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Kern, Michal

Michal Kern

Dr. rer. nat.

Gruppenleiter "Magnetische Resonanz und Spintronik"
Institut für Intelligente Sensorik und Theoretische Elektrotechnik

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+49 711 685 67280
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Pfaffenwaldring 47
70569 Stuttgart
Deutschland
Raum: 3.113

Publikationen

Zeitschriften, Konferenzen und Bücher:

2025
1. J. Lettens et al., “Integration of electrically detected magnetic resonance on a chip (EDMRoC) with charge pumping for low-cost and sensitive defect characterization in silicon carbide metal–oxide–semiconductor field-effect transistors,” Journal of Applied Physics, vol. 137, Art. no. 6, Feb. 2025, doi: 10.1063/5.0245349.
  BibTeX
  @article{Lettens_2025, author = {Lettens, Jan and Avramenko, Marina and Vandevenne, Ilias and Chu, Anh and Hengel, Philipp and Kern, Michal and Anders, Jens and Moens, Peter and Goovaerts, Etienne and Cambré, Sofie}, doi = {10.1063/5.0245349}, issn = {1089-7550}, journal = {Journal of Applied Physics}, month = {02}, number = 6, publisher = {AIP Publishing}, title = {Integration of electrically detected magnetic resonance on a chip (EDMRoC) with charge pumping for low-cost and sensitive defect characterization in silicon carbide metal–oxide–semiconductor field-effect transistors}, url = {http://dx.doi.org/10.1063/5.0245349}, volume = 137, year = 2025 }
  Link
  http://dx.doi.org/10.1063/5.0245349
  DOI
  10.1063/5.0245349
2. H. Lotfi, Q. Yang, T. Elrifai, M. Kern, and J. Anders, “An Energy-Efficient Microwave Magnetic Field Generator for NV Center Quantum Magnetometers Based on an Array of Four Injection-Locked VCOs,” in 2025 9th IEEE Electron Devices Technology & Manufacturing Conference (EDTM), Mar. 2025, pp. 1–3. doi: 10.1109/EDTM61175.2025.11041390.
  - BibTeX
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  BibTeX
  @inproceedings{11041390, abstract = {This paper proposes the use of chip-integrated LC voltage-controlled oscillators (VCOs) as the $B_{1}$ field source in NV diamond-based magnetometers. VCOs provide a compact, energy-efficient solution by directly converting DC power into the microwave $B_{1}$ field required for NV center control, bypassing conventional RF amplification stages. Additionally, the VCO's intrinsic frequency agility, enabled by the varactor inside the LC tank, which simultaneously changes the resonant frequency of the LC resonator and the oscillation frequency, ensures a near-constant $B_{1}$ field across the tuning range. Current state-of-the-art chip-integrated diamond magnetometers, while showing promising results, typically make use of classical transmitter architectures, in general, providing a lower energy efficiency compared to the presented VCO-based approach. With its very good energy efficiency, the proposed VCO-based approach offers a path to scalable, low-power NV-based magnetometers suitable for portable and embedded applications. To provide a sufficiently large active area for typical diamond samples, the presented VCO-based $B_{1}$ generator uses an array of four injection-locked VCOs. An on-chip phase-locked loop (PLL) precisely defines the frequency of the $B_{1}$ field from an external reference. The design is validated using electrical measurements that reflect the key metrics of the target quantum magnetometry application.}, author = {Lotfi, Hadi and Yang, Qing and Elrifai, Tarek and Kern, Michal and Anders, Jens}, booktitle = {2025 9th IEEE Electron Devices Technology & Manufacturing Conference (EDTM)}, doi = {10.1109/EDTM61175.2025.11041390}, month = {03}, pages = {1-3}, title = {An Energy-Efficient Microwave Magnetic Field Generator for NV Center Quantum Magnetometers Based on an Array of Four Injection-Locked VCOs}, year = 2025 }
  DOI
  10.1109/EDTM61175.2025.11041390
3. H. Lotfi, Q. Yang, M. Kern, and J. Anders, “A VCO-based EPR Sensor Featuring a Large 400 µm Coil to Enhance MW B1 Homogeneity and Concentration Sensitivity,” in 2025 IEEE International Symposium on Circuits and Systems (ISCAS), May 2025, pp. 1–5. doi: 10.1109/ISCAS56072.2025.11043483.
