"24566","status":"public","type":"journal_article","publication":"ChemElectroChem","main_file_link":[{"url":"https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/celc.202100216","open_access":"1"}],"doi":"10.1002/celc.202100216","title":"Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte","date_created":"2021-09-16T15:56:58Z","author":[{"first_name":"Katja","last_name":"Engelkemeier","full_name":"Engelkemeier, Katja","id":"21743"},{"full_name":"Sun, Aijia","last_name":"Sun","first_name":"Aijia"},{"first_name":"Dietrich","id":"52634","full_name":"Voswinkel, Dietrich","last_name":"Voswinkel"},{"first_name":"Olexandr","last_name":"Grydin","id":"43822","full_name":"Grydin, Olexandr"},{"first_name":"Mirko","last_name":"Schaper","id":"43720","full_name":"Schaper, Mirko"},{"full_name":"Bremser, Wolfgang","last_name":"Bremser","first_name":"Wolfgang"}],"date_updated":"2023-06-01T14:39:27Z","publisher":"Wiley","oa":"1","citation":{"ama":"Engelkemeier K, Sun A, Voswinkel D, Grydin O, Schaper M, Bremser W. Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte. ChemElectroChem. Published online 2021:2155-2168. doi:10.1002/celc.202100216","chicago":"Engelkemeier, Katja, Aijia Sun, Dietrich Voswinkel, Olexandr Grydin, Mirko Schaper, and Wolfgang Bremser. “Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte.” ChemElectroChem, 2021, 2155–68. https://doi.org/10.1002/celc.202100216.","ieee":"K. Engelkemeier, A. Sun, D. Voswinkel, O. Grydin, M. Schaper, and W. Bremser, “Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte,” ChemElectroChem, pp. 2155–2168, 2021, doi: 10.1002/celc.202100216.","short":"K. Engelkemeier, A. Sun, D. Voswinkel, O. Grydin, M. Schaper, W. Bremser, ChemElectroChem (2021) 2155–2168.","bibtex":"@article{Engelkemeier_Sun_Voswinkel_Grydin_Schaper_Bremser_2021, title={Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte}, DOI={10.1002/celc.202100216}, journal={ChemElectroChem}, publisher={Wiley}, author={Engelkemeier, Katja and Sun, Aijia and Voswinkel, Dietrich and Grydin, Olexandr and Schaper, Mirko and Bremser, Wolfgang}, year={2021}, pages={2155–2168} }","mla":"Engelkemeier, Katja, et al. “Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte.” ChemElectroChem, Wiley, 2021, pp. 2155–68, doi:10.1002/celc.202100216.","apa":"Engelkemeier, K., Sun, A., Voswinkel, D., Grydin, O., Schaper, M., & Bremser, W. (2021). Zinc Anodizing: Structural Diversity of Anodic Zinc Oxide Controlled by the Type of Electrolyte. ChemElectroChem, 2155–2168. https://doi.org/10.1002/celc.202100216"},"page":"2155-2168","year":"2021","publication_status":"published","publication_identifier":{"issn":["2196-0216","2196-0216"]},"quality_controlled":"1"},{"publication":"Materials Science and Engineering: A","type":"journal_article","status":"public","_id":"23897","department":[{"_id":"158"},{"_id":"321"}],"user_id":"43720","article_number":"141662","language":[{"iso":"eng"}],"publication_identifier":{"issn":["0921-5093"]},"quality_controlled":"1","publication_status":"published","year":"2021","citation":{"short":"A. Andreiev, K.-P. Hoyer, D. Dula, F. Hengsbach, O. Grydin, Y. Frolov, M. Schaper, Materials Science and Engineering: A (2021).","mla":"Andreiev, Anatolii, et al. “Laser Beam Melting of Functionally Graded Materials with Application-Adapted Tailoring of Magnetic and Mechanical Performance.” Materials Science and Engineering: A, 141662, 2021, doi:10.1016/j.msea.2021.141662.","bibtex":"@article{Andreiev_Hoyer_Dula_Hengsbach_Grydin_Frolov_Schaper_2021, title={Laser beam melting of functionally graded materials with application-adapted tailoring of magnetic and mechanical performance}, DOI={10.1016/j.msea.2021.141662}, number={141662}, journal={Materials Science and Engineering: A}, author={Andreiev, Anatolii and Hoyer, Kay-Peter and Dula, Dimitri and Hengsbach, Florian and Grydin, Olexandr and Frolov, Yaroslav and Schaper, Mirko}, year={2021} }","apa":"Andreiev, A., Hoyer, K.