12/2024
	M. B. Khan, K. Schäfer, F. Hofmann, M. Lutzi, E. S. Oliveros Mata, O. Pylypovskyi, D. Makarov, and O. Gutfleisch Bioinspired Design, Fabrication, and Wing Morphing of 3D Printed Magnetic Butterflies Adv. Intell. Syst. 2400620 (2024). URL PDF

11/2024
	O. Bezsmertna, R. Xu, O. Pylypovskyi, D. Raftrey, A. Sorrentino, J. A. Fernandez-Roldan, I. Soldatov, D. Wolf, A. Lubk, R. Schäfer, P. Fischer, and D. Makarov Magnetic Solitons in Hierarchical 3D Magnetic Nanoarchitectures of Nanoflower Shape Nano Letters 24, 15774 (2024). URL PDF

11/2024
	R. Pedan, I. Kruhlov, P. Makushko, O. Dubikovskyi, O. Kosulya, A. Orlov, A. Bodnaruk, V. Golub, F. Munnik, R. Hübner, D. Makarov, and I. Vladymyrskyi The effect of Ar+ and N+ ion irradiation on the thermally induced evolution of the structural and magnetic properties of Co/Pt and Pt/Co bilayered stacks MaterChemPhys 327, 129862 (2024). URL PDF

10/2024
	J. Schmidtpeter, P. T. Das, Y. Zabila, C. Schubert, T. Gundrum, T. Wondrak and D. Makarov Exchange-Biased Multiring Planar Hall Magnetoresistive Sensors With Nanotesla Resolution in Nonshielded Environments IEEE Magn. Lett. 15, 4100205 (2024). URL

10/2024
	P. Rickhaus, O. V. Pylypovskyi, G. Seniutinas, V. Borras, P. Lehmann, K. Wagner, L. Zaper, P. J. Prusik, P. Makushko, I. Veremchuk, T. Kosub, R. Hübner, D. D. Sheka, P. Maletinsky, and D. Makarov Antiferromagnetic nanoscale bit arrays of magnetoelectric Cr2O3 thin films Nano Letters 24, 13172 (2024). URL PDF

09/2024
	L. Guo, R. Xu, and D. Makarov Printable magnetoresistive sensors: A crucial step toward unconventional magnetoelectronics Chinese Journal of Structural Chemistry 100428 (2024). URL

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

10/2024	Paper featured as back inside cover of Journal of Materials Chemistry A
	Our paper on the realisation of printed recyclable magnetoelectronics is highlighted as back inside cover of Journal of Materials Chemistry A. We have developed printable magnetic field sensors with full recyclability. The printing technology streamlines the fabrication process, resulting in reduced energy consumption and equipment investments. Additionally, the circularity of materials at the end of the sensors' lifespan minimizes environmental footprint. With energy-efficient fabrication and material circularity minimizing environmental impact, our sensors hold significant promise for Internet of Things (IoT) applications requiring a multitude of low-cost sensors for real-time data exchange. This potential is exemplified by the integration of magnetic sensing in smart home systems. This work is result of fruitful cooperation of the HZDR team with the group of Prof. Yuhan Wu (Shenyang University of Technology, Shenyang, China). X. Wang, L. Guo, O. Bezsmertna, Y. Wu, D. Makarov, and R. Xu Printed magnetoresistive sensors for recyclable magnetoelectronics J. Mater. Chem. A 12, 24906 (2024). URL PDF

10/2024

Paper featured as back inside cover of Journal of Materials Chemistry A

Our paper on the realisation of printed recyclable magnetoelectronics is highlighted as back inside cover of Journal of Materials Chemistry A.

We have developed printable magnetic field sensors with full recyclability. The printing technology streamlines the fabrication process, resulting in reduced energy consumption and equipment investments. Additionally, the circularity of materials at the end of the sensors' lifespan minimizes environmental footprint. With energy-efficient fabrication and material circularity minimizing environmental impact, our sensors hold significant promise for Internet of Things (IoT) applications requiring a multitude of low-cost sensors for real-time data exchange. This potential is exemplified by the integration of magnetic sensing in smart home systems.

This work is result of fruitful cooperation of the HZDR team with the group of Prof. Yuhan Wu (Shenyang University of Technology, Shenyang, China).

