Shapeable Magnetic Sensorics
There is a trend in electronics towards becoming shapeable (flexible, stretchable or printable), which allows electronic components to be arbitrarily reshaped after fabrication. This unique feature offers new unexplored functionalities for the markets of consumer electronics and eMobility. Shapeable electronics and optoelectronics have been developed already for a few years.
Very recently, we added a new member to this family - the shapeable magnetic sensorics, which pave the way towards the development of a unique class of devices with important functionality being not only shapeable and fast, but also with the ability to react and respond to a magnetic field. Shapeable magnetic sensor devices could enable the fabrication of, e.g. health monitoring systems, where large-angle folding of the micrometer-sized functional elements is a crucial prerequisite for a successful implementation.
In the ERC project SMaRT we aim to develop shapeable magnetoelectronics to the industry-ready product and integrate these magnetic field sensorics into flexible large area multifunctional devices consisting of flexible batteries, communication modules and different types of sensing elements, e.g. environmental, chemical, temperature.
Recent Highlights
01/2023 | Paper featured as a font cover page of JACS |
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![]() | Our paper on the development of a new method to prepare high-quality films of the two-dimensional conjugated coordination polymer Cu-BHT is highlighted with the front cover page of Journal of the American Chemical Society (JACS). We developed a solvent-free chemical vapor deposition method to prepare high-quality films of the two-dimensional conjugated coordination polymer Cu-BHT (BHT = benzenehexanothiolate). The restricted metal ion mobility during the vapor–solid reaction enables high-resolution patterning via both bottom-up lithography, including the fabrication of micron-sized Hall bar and electrode patterns to accurately evaluate the conductivity and mobility values of the Cu-BHT films. Crystalline coordination polymers with high electrical conductivities and charge carrier mobilities might open new opportunities for electronic devices. This work is a result of fruitful cooperation between the Helmholtz-Zentrum Dresden-Rossendorf e.V., Dresden University of Technology, Katholieke Universiteit Leuven and Deutsches Elektronen-Synchrotron DESY. V. Rubio-Giménez, G. Arnauts, M. Wang, E. S. Oliveros Mata, X. Huang, T. Lan, M. L. Tietze, D. E. Kravchenko, J. Smets, N. Wauteraerts, A. Khadiev, D. V. Novikov, D. Makarov, R. Dong, and R. AmelootChemical Vapor Deposition and High-Resolution Patterning of a Highly Conductive Two-Dimensional Coordination Polymer Film Journal of the American Chemical Society 145, 152 (2023). URL |
10/2022 | Paper featured as a back cover page of Advanced Materials Technologies |
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![]() | Our paper on the realization of dispenser printed Bi-based magnetic field sensors is highlighted with a back cover page of Advanced Materials Technologies. We present dispenser printing of magnetic field sensors based on commodity scale Bismuth powder. Benefiting from the non-saturating large magnetoresistance effect, this technology enables scalable large area printing of sensors with broad detection range on flexible and rigid substrates. Our technology could be applied for in-mold electronics, yielding shapeable custom-made sensors that can be geometrically adapted for lamination over uneven surfaces. Profiting from the high versatility in design and substrate material, we demonstrate magnetically controlled interactive devices based on a printed array of sensors, to be used for interactive advertisement, smart wallpapers, and security input panels. This work is a result of fruitful cooperation between the Helmholtz-Zentrum Dresden-Rossendorf e.V. and Fraunhofer Institute IKTS in Dresden (group of Dr. Mykola Vinnichenko). E. S. Oliveros Mata, C. Voigt, G. S. Cañón Bermúdez, Y. Zabila, N. M. Valdez-Garduño, M. Fritsch, S. Mosch, M. Kusnezoff, J. Fassbender, M. Vinnichenko, and D. MakarovDispenser printed bismuth-based magnetic field sensors with non-saturating large magnetoresistance for touchless interactive surfaces Adv. Mater. Technol. 7, 2200227 (2022). URL PDF |
06/2021 | Paper featured as a back cover page of Advanced Functional Materials |
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![]() | Our paper on the realization of flexible magnetoreceptors with tunable intrinsic logic for on-skin touchless human-machine interfaces is highlighted with a back cover page of Advanced Functional Materials. Artificial magnetoception, i.e., electronically expanding human perception to detect magnetic fields, is a new and yet unexplored way for interacting with our surroundings. Here, we present skin-compliant touchless interactive devices based on spin-valves with out-of-plane sensitivity to magnetic fields. These devices reveal tunable logic characteristics, as needed for intuitive, energy efficient and insensitive to external magnetic disturbances magnetoreceptive human-machine interfaces. This work is a result of a fruitful cooperation between the Helmholtz-Zentrum Dresden-Rossendorf e.V., Università Politecnica delle Marche (group of Prof. Gianni Barucca), Politecnico di Milano (group of Prof. Christian Rinaldi), University of Augsburg (group of Prof. Manfred Albrecht), and CNR Istituto di Struttura della Materia (group of Dr. Gaspare Varvaro). P. Makushko, E. S. Oliveros Mata, G. S. Cañón Bermúdez, M. Hassan, S. Laureti, C. Rinaldi, F. Fagiani, G. Barucca, N. Schmidt, Y. Zabila, T. Kosub, R. Illing, O. Volkov, I. Vladymyrskyi, J. Fassbender, M. Albrecht, G. Varvaro, and D. MakarovFlexible magnetoreceptor with tunable intrinsic logic for on-skin touchless human-machine interfaces Adv. Funct. Mater. 31, 2101089 (2021). URL PDF |
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