Magnetic Resonance Microscopy
Instrumentation and Applications in Engineering, Life Science, and Energy Research
1. Edition May 2022
464 Pages, Hardcover
29 Pictures (29 Colored Figures)
5 tables
Monograph
ISBN:
978-3-527-34760-5
Wiley-VCH, Weinheim
Short Description
This book provides an up-to-date overview of the methods, hardware and approaches in magnetic resonance microscopy. A wide range of applications are discussed in material science and engineering, life sciences and electrochemical systems.
Further versions
Part I DEVELOPMENTS IN HARDWARE AND METHODS
Magnet technology suitable for ultra high field NMR and MRI
Ceramic and metamaterial coils for MR microscopy
Micro-integrated gradient system for magnetic resonance microscopy
Advances and adventures with mobile NMR
Technology of a portable brain scanner for use in emergency medicine
Single-and-Multi-shot spatiotemporally encoded MRI
Sweep imaging with Fourier transformation: New developments and perspectives
Part II APPLICATIONS IN CHEMICAL ENGINEERING
Imaging of transport processes in biofilms
MRI of transport in food and fruit
MRI of filtration processes
Ultra-fast MR techniques to image multi-phase flows in pipes and trickle bed reactors
Part III APPLICATIONS IN LIFE SCIENCES
Magnetic Resonance Microscopy: a tool for imaging down to the subcellular level
MRI of single cells labelled with super paramagnetic iron oxide nanoparticles
Magnetic resonance studies of wood
3D imaging of flow pattern in natural porous media under low flow rate
Part IV Applications in Energy Research
Spectroscopic imaging of lithiation fronts in battery electrodes
Combining PFG-NMR and in situ MRI for salt distribution and diffusivity in battery electrolytes
Magnetic field map measurements as a diagnostic tool for the battery condition
Long-run in-operando NMR as a suitable tool for battery research
Perspectives
Magnet technology suitable for ultra high field NMR and MRI
Ceramic and metamaterial coils for MR microscopy
Micro-integrated gradient system for magnetic resonance microscopy
Advances and adventures with mobile NMR
Technology of a portable brain scanner for use in emergency medicine
Single-and-Multi-shot spatiotemporally encoded MRI
Sweep imaging with Fourier transformation: New developments and perspectives
Part II APPLICATIONS IN CHEMICAL ENGINEERING
Imaging of transport processes in biofilms
MRI of transport in food and fruit
MRI of filtration processes
Ultra-fast MR techniques to image multi-phase flows in pipes and trickle bed reactors
Part III APPLICATIONS IN LIFE SCIENCES
Magnetic Resonance Microscopy: a tool for imaging down to the subcellular level
MRI of single cells labelled with super paramagnetic iron oxide nanoparticles
Magnetic resonance studies of wood
3D imaging of flow pattern in natural porous media under low flow rate
Part IV Applications in Energy Research
Spectroscopic imaging of lithiation fronts in battery electrodes
Combining PFG-NMR and in situ MRI for salt distribution and diffusivity in battery electrolytes
Magnetic field map measurements as a diagnostic tool for the battery condition
Long-run in-operando NMR as a suitable tool for battery research
Perspectives
Dr. Sabina Haber-Pohlmeier was a scientist at the Institute of Macromolecular Chemistry at RTWH Aachen before moving to the University of Stuttgart, with close connections to the Research Center Jülich. Having received her PhD in chemistry from University of Bielefeld in the field of dynamic light scattering in the time and frequency domains she worked as a Lise Meitner Fellow on Small Angle X-ray Scattering (SAXS) before moving to the field of NMR. Her research focuses on relaxometry, especially fast field cycling relaxometry, of fluids in porous media, spatially resolved studies in soil-plant systems, investigation of transport processes and combination of MRI with complementary non-invasive tomographic methods such as neutron imaging. During her time in Aachen she spent several research stays at institutes in the USA, New Zealand and Canada.
Prof. Blümich is cofounder of the series of International Conferences on Magnetic Resonance Microscopy. He was Chair of Macromolecular Chemistry at RWTH Aachen University and is cofounder and director of Magritek Ltd., a manufacturer of tabletop NMR spectrometers and the NMR-MOUSE. His work aims at understanding the macroscopic properties of polymer and porous materials on a microscopic and molecular scale employing novel NMR methods and instrumentation. His recent work focuses on compact NMR instruments for non-destructive materials testing such as studies of tangible cultural heritage and for high-resolution spectroscopy for chemical analysis.
Luisa Ciobanu is currently Research Director at NeuroSpin, CEA-Saclay. She received her doctorate in Physics from the Ohio State University and has held research appointments at the Beckman Institute, University of Illinois at Urbana-Champaign and Pfizer, Inc. Her current research focuses on the development of new techniques for magnetic resonance imaging (MRI) at high and ultra-high magnetic fields for the understanding of fundamental physical principles underlying biological function.
Prof. Blümich is cofounder of the series of International Conferences on Magnetic Resonance Microscopy. He was Chair of Macromolecular Chemistry at RWTH Aachen University and is cofounder and director of Magritek Ltd., a manufacturer of tabletop NMR spectrometers and the NMR-MOUSE. His work aims at understanding the macroscopic properties of polymer and porous materials on a microscopic and molecular scale employing novel NMR methods and instrumentation. His recent work focuses on compact NMR instruments for non-destructive materials testing such as studies of tangible cultural heritage and for high-resolution spectroscopy for chemical analysis.
Luisa Ciobanu is currently Research Director at NeuroSpin, CEA-Saclay. She received her doctorate in Physics from the Ohio State University and has held research appointments at the Beckman Institute, University of Illinois at Urbana-Champaign and Pfizer, Inc. Her current research focuses on the development of new techniques for magnetic resonance imaging (MRI) at high and ultra-high magnetic fields for the understanding of fundamental physical principles underlying biological function.