X. Wang, L. Guo, O. Bezsmertna, Y. Wu, D. Makarov, and R. Xu
Printed magnetoresistive sensors for recyclable magnetoelectronics
J. Mater. Chem. A 12, 24906 (2024). URL PDF

03/2024	Paper featured as a cover of Nature Electronics
	Our paper on the discovery of the nonlinear Hall effect in elementary Bi thin films is highlighted as a cover of Nature Electronics. We demonstrate that in the elemental (semi)metal bismuth, the room-temperature nonlinear Hall effect is generated by surface states that are characterized by a Berry curvature triple: a quantity governing a skew scattering effect that generates non-linear transverse currents. The strength of nonlinear Hall effect can be controlled on demand using an extrinsic classical shape effect: the geometric nonlinear Hall effect. We performed high harmonic generation experiments to show the potential of polycrystalline Bi thin films for optoelectronic applications in the terahertz (THz) spectral domain. This work is result of fruitful cooperation of the HZDR team with the group of Prof. Carmine Ortix (University of Salerno, Italy). P. Makushko, S. Kovalev, Y. Zabila, I. Ilyakov, A. Ponomaryov, A. Arshad, G. L. Prajapati, T. V. A. G. de Oliveira, J.-C. Deinert, P. Chekhonin, I. Veremchuk, T. Kosub, Y. Skourski, F. Ganss, D. Makarov, C. Ortix A tunable room-temperature nonlinear Hall effect in elemental bismuth thin films Nature Electronics 7, 207 (2024). URL PDF

03/2024

Paper featured as a cover of Nature Electronics

Our paper on the discovery of the nonlinear Hall effect in elementary Bi thin films is highlighted as a cover of Nature Electronics.

We demonstrate that in the elemental (semi)metal bismuth, the room-temperature nonlinear Hall effect is generated by surface states that are characterized by a Berry curvature triple: a quantity governing a skew scattering effect that generates non-linear transverse currents. The strength of nonlinear Hall effect can be controlled on demand using an extrinsic classical shape effect: the geometric nonlinear Hall effect. We performed high harmonic generation experiments to show the potential of polycrystalline Bi thin films for optoelectronic applications in the terahertz (THz) spectral domain.

This work is result of fruitful cooperation of the HZDR team with the group of Prof. Carmine Ortix (University of Salerno, Italy).

P. Makushko, S. Kovalev, Y. Zabila, I. Ilyakov, A. Ponomaryov, A. Arshad, G. L. Prajapati, T. V. A. G. de Oliveira, J.-C. Deinert, P. Chekhonin, I. Veremchuk, T. Kosub, Y. Skourski, F. Ganss, D. Makarov, C. Ortix
A tunable room-temperature nonlinear Hall effect in elemental bismuth thin films
Nature Electronics 7, 207 (2024). URL PDF

11/2023	Paper featured as a back cover of the Advanced Sensor Research
	Our paper on the development of a modular droplet-based fluidics for the realization of large volume libraries of codes for Lab-On-Chip systems is highlighted as a back cover of the Advanced Sensor Research. We propose and validate a concept for a multiparametric library of multi-droplet codes in fluidics, where information is stored in different physical and chemical properties like concentration of magnetic content, droplet volume and ionic concentration. The concept allows coding of more than 1 million droplets using available lab scale fluidic equipment, which makes it relevant for large high-throughput screening assays in drug discovery. This work is result of fruitful cooperation with the group of Prof. Lior Klein (Bar-Ilan University, Israel) and Dr. Asaf Grosz (Ben-Gurion University of the Negev, Israel). J. Schütt, H. Nhalil, J. Fassbender, L. Klein, A. Grosz, D. Makarov Modular Droplet-Based Fluidics for Large Volume Libraries of Individual Multiparametric Codes in Lab-On-Chip Systems Advanced Sensor Research 2300101 (2023). URL PDF

11/2023

Paper featured as a back cover of the Advanced Sensor Research

Our paper on the development of a modular droplet-based fluidics for the realization of large volume libraries of codes for Lab-On-Chip systems is highlighted as a back cover of the Advanced Sensor Research.

We propose and validate a concept for a multiparametric library of multi-droplet codes in fluidics, where information is stored in different physical and chemical properties like concentration of magnetic content, droplet volume and ionic concentration. The concept allows coding of more than 1 million droplets using available lab scale fluidic equipment, which makes it relevant for large high-throughput screening assays in drug discovery.

This work is result of fruitful cooperation with the group of Prof. Lior Klein (Bar-Ilan University, Israel) and Dr. Asaf Grosz (Ben-Gurion University of the Negev, Israel).

J. Schütt, H. Nhalil, J. Fassbender, L. Klein, A. Grosz, D. Makarov
Modular Droplet-Based Fluidics for Large Volume Libraries of Individual Multiparametric Codes in Lab-On-Chip Systems
Advanced Sensor Research 2300101 (2023). URL PDF

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Shapeable Magnetic Sensorics

Recent Highlights