Other disciplines of study, such as Microelectromechanical systems and Electrical engineering, are mixed together with his Nanotechnology studies. He applies his multidisciplinary studies on Electrical engineering and Nanotechnology in his research. His work often combines Optoelectronics and Optics studies. His work often combines Optics and Optoelectronics studies. While working on this project, he studies both Radiology and Magnetic resonance imaging. His research on Layer (electronics) often connects related areas such as Composite material. He regularly ties together related areas like Layer (electronics) in his Composite material studies. In his research, he performs multidisciplinary study on Nuclear magnetic resonance and Magnetic resonance imaging.
His Nanotechnology studies intersect with other disciplines such as Electrical engineering and Microfluidics. He performs multidisciplinary study on Electrical engineering and Nanotechnology in his works. As part of his studies on Pathology, Jan G. Korvink often connects relevant subjects like Fabrication. His Fabrication study frequently links to adjacent areas such as Alternative medicine. Many of his studies on Alternative medicine involve topics that are commonly interrelated, such as Pathology. By researching both Radiology and Magnetic resonance imaging, Jan G. Korvink produces research that crosses academic boundaries. Magnetic resonance imaging and Radiology are two areas of study in which Jan G. Korvink engages in interdisciplinary research.
His study focuses on the intersection of Scaffold and fields such as Biomedical engineering with connections in the field of Tissue engineering. In his articles, he combines various disciplines, including Tissue engineering and Biomedical engineering. Many of his Metallurgy research pursuits overlap with Copper and Chemical engineering. He connects Copper with Electroplating in his study. He performs integrative Chemical engineering and Metallurgy research in his work. His Thermodynamics study frequently intersects with other fields, such as Heat exchanger and Power (physics). His Power (physics) study frequently links to adjacent areas such as Thermodynamics. His Electrical engineering research is intertwined with Miniaturization and Detector. His Detector study frequently links to related topics such as Electrical engineering.
Jan G. Korvink performs integrative Composite material and Fiber research in his work. By researching both Fiber and Composite material, Jan G. Korvink produces research that crosses academic boundaries. Jan G. Korvink integrates Nanotechnology with Biochemical engineering in his research. While working on this project, Jan G. Korvink studies both Biochemical engineering and Nanotechnology. Tissue engineering and Genetics are commonly linked in his work. His research ties Stem cell and Genetics together. His Stem cell study frequently draws connections between related disciplines such as Cell biology. His research on Cell biology often connects related areas such as Regeneration (biology). Jan G. Korvink performs integrative study on Regeneration (biology) and Regenerative medicine.
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Printed electronics: the challenges involved in printing devices, interconnects, and contacts based on inorganic materials
Jolke Perelaer;Patrick J. Smith;Dario Mager;Daniel Soltman.
Journal of Materials Chemistry (2010)
Cascaded digital lattice Boltzmann automata for high Reynolds number flow.
Martin Geier;Andreas Greiner;Jan G. Korvink.
Physical Review E (2006)
Parallel imaging in non-bijective, curvilinear magnetic field gradients: a concept study.
Jürgen Hennig;Anna Masako Welz;Gerrit Schultz;Jan G. Korvink.
Magnetic Resonance Materials in Physics Biology and Medicine (2008)
Review: Automatic Model Reduction for Transient Simulation of MEMS‐based Devices
Evgenii B. Rudnyi;Jan G. Korvink.
Sensors Update (2002)
MEMS: A Practical Guide to Design, Analysis, and Applications
Jan G Korvink;Oliver Paul.
A fully MEMS-compatible process for 3D high aspect ratio micro coils obtained with an automatic wire bonder
K Kratt;V Badilita;T Burger;J G Korvink.
Journal of Micromechanics and Microengineering (2010)
Efficient optimization of transient dynamic problems in MEMS devices using model order reduction
Jeong Sam Han;Evgenii B Rudnyi;Jan G Korvink.
Journal of Micromechanics and Microengineering (2005)
Model order reduction for large scale engineering models developed in ANSYS
Evgenii B. Rudnyi;Jan G. Korvink.
parallel computing (2004)
Terahertz metamaterials fabricated by inkjet printing
Markus Walther;Alex Ortner;Henning Meier;Ute Löffelmann.
Applied Physics Letters (2009)
A hyperpolarized equilibrium for magnetic resonance
Jan-Bernd Hövener;Niels Schwaderlapp;Thomas Lickert;Simon B. Duckett.
Nature Communications (2013)
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