  - BibTeX
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  @inproceedings{11043483, abstract = {We present a voltage-controlled oscillator (VCO)-based electron paramagnetic resonance (EPR) sensor featuring an enhanced sensing area for a high concentration sensitivity and improved homogeneity compared to conventional, chip-integrated planar sensors. Prior designs have relied on VCO-array configurations to expand the sensing area, which comes at the cost of increased power consumption. Here, the relatively small diameters of the individual coil elements limit the homogeneous region in the direction perpendicular to the chip surface. To address these limitations, we propose the use of inductance-capacitance (LC) VCO-based EPR detectors with large coil diameters with a laser-fabricated hole to create a large sensitive volume with high homogeneity of the microwave B1 field inside the coil. Despite the enlarged coil diameter and the correspondingly large inductance, the VCO-based detector achieves a low phase noise (PN) of -116 dBc/Hz at a 1 MHz offset from a center frequency of 6.75 GHz, and a 10 % frequency tuning range. The presented sensor frontend incorporates the VCO-based EPR detector inside an integer-N phase-locked loop (PLL), enabling precise phase and frequency control from an external low-frequency reference. The C-band operation of the presented VCO-based EPR detector is compatible with the static magnetic fields achievable with compact permanent magnets. The proposed sensor is electrically characterized and validated in the target EPR application using standard EPR samples of BDPA (α, γ-bisdiphenylene-β-phenylallyl) and TEM-POL (2,2,6,6-tetramethyl-4-hydroxy-piperidine-1-oxyl), achieving a spin sensitivity of 5 × 109 spins/(G Hz1/2) and concentration sensitivity of 15.6 µM/(G Hz1/2), respectively.}, author = {Lotfi, Hadi and Yang, Qing and Kern, Michal and Anders, Jens}, booktitle = {2025 IEEE International Symposium on Circuits and Systems (ISCAS)}, doi = {10.1109/ISCAS56072.2025.11043483}, issn = {2158-1525}, month = {05}, pages = {1-5}, title = {A VCO-based EPR Sensor Featuring a Large 400 µm Coil to Enhance MW B1 Homogeneity and Concentration Sensitivity}, year = 2025 }
  DOI
  10.1109/ISCAS56072.2025.11043483
4. J. E. McPeak et al., “Operando detection of dissolved oxygen in fluid solution using a submersible rapid scan EPR on a chip dipstick sensor,” Scientific Reports, vol. 15, Art. no. 1, Mar. 2025, doi: 10.1038/s41598-025-93591-4.
  BibTeX
  @article{McPeak2025, abstract = {Electron paramagnetic resonance (EPR) is an accurate and efficient technique to probe unpaired electrons in many applications across materials science, chemistry, and biology. Dynamic processes are investigated using EPR; however, these applications are limited by the use of resonator-based spectrometers such that the entire process must be confined to the resonator. The EPR-on-a-chip (EPRoC) device circumvents this limitation by integrating the entire EPR spectrometer into a single microchip. In this approach, the coil of a voltage-controlled oscillator (VCO) is used as the microwave source and detector simultaneously, operating under a protective coating such that the device may be placed in the sample solution directly. Additionally, improvements in sensitivity via rapid scan EPR (RS-EPR/RS-EPRoC) increase the accessible applications where SNR per measurement time is the fundamental limit. The herein reported device combines a dipstick EPRoC sensor with the enhanced sensitivity of frequency-swept frequency modulated rapid scan to measure triarylmethyl (trityl, Ox071) oxygen-sensitive probes dissolved in aqueous solutions. EPR spectra of Ox071 solutions were recorded using the RS-EPRoC sensor while varying the oxygen concentration of the solution between normal atmosphere and after purging the solution with nitrogen gas. We demonstrate that EPRoC may be employed to monitor dissolved oxygen in fluid solution in an online fashion.}, author = {McPeak, Joseph E. and Segantini, Michele and Marcozzi, Gianluca and Dona, Irene and K{\"u}nstner, Silvio and Chu, Anh and Kern, Michal and Poncelet, Martin and Driesschaert, Benoit and Anders, Jens and Lips, Klaus}, day = 21, doi = {10.1038/s41598-025-93591-4}, issn = {2045-2322}, journal = {Scientific Reports}, month = {03}, number = 1, pages = 9872, title = {Operando detection of dissolved oxygen in fluid solution using a submersible rapid scan EPR on a chip dipstick sensor}, url = {https://doi.org/10.1038/s41598-025-93591-4}, volume = 15, year = 2025 }
  Link
  https://doi.org/10.1038/s41598-025-93591-4
  DOI
  10.1038/s41598-025-93591-4
5. Q. Yang, H. Lotfi, F. Dreyer, M. Kern, B. Blümich, and J. Anders, “A Portable Chip-Based Overhauser DNP Platform for Biomedical Liquid Sample Analysis,” IEEE Transactions on Biomedical Circuits and Systems, vol. 19, Art. no. 2, Apr. 2025, doi: 10.1109/TBCAS.2024.3521033.
