Mathias Göken mostly deals with Metallurgy, Composite material, Microstructure, Nanoindentation and Indentation. As a part of the same scientific family, he mostly works in the field of Metallurgy, focusing on Pressing and, on occasion, Diffraction, Equiaxed crystals and Transmission electron microscopy. His study looks at the intersection of Composite material and topics like Mineralogy with Radius.
His work carried out in the field of Microstructure brings together such families of science as Alloy, Oxide, Lamellar structure and Base. Mathias Göken has researched Nanoindentation in several fields, including Indentation hardness and Elastic modulus. His Indentation study combines topics in areas such as Crystallography, Nanocrystalline material and Deformation mechanism.
His main research concerns Composite material, Metallurgy, Nanoindentation, Microstructure and Superalloy. His work focuses on many connections between Composite material and other disciplines, such as Crystallography, that overlap with his field of interest in Lattice. His Nanoindentation research includes elements of Scanning electron microscope, Elastic modulus, Young's modulus, Modulus and Nanocrystalline material.
His Microstructure research integrates issues from Solid solution, Lamellar structure, Plasticity, Transmission electron microscopy and Ductility. The Superalloy study combines topics in areas such as Atom probe, Volume fraction, Base, Crystallite and Creep. His studies deal with areas such as Deformation mechanism and Finite element method as well as Indentation.
His scientific interests lie mostly in Composite material, Microstructure, Superalloy, Alloy and Aluminium. His research links Metal with Composite material. His Microstructure study deals with Dislocation intersecting with Composite number, Nanocomposite and Strain hardening exponent.
His Alloy study is related to the wider topic of Metallurgy. In general Metallurgy study, his work on Magnesium often relates to the realm of Spectroscopy, thereby connecting several areas of interest. His Nanoindentation research is multidisciplinary, incorporating perspectives in Indentation, Compression, Copper and Nanocrystalline material.
His primary areas of investigation include Composite material, Superalloy, Aluminium, Accumulative roll bonding and Deformation mechanism. All of his Composite material and Deformation, Microstructure, Tension, Compression and Plasticity investigations are sub-components of the entire Composite material study. His Deformation study combines topics from a wide range of disciplines, such as Ultimate tensile strength, Indentation, Single crystal and Creep.
Alloy and Metallurgy are closely tied to his Superalloy research. His Aluminium research incorporates elements of Niobium, Nanoindentation, Brittleness, Titanium and Slip. His Deformation mechanism research includes themes of Frank-Read Source and Dislocation.
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Strain rate sensitivity of ultrafine-grained aluminium processed by severe plastic deformation
J. May;H.W. Höppel;M. Göken.
Scripta Materialia (2005)
Indentation size effect in metallic materials: Correcting for the size of the plastic zone
Karsten Durst;Björn Backes;Mathias Göken.
Scripta Materialia (2005)
High-performance direct conversion X-ray detectors based on sintered hybrid lead triiodide perovskite wafers
Shreetu Shrestha;René Fischer;Gebhard J. Matt;Patrick Feldner.
Nature Photonics (2017)
Indentation size effect in metallic materials: Modeling strength from pop-in to macroscopic hardness using geometrically necessary dislocations
Karsten Durst;Björn Backes;Oliver Franke;Mathias Göken.
Acta Materialia (2006)
Nanoindentation strain-rate jump tests for determining the local strain-rate sensitivity in nanocrystalline Ni and ultrafine-grained Al
Verena Maier;Karsten Durst;Johannes Mueller;Björn Backes.
Journal of Materials Research (2011)
Imaging and measurement of local mechanical material properties by atomic force acoustic microscopy
U. Rabe;S. Amelio;M. Kopycinska;S. Hirsekorn.
Surface and Interface Analysis (2002)
Enhanced Strength and Ductility in Ultrafine‐Grained Aluminium Produced by Accumulative Roll Bonding
Heinz Werner Höppel;Johannes May;Mathias Göken.
Advanced Engineering Materials (2004)
Microstructure and creep strength of different γ/γ′-strengthened Co-base superalloy variants
A. Bauer;S. Neumeier;S. Neumeier;F. Pyczak;M. Göken.
Scripta Materialia (2010)
Mechanical properties of copper/bronze laminates: Role of interfaces
Xiaolong Ma;Chongxiang Huang;Jordan Moering;Mathis Ruppert.
Acta Materialia (2016)
On the measurement of the nanohardness of the constitutive phases of TRIP-assisted multiphase steels
Q. Furnemont;M. Kempf;Pascal J. Jacques;M. Goken.
Materials Science and Engineering A-structural Materials Properties Microstructure and Processing (2002)
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