-P., Dula, D., Hengsbach, F., Grydin, O., Frolov, Y., & Schaper, M. (2021). Laser beam melting of functionally graded materials with application-adapted tailoring of magnetic and mechanical performance. Materials Science and Engineering: A, Article 141662. https://doi.org/10.1016/j.msea.2021.141662","chicago":"Andreiev, Anatolii, Kay-Peter Hoyer, Dimitri Dula, Florian Hengsbach, Olexandr Grydin, Yaroslav Frolov, and Mirko Schaper. “Laser Beam Melting of Functionally Graded Materials with Application-Adapted Tailoring of Magnetic and Mechanical Performance.” Materials Science and Engineering: A, 2021. https://doi.org/10.1016/j.msea.2021.141662.","ieee":"A. Andreiev et al., “Laser beam melting of functionally graded materials with application-adapted tailoring of magnetic and mechanical performance,” Materials Science and Engineering: A, Art. no. 141662, 2021, doi: 10.1016/j.msea.2021.141662.","ama":"Andreiev A, Hoyer K-P, Dula D, et al. Laser beam melting of functionally graded materials with application-adapted tailoring of magnetic and mechanical performance. Materials Science and Engineering: A. Published online 2021. doi:10.1016/j.msea.2021.141662"},"date_updated":"2023-06-01T14:40:21Z","date_created":"2021-09-08T07:29:29Z","author":[{"id":"50215","full_name":"Andreiev, Anatolii","last_name":"Andreiev","first_name":"Anatolii"},{"first_name":"Kay-Peter","id":"48411","full_name":"Hoyer, Kay-Peter","last_name":"Hoyer"},{"full_name":"Dula, Dimitri","last_name":"Dula","first_name":"Dimitri"},{"last_name":"Hengsbach","full_name":"Hengsbach, Florian","first_name":"Florian"},{"first_name":"Olexandr","last_name":"Grydin","id":"43822","full_name":"Grydin, Olexandr"},{"full_name":"Frolov, Yaroslav","last_name":"Frolov","first_name":"Yaroslav"},{"last_name":"Schaper","id":"43720","full_name":"Schaper, Mirko","first_name":"Mirko"}],"title":"Laser beam melting of functionally graded materials with application-adapted tailoring of magnetic and mechanical performance","doi":"10.1016/j.msea.2021.141662"},{"author":[{"first_name":"Sudipta","full_name":"Pramanik, Sudipta","last_name":"Pramanik"},{"first_name":"Anatolii","full_name":"Andreiev, Anatolii","id":"50215","last_name":"Andreiev"},{"last_name":"Hoyer","id":"48411","full_name":"Hoyer, Kay-Peter","first_name":"Kay-Peter"},{"last_name":"Schaper","full_name":"Schaper, Mirko","id":"43720","first_name":"Mirko"}],"date_created":"2021-09-08T07:33:06Z","date_updated":"2023-06-01T14:40:01Z","doi":"10.1016/j.ijfatigue.2021.106498","title":"Quasi in-situ analysis of fracture path during cyclic loading of double-edged U notched additively manufactured FeCo alloy","quality_controlled":"1","publication_identifier":{"issn":["0142-1123"]},"publication_status":"published","citation":{"ieee":"S. Pramanik, A. Andreiev, K.-P. Hoyer, and M. Schaper, “Quasi in-situ analysis of fracture path during cyclic loading of double-edged U notched additively manufactured FeCo alloy,” International Journal of Fatigue, Art. no. 106498, 2021, doi: 10.1016/j.ijfatigue.2021.106498.","chicago":"Pramanik, Sudipta, Anatolii Andreiev, Kay-Peter Hoyer, and Mirko Schaper. “Quasi In-Situ Analysis of Fracture Path during Cyclic Loading of Double-Edged U Notched Additively Manufactured FeCo Alloy.” International Journal of Fatigue, 2021. https://doi.org/10.1016/j.ijfatigue.2021.106498.","ama":"Pramanik S, Andreiev A, Hoyer K-P, Schaper M. Quasi in-situ analysis of fracture path during cyclic loading of double-edged U notched additively manufactured FeCo alloy. International Journal of Fatigue. Published online 2021. doi:10.1016/j.ijfatigue.2021.106498","short":"S. Pramanik, A. Andreiev, K.-P. Hoyer, M. Schaper, International Journal of Fatigue (2021).","mla":"Pramanik, Sudipta, et al. “Quasi In-Situ Analysis of Fracture Path during Cyclic Loading of Double-Edged U Notched Additively Manufactured FeCo Alloy.” International Journal of Fatigue, 106498, 2021, doi:10.1016/j.ijfatigue.2021.106498.","bibtex":"@article{Pramanik_Andreiev_Hoyer_Schaper_2021, title={Quasi in-situ analysis of fracture path during cyclic loading of double-edged U notched additively manufactured FeCo alloy}, DOI={10.1016/j.ijfatigue.2021.106498}, number={106498}, journal={International Journal of Fatigue}, author={Pramanik, Sudipta and Andreiev, Anatolii and Hoyer, Kay-Peter and Schaper, Mirko}, year={2021} }","apa":"Pramanik, S., Andreiev, A., Hoyer, K.-P., & Schaper, M. (2021). Quasi in-situ analysis of fracture path during cyclic loading of double-edged U notched additively manufactured FeCo alloy. 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