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  @article{10811975, abstract = {Low-field nuclear magnetic resonance (NMR) instruments are an indispensable tool in industrial research and quality control. However, the intrinsically low spin polarization at low magnetic fields severely limits their detection sensitivity and measurement throughput, preventing their widespread use in biomedical analysis. Overhauser dynamic nuclear polarization (ODNP) effectively addresses this problem by transferring the spin polarization from free electrons to protons, significantly enhancing sensitivity. In this paper, we explore the potential of using ODNP for signal enhancement in a custom-designed portable chip-based DNP-enhanced NMR platform, which is centered around a miniaturized microwave (MW) transmitter, a custom-designed NMR-on-a-chip transceiver, and two application-specific ODNP probes. The MW transmitter provides frequency synthesis, signal modulation, and power amplification, providing sufficient output power for efficient polarization transfer. The NMR-on-a-chip transceiver combines a radio frequency (RF) transmitter with a fully differential quadrature receiver, providing pulsed excitation and NMR signal down-conversion and amplification. Two custom-designed ODNP probes are used for proof-of-concept DNP-enhanced NMR relaxometry and spectroscopy measurements. The presented chip-based ODNP platform achieves a maximum MW output power of $34 \textrm{dBm}$, resulting in a signal enhancement of $-162$ using the relaxometry ODNP probe with $1.4 \mu\textrm{L}$ of $10 \textrm{mM}$ non-degassed TEMPOL solution, and an enhancement of $-63$ with the spectroscopy ODNP probe using $50 \textrm{nL}$ of the same solution. The proton polarization was increased from $0.5\times 10^{-6}$ to $81\times 10^{-6}$ at a low field of $0.16 \textrm{T}$. Proof-of-concept measurements on radical-doped tattoo inks and acetic acid verify the potential of our chip-based ODNP platform for the analysis of biologically and medically relevant parameters such as relaxation times, chemical shifts, and hyperfine interactions.}, author = {Yang, Qing and Lotfi, Hadi and Dreyer, Frederik and Kern, Michal and Blümich, Bernhard and Anders, Jens}, doi = {10.1109/TBCAS.2024.3521033}, issn = {1940-9990}, journal = {IEEE Transactions on Biomedical Circuits and Systems}, month = {04}, number = 2, pages = {257-269}, title = {A Portable Chip-Based Overhauser DNP Platform for Biomedical Liquid Sample Analysis}, volume = 19, year = 2025 }
  DOI
  10.1109/TBCAS.2024.3521033
2024
1. A. R. Altenhof, Q. Yang, M. Kern, S. G. Newman, J. Anders, and M. W. Malone, “A high-volume resonator for L-band DNP-NMR,” Journal of Magnetic Resonance, vol. 368, p. 107788, Nov. 2024, doi: 10.1016/j.jmr.2024.107788.
  BibTeX
  @article{Altenhof_2024, author = {Altenhof, Adam R. and Yang, Qing and Kern, Michal and Newman, Shaun G. and Anders, Jens and Malone, Michael W.}, doi = {10.1016/j.jmr.2024.107788}, issn = {1090-7807}, journal = {Journal of Magnetic Resonance}, month = {11}, pages = 107788, publisher = {Elsevier BV}, title = {A high-volume resonator for L-band DNP-NMR}, url = {http://dx.doi.org/10.1016/j.jmr.2024.107788}, volume = 368, year = 2024 }
  Link
  http://dx.doi.org/10.1016/j.jmr.2024.107788
  DOI
  10.1016/j.jmr.2024.107788
2. M. Kern, A. Chu, and J. Anders, “Current Trends in VCO-Based EPR,” Applied Magnetic Resonance, Aug. 2024, doi: 10.1007/s00723-024-01698-0.
