Your search keyword '"Marcin J. Kraśny"' showing total 3 results

1. Experimental assessment of clinical MRI-induced global SAR distributions in head phantoms

Author

Gideon Oluniran, Brendan Tuohy, James Blackwell, Niall Colgan, Michel Destrade, Marcin J. Kraśny, European Regional Development Fund, Enterprise Ireland, Irish Research Council, and College of Science, National University of Ireland Galway

Subjects

Scanner, Computer science, Biophysics, FOS: Physical sciences, MRI safety, General Physics and Astronomy, Condensed Matter - Soft Condensed Matter, Radiation Dosage, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Proton resonance, 0302 clinical medicine, Proton resonance frequency, Humans, Radiology, Nuclear Medicine and imaging, MR thermometry, skin and connective tissue diseases, Remote sensing, Protocol (science), Specific absorption rate, Phantoms, Imaging, business.industry, fungi, Rf transmission, General Medicine, Magnetic Resonance Imaging, Physics - Medical Physics, body regions, Duty cycle, 030220 oncology & carcinogenesis, Soft Condensed Matter (cond-mat.soft), Medical Physics (physics.med-ph), business, Head, Quality assurance

Abstract

Accurate estimation of SAR is critical to safeguarding vulnerable patients who require an MRI procedure. The increased static field strength and RF duty cycle capabilities in modern MRI scanners mean that systems can easily exceed safe SAR levels for patients. Advisory protocols routinely used to establish quality assurance protocols are not required to advise on the testing of MRI SAR levels and is not routinely measured in annual medical physics quality assurance checks. This study aims to develop a head phantom and protocol that can independently verify global SAR for MRI clinical scanners. A four-channel birdcage head coil was used for RF transmission and signal reception. Proton resonance shift thermometry was used to estimate SAR. The SAR estimates were verified by comparing results against two other independent measures, then applied to a further four scanners at field strengths of 1.5¿T and 3¿T. Scanner output SAR values ranged from 0.42 to 1.52¿W/kg. Percentage SAR differences between independently estimated values and those calculated by the scanners differed by 0-2.3%. We have developed a quality assurance protocol to independently verify the SAR output of MRI scanners. The project was co-financed by the European Regional Development Fund (ERDF) under Ireland’s European Structural, Investment Funds Programme 2014–2020 and Enterprise Ireland; Grant agreement: CF-2017-0826-P, Irish Research Council postgraduate scholarship GOIPG/2018/82 and the NUI Galway College of Science. Thank you to the NUI Galway Microbiology and physics department for their help creating the phantom. Authors would like to thank Maja Drapiewska and David Connolly from the NUI Galway College of Engineering and Informatics and Eileen Smith from Netzsch for help with DSC measurements. peer-reviewed 2020-10-05

Published

2020

2. Freeze cast porous barium titanate for enhanced piezoelectric energy harvesting

Author

Yan Zhang, Marcin J. Kraśny, John Taylor, R. W. C. Lewis, Christopher R. Bowen, and James Roscow

Subjects

energy harvesting, Permittivity, porosity, Materials science, Acoustics and Ultrasonics, FOS: Physical sciences, finite element analysis, 02 engineering and technology, Applied Physics (physics.app-ph), 01 natural sciences, 7. Clean energy, chemistry.chemical_compound, 0103 physical sciences, Figure of merit, freeze casting, Composite material, Porosity, 010302 applied physics, Poling, Physics - Applied Physics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, Piezoelectricity, Ferroelectricity, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry, Barium titanate, piezoelectric, 0210 nano-technology

Abstract

Energy harvesting is an important developing technology for a new generation of self-powered sensor networks. This paper demonstrates the significant improvement in the piezoelectric energy harvesting performance of barium titanate by forming highly aligned porosity using freeze casting. Firstly, a finite element model demonstrating the effect of pore morphology and angle with respect to poling field on the poling behaviour of porous ferroelectrics was developed. A second model was then developed to understand the influence of microstructure-property relationships on the poling behaviour of porous freeze cast ferroelectric materials and their resultant piezoelectric and energy harvesting properties. To compare with model predictions, porous barium titanate was fabricated using freeze casting to form highly aligned microstructures with excellent longitudinal piezoelectric strain coefficients, d 33. The freeze cast barium titanate with 45 vol.% porosity had a d 33 = 134.5 pC N-1 compared to d 33 = 144.5 pC N-1 for dense barium titanate. The d 33 coefficients of the freeze cast materials were also higher than materials with uniformly distributed spherical porosity due to improved poling of the aligned microstructures, as predicted by the models. Both model and experimental data indicated that introducing porosity provides a large reduction in the permittivity () of barium titanate, which leads to a substantial increase in energy harvesting figure of merit, , with a maximum of 3.79 pm2 N-1 for barium titanate with 45 vol.% porosity, compared to only 1.40 pm2 N-1 for dense barium titanate. Dense and porous barium titanate materials were then used to harvest energy from a mechanical excitation by rectification and storage of the piezoelectric charge on a capacitor. The porous barium titanate charged the capacitor to a voltage of 234 mV compared to 96 mV for the dense material, indicating a 2.4-fold increase that was similar to that predicted by the energy harvesting figures of merit.

Published

2019

3. Energy harvesting from coupled bending-twisting oscillations in carbon-fibre reinforced polymer laminates

Author

Christopher R. Bowen, Marcin J. Kraśny, Mustafa Arafa, Andrew Rhead, Mengying Xie, and Yan Zhang

Subjects

Frequency response, Work (thermodynamics), Materials science, Cantilever, Aerospace Engineering, FOS: Physical sciences, 02 engineering and technology, Bending, 01 natural sciences, 0103 physical sciences, Composite material, Civil and Structural Engineering, 010302 applied physics, Condensed Matter - Materials Science, Mechanical Engineering, Materials Science (cond-mat.mtrl-sci), 021001 nanoscience & nanotechnology, Piezoelectricity, Computer Science Applications, Vibration, Control and Systems Engineering, Signal Processing, Physics::Accelerator Physics, 0210 nano-technology, Energy harvesting, Beam (structure)

Abstract

The energy harvesting capability of resonant harvesting structures, such as piezoelectric cantilever beams, can be improved by utilizing coupled oscillations that generate favourable strain mode distributions. In this work, we present the first demonstration of the use of a laminated carbon fibre reinforced polymer to create cantilever beams that undergo coupled bending-twisting oscillations for energy harvesting applications. Piezoelectric layers that operate in bending and shear mode are attached to the bend-twist coupled beam surface at locations of maximum bending and torsional strains in the first mode of vibration to fully exploit the strain distribution along the beam. Modelling of this new bend-twist harvesting system is presented, which compares favourably with experimental results. It is demonstrated that the variety of bend and torsional modes of the harvesters can be utilized to create a harvester that operates over a wider range of frequencies and such multi-modal device architectures provides a unique approach to tune the frequency response of resonant harvesting systems.

Published

2019