  BibTeX
  @article{Kern2024, abstract = {In this article we provide an overview of chip-integrated voltage-controlled oscillator (VCO)-based EPR detection as a new paradigm in EPR sensing. After a brief motivation for this alternative detection method, we provide a self-contained overview of the detection principle, both for continuous-wave and pulsed detection. Based on this introduction, we will highlight the advantages and disadvantages of VCO-based detection compared to conventional resonator-based detection. This is followed by an overview of the current state of the art in VCO-based EPR and interesting emerging applications of the technology. The paper concludes with a brief summary and outlook on future research directions.}, author = {Kern, Michal and Chu, Anh and Anders, Jens}, day = 19, doi = {10.1007/s00723-024-01698-0}, issn = {1613-7507}, journal = {Applied Magnetic Resonance}, month = {08}, title = {Current Trends in VCO-Based EPR}, url = {https://doi.org/10.1007/s00723-024-01698-0}, year = 2024 }
  Link
  https://doi.org/10.1007/s00723-024-01698-0
  DOI
  10.1007/s00723-024-01698-0
3. S. Künstner et al., “Monitoring the state of charge of vanadium redox flow batteries with an EPR-on-a-Chip dipstick sensor,” Phys. Chem. Chem. Phys., vol. 26, Art. no. 25, 2024, doi: 10.1039/D4CP00373J.
  BibTeX
  @article{D4CP00373J, abstract = {The vanadium redox flow battery (VRFB) is considered a promising candidate for large-scale energy storage in the transition from fossil fuels to renewable energy sources. VRFBs store energy by electrochemical reactions of different electroactive species dissolved in electrolyte solutions. The redox couples of VRFBs are VO2+/VO2+ and V2+/V3+{,} the ratio of which to the total vanadium content determines the state of charge (SOC). V(iv) and V(ii) are paramagnetic half-integer spin species detectable and quantifiable with electron paramagnetic resonance spectroscopy (EPR). Common commercial EPR spectrometers{,} however{,} employ microwave cavity resonators which necessitate the use of large electromagnets{,} limiting their application to dedicated laboratories. For an SOC monitoring device for VRFBs{,} a small{,} cost-effective submersible EPR spectrometer{,} preferably with a permanent magnet{,} is desirable. The EPR-on-a-Chip (EPRoC) spectrometer miniaturises the complete EPR spectrometer onto a single microchip by utilising the coil of a voltage-controlled oscillator as both microwave source and detector. It is capable of sweeping the frequency while the magnetic field is held constant enabling the use of small permanent magnets. This drastically reduces the experimental complexity of EPR. Hence{,} the EPRoC fulfils the requirements for an SOC sensor. We{,} therefore{,} evaluate the potential for utilisation of an EPRoC dipstick spectrometer as an operando and continuously online monitor for the SOC of VRFBs. Herein{,} we present quantitative proof-of-principle submersible EPRoC experiments on variably charged vanadium electrolyte solutions. EPR data obtained with a commercial EPR spectrometer are in good agreement with the EPRoC data.}, author = {Künstner, Silvio and McPeak, Joseph E. and Chu, Anh and Kern, Michal and Dinse, Klaus-Peter and Naydenov, Boris and Fischer, Peter and Anders, Jens and Lips, Klaus}, doi = {10.1039/D4CP00373J}, journal = {Phys. Chem. Chem. Phys.}, number = 25, pages = {17785-17795}, publisher = {The Royal Society of Chemistry}, title = {Monitoring the state of charge of vanadium redox flow batteries with an EPR-on-a-Chip dipstick sensor}, url = {http://dx.doi.org/10.1039/D4CP00373J}, volume = 26, year = 2024 }
  Link
  http://dx.doi.org/10.1039/D4CP00373J
  DOI
  10.1039/D4CP00373J
4. S. Künstner et al., “Microwave field mapping for EPR-on-a-chip experiments,” Science Advances, vol. 10, Art. no. 33, 2024, doi: 10.1126/sciadv.ado5467.
  BibTeX
  @article{doi:10.1126/sciadv.ado5467, abstract = {Electron paramagnetic resonance–on-a-chip (EPRoC) devices use small voltage-controlled oscillators (VCOs) for both the excitation and detection of the EPR signal, allowing access to unique sample environments by lifting the restrictions imposed by resonator-based EPR techniques. EPRoC devices have been successfully used at multiple frequencies (7 to 360 gigahertz) and have demonstrated their utility in producing high-resolution spectra in a variety of spin centers. To enable quantitative measurements using EPRoC devices, the spatial distribution of the B1 field produced by the VCOs must be known. As an example, the field distribution of a 12-coil VCO array EPRoC operating at 14 gigahertz is described in this study. The frequency modulation–recorded EPR spectra of a “point”-like and a thin-film sample were investigated while varying the position of both samples in three directions. The results were compared to COMSOL simulations of the B1-field intensity. The EPRoC array sensitive volume was determined to be ~19 nanoliters. Implications for possible EPR applications are discussed. High-resolution spatial mapping of the microwave field enables quantitative EPR on chip measurements.}, author = {Künstner, Silvio and McPeak, Joseph E. and Chu, Anh and Kern, Michal and Wick, Markus and Dinse, Klaus-Peter and Anders, Jens and Naydenov, Boris and Lips, Klaus}, doi = {10.1126/sciadv.ado5467}, eprint = {https://www.science.org/doi/pdf/10.1126/sciadv.ado5467}, journal = {Science Advances}, number = 33, pages = {eado5467}, title = {Microwave field mapping for EPR-on-a-chip experiments}, url = {https://www.science.org/doi/abs/10.1126/sciadv.ado5467}, volume = 10, year = 2024 }
  Link
  https://www.science.org/doi/abs/10.1126/sciadv.ado5467
  DOI
  10.1126/sciadv.ado5467
5. H. Lotfi et al., “An S-band SiGe BiCMOS Transmitter for an NV Center Based Quantum Magnetometer,” in 2024 IEEE International Symposium on Circuits and Systems (ISCAS), May 2024, pp. 1–5. doi: 10.1109/ISCAS58744.2024.10558502.
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  @inproceedings{10558502, abstract = {The excellent performance of quantum magnetometers based on nitrogen-vacancy (NV) centers in diamond, including their high sensitivity, their wide dynamic range, and the possibility for a calibration-free operation, renders them a very promising alternative to classical magnetic field sensors. However, existing lab prototypes of NV center sensors still suffer from a large volume and non-scalable manufacturing technologies. To mitigate this problem, in this paper, we present a miniaturized and scalable microwave electronics platform for quantum magnetometry based on an S-band SiGe BiCMOS transmitter (TX) chip and a custom-designed resonator manufactured on a microwave printed circuit board. The fabricated TX chip can deliver a high saturated output power of 19dBm at a center frequency of 2.87GHz over a wide relative bandwidth of 38.3% of the center frequency to a 50Ω load while occupying a compact die area of 0.593mm2. To manipulate the spin state of NV centers efficiently, we use two of the presented TX chips to drive a newly proposed differential resonator, which provides microwave magnetic fields of B1=179μT over a large active area of 18.48×104 μm2. Continuous-wave and pulsed optically detected magnetic resonance (ODMR) measurements are used to verify the excellent performance of the proposed platform compared to the state-of-the-art. In these experiments, the presented platform produced Rabi frequencies up to 5.81MHz.}, author = {Lotfi, Hadi and Kern, Michal and Unden, Thomas and Scharpf, Jochen and Schwartz, Ilai and Neumann, Philipp and Anders, Jens}, booktitle = {2024 IEEE International Symposium on Circuits and Systems (ISCAS)}, doi = {10.1109/ISCAS58744.2024.10558502}, issn = {2158-1525}, month = {05}, pages = {1-5}, title = {An S-band SiGe BiCMOS Transmitter for an NV Center Based Quantum Magnetometer}, year = 2024 }
  DOI
  10.1109/ISCAS58744.2024.10558502
6. H. Lotfi et al., “A Four-Channel BiCMOS Transmitter for a Quantum Magnetometer Based on Nitrogen-Vacancy Centers in Diamond,” IEEE Journal of Solid-State Circuits, vol. 59, Art. no. 5, May 2024, doi: 10.1109/JSSC.2024.3350995.
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  @article{10409187, abstract = {Quantum sensors based on solid-state defects, such as the nitrogen-vacancy (NV) center in diamond, offer very good room-temperature sensitivity, long-term stability, and the potential for calibration-free measurements. However, most quantum sensors still suffer from a bulky size and weight, low energy efficiency, and high costs, prohibiting their widespread use. Here, we present custom-designed chip-integrated microwave (MW) electronics for a miniaturized, low-cost, and highly scalable quantum magnetometer based on NV centers in diamond. The presented electronics include a quadrature phase-locked loop (QPLL) chip to generate the required local oscillator signal at around 7 GHz with a wide tuning range of 22% and a low phase noise (PN) of −122 dBc/Hz at 1-MHz offset from a 7-GHz carrier for broadband low-noise magnetometry. In addition, the magnetometer electronics comprise a 4-channel transmitter chip, which can provide currents up to 412 mApp into a custom-designed inductor over a wide frequency range from 6.4 to 8 GHz. In combination with a custom-designed coil, manufactured on a glass substrate for optical transparency, which features a large active area of ( $\pi { \times } 180 { \times }180~\mu \text {m}^{2}$ ), this current is sufficient to produce strong MW magnetic fields up to $B_{{1}} = (1/2) \cdot B_{\text {ac}} = 170~{\mu \mathrm {T}}$ , enabling pulsed optically detected magnetic resonance (ODMR) experiments. In proof-of-concept ODMR experiments, the presented chip-based spin control system produces fast Rabi oscillations of 5.49 MHz. The measured dc and ac magnetic field limits of detection (LOD) of the presented magnetometer are 32 nT/Hz $^{\text {1/2}}$ and 300 pT/Hz $^{\text {1/2}}$ , respectively.}, author = {Lotfi, Hadi and Kern, Michal and Yang, Qing and Unden, Thomas and Striegler, Nico and Scharpf, Jochen and Schalberger, Patrick and Stöhr, Rainer and Schwartz, Ilai and Neumann, Philipp and Anders, Jens}, doi = {10.1109/JSSC.2024.3350995}, issn = {1558-173X}, journal = {IEEE Journal of Solid-State Circuits}, month = {05}, number = 5, pages = {1421-1432}, title = {A Four-Channel BiCMOS Transmitter for a Quantum Magnetometer Based on Nitrogen-Vacancy Centers in Diamond}, volume = 59, year = 2024 }
  DOI
  10.1109/JSSC.2024.3350995
7. L. Marti et al., “Towards optical MAS magnetic resonance using optical traps,” Journal of Magnetic Resonance Open, vol. 18, p. 100145, 2024, doi: https://doi.org/10.1016/j.jmro.2023.100145.
  BibTeX
  @article{MARTI2024100145, abstract = {Higher magic angle spinning (MAS) frequencies than currently available are desirable to improve spectral resolution in NMR and EPR systems. While conventional strategies employ pneumatic spinning limited by fluid dynamics, this paper demonstrates the development of an optical spinning technique in which vacuum quality dictates the maximum achievable spinning frequency. Using optical traps, we levitated a range of micron-sized samples. Under vacuum we achieved optical rotation of a single ∼10 μm diameter particle of vaterite at several mbar up to hundreds of Hz and of 20 μm diameter SiO2 particles at ≤10−2 mbar at several kHz. At ambient conditions, we optically levitated γ-irradiated alanine particles of 20–50 μm diameter. Additionally, using a single chip EPR detector operating at 11 GHz, we measured the EPR spectrum for a 30 μm γ-irradiated alanine particle in contact with the chip surface (i.e., without optical levitation) in a single scan lasting 92 s. These observations suggest that a γ-irradiated alanine particle having a diameter in the order of 30 μm is a promising candidate for our aim of demonstrating the first magnetic resonance experiment on optically levitated samples. Furthermore, we discuss strategies, limitations, and the potential of implementing MAS with optical traps for NMR and EPR.}, author = {Marti, Lea and {Şahin Solmaz}, Nergiz and Kern, Michal and Chu, Anh and Farsi, Reza and Hengel, Philipp and Gao, Jialiang and Alaniva, Nicholas and Urban, Michael A. and Gunzenhauser, Ronny and Däpp, Alexander and Klose, Daniel and Anders, Jens and Boero, Giovanni and Novotny, Lukas and Frimmer, Martin and Barnes, Alexander B.}, doi = {https://doi.org/10.1016/j.jmro.2023.100145}, issn = {2666-4410}, journal = {Journal of Magnetic Resonance Open}, pages = 100145, title = {Towards optical MAS magnetic resonance using optical traps}, url = {https://www.sciencedirect.com/science/article/pii/S2666441023000535}, volume = 18, year = 2024 }
  Link
  https://www.sciencedirect.com/science/article/pii/S2666441023000535
  DOI
  https://doi.org/10.1016/j.jmro.2023.100145
8. E. Shabratova et al., “Towards an EPR on a Chip Spectrometer for Monitoring Radiation Damage During X-ray Absorption Spectroscopy,” Applied Magnetic Resonance, Sep. 2024, doi: 10.1007/s00723-024-01702-7.
  BibTeX
  @article{Shabratova2024, abstract = {Electron paramagnetic resonance (EPR) spectroscopy is an essential tool to investigate the effects of ionizing radiation, which is routinely administered for reducing contaminations and waste in food products and cosmetics as well as for sterilization in industry and medicine. In materials research, EPR methods are not only employed as a spectroscopic method of structural investigations, but also have been employed for detection of changes in electronic structure due to radiation damage from high energy X-rays, for example, to monitor radical formation inside biomolecules caused by X-ray irradiation at carbon, nitrogen, and oxygen K-edges at synchrotron facilities. Here a compact EPR spectrometer, based on EPR-on-a-chip (EPRoC) sensor and a portable electromagnet, has been developed as a solution for monitoring radiation damage of samples during their investigation by X-ray absorption spectroscopy (XAS) at synchrotron facilities. A portable electromagnet with a soft iron core and forced air temperature stabilization was constructed as the source of the external magnetic field. The sweep range of magnetic field inside the most homogeneous region of the portable electromagnet is 12--290 mT. The compact spectrometer performance was evaluated by placing the EPRoC sensor inside either a commercial electromagnet or the portable electromagnet to record the EPR spectrum of tempol, irradiated alanine, and dilithium phthalocyanine (Li2Pc). The potential performance of the portable spectrometer for the detection of radiation damage in organic compounds and transition metal-containing catalysts during XAS measurements in both fluorescence and transmission modes was calculated with promising implications for measurements after implementation in a synchrotron-based XAS spectrometer.}, author = {Shabratova, Ekaterina and Lotfi, Hadi and Sakr, Ayman and Hassan, Mohamed Atef and Kern, Michal and Neeb, Matthias and Gr{\"u}neberger, Ren{\'e} and Klemke, Bastian and Marcozzi, Gianluca and Kiefer, Klaus and Tsarapkin, Aleksei and H{\"o}flich, Katja and Dittwald, Alina and Denker, Andrea and Anders, Jens and McPeak, Joseph E. and Lips, Klaus}, day = 03, doi = {10.1007/s00723-024-01702-7}, issn = {1613-7507}, journal = {Applied Magnetic Resonance}, month = {09}, title = {Towards an EPR on a Chip Spectrometer for Monitoring Radiation Damage During X-ray Absorption Spectroscopy}, url = {https://doi.org/10.1007/s00723-024-01702-7}, year = 2024 }
  Link
  https://doi.org/10.1007/s00723-024-01702-7
  DOI
  10.1007/s00723-024-01702-7
9. Q. Yang, H. Lotfi, F. Dreyer, M. Kern, and J. Anders, “A Miniaturized Chip-based ODNP Platform,” in 2024 IEEE International Symposium on Circuits and Systems (ISCAS), May 2024, pp. 1–5. doi: 10.1109/ISCAS58744.2024.10558466.
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  @inproceedings{10558466, abstract = {In this paper, we present a miniaturized chip-based Overhauser dynamic nuclear polarization (ODNP) platform for enhancing detection sensitivity and, thereby, improving the achievable limit of detection. The presented system uses three custom-designed ASICs for the excitation and the detection of the NMR signal as well as the generation and preamplification of the required microwave (MW) signal. A commercial baredie GaN power amplifier is used in addition to achieve the driving strength of up to 26 dBm at 7 GHz required for the target ODNP application. Moreover, the wide bandwidth of the custom-designed, printed MW Alderman-Grant (AG) resonator allows for an indirect measurement of the electron spin resonance (ESR) signal of the utilized DNP agent without the need for an additional ESR spectrometer. Overall, the presented system achieves an ODNP enhancement factor of 50 with an active volume of 500 nL, the latter number improving the state-of-the-art in chip-based ODNP platforms by a factor of 500×.}, author = {Yang, Qing and Lotfi, Hadi and Dreyer, Frederik and Kern, Michal and Anders, Jens}, booktitle = {2024 IEEE International Symposium on Circuits and Systems (ISCAS)}, doi = {10.1109/ISCAS58744.2024.10558466}, issn = {2158-1525}, month = {05}, pages = {1-5}, title = {A Miniaturized Chip-based ODNP Platform}, year = 2024 }
  DOI
  10.1109/ISCAS58744.2024.10558466
10. Q. Yang et al., “A miniaturized dual-mode continuous-wave and pulsed pumping ODNP platform,” Journal of Magnetic Resonance Open, vol. 21, p. 100174, Dec. 2024, doi: 10.1016/j.jmro.2024.100174.
  BibTeX
  @article{Yang_2024, author = {Yang, Qing and Lotfi, Hadi and Kern, Michal and Dreyer, Frederik and Jouda, Mazin and Korvink, Jan. G. and Blümich, Bernhard and Anders, Jens}, doi = {10.1016/j.jmro.2024.100174}, issn = {2666-4410}, journal = {Journal of Magnetic Resonance Open}, month = {12}, pages = 100174, publisher = {Elsevier BV}, title = {A miniaturized dual-mode continuous-wave and pulsed pumping ODNP platform}, url = {http://dx.doi.org/10.1016/j.jmro.2024.100174}, volume = 21, year = 2024 }
  Link
  http://dx.doi.org/10.1016/j.jmro.2024.100174
  DOI
  10.1016/j.jmro.2024.100174
11. Q. Yang et al., “A chip-based C-band ODNP platform,” Journal of Magnetic Resonance, vol. 358, p. 107603, 2024, doi: https://doi.org/10.1016/j.jmr.2023.107603.
  BibTeX
  @article{YANG2024107603, abstract = {In this paper, we present a chip-based C-band ODNP platform centered around an NMR-on-a-chip transceiver and a printed microwave (MW) Alderman-Grant (AG) coil with a broadband tunable frequency range of 528MHz. The printable ODNP probe is optimized for a high input-power-to-magnetic-field conversion-efficiency, achieving a measured ODNP enhancement factor of −151 at microwave power levels of 33.3dBm corresponding to 2.1W. NMR measurements with and without microwave irradiation verify the functionality and the state-of-the-art performance of the proposed ODNP platform. The wide tuning range of the system allows for indirect measurements of the EPR signal of the DNP agent by sweeping the microwave excitation frequency and recording the resulting NMR signal. This feature can, e.g., be used to detect line broadening of the DNP agent. Moreover, we demonstrate experimentally that the wide tuning range of the new ODNP platform can be used to perform multi-tone microwave excitation for further signal enhancement: Using a 10mM TEMPOL solution, we improved the enhancement by a factor of two.}, author = {Yang, Qing and Zhao, Jianyu and Dreyer, Frederik and Krüger, Daniel and Chu, Anh and Kern, Michal and Blümich, Bernhard and Anders, Jens}, doi = {https://doi.org/10.1016/j.jmr.2023.107603}, issn = {1090-7807}, journal = {Journal of Magnetic Resonance}, pages = 107603, title = {A chip-based C-band ODNP platform}, url = {https://www.sciencedirect.com/science/article/pii/S1090780723002380}, volume = 358, year = 2024 }
  Link
  https://www.sciencedirect.com/science/article/pii/S1090780723002380
  DOI
  https://doi.org/10.1016/j.jmr.2023.107603
2023
1. A. Chu, M. Kern, K. Khan, K. LiPS, and J. Anders, “A 263GHz 32-Channel EPR-on-a-Chip Injection-Locked VCO-Array,” in 2023 IEEE International Solid- State Circuits Conference (ISSCC), Feb. 2023, pp. 20–22. doi: 10.1109/ISSCC42615.2023.10067623.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{10067623, abstract = {Electron paramagnetic resonance (EPR) spectroscopy is a powerful technique that uses the spin of an unpaired electron as a nanoscopic probe inside a molecule to extract information about its chemical structure and composition as well as its surroundings via small changes in its resonance frequency, see Fig. 21.4.1 (left). EPR has applications in studying and monitoring a wide range of materials, starting from defects in semiconductors over free radicals in the blood to metal catalysts in hydrogen fuel production. EPR measurements are typically performed in moderate static magnetic fields around 0.3T, corresponding to EPR frequencies around $9\mathsf{GHz}$. This combination of field and frequency is commonly used due to the relative ease of generation of 0 $3\mathsf{T}$ magnetic fields with sufficient homogeneity as well as the required $9\mathsf{GHz}$ frequency signal. However, access to higher frequencies and fields is strongly desirable due to higher spin polarization (with corresponding increased signal amplitude), higher spectral resolution, which allows, e.g., the determination of electronic and geometric structures of active centers in enzymes, and access to higher energy electronic transitions, such as those found in metal complexes or materials interesting for antiferromagnetic spintronics, explaining the ongoing research towards high-frequency EPR (HFEPR) with operating frequencies beyond $90\mathsf{GHz}$. Here, another strong driver of HFEPR is the field of dynamic nuclear polarization (DNP), a method that can be used to boost the relatively poor sensitivity of nuclear magnetic resonance (NMR) by transferring the intrinsically higher electron polarization to the nuclear spins. Today, there are only a few commercial HFEPR-based DNP spectrometers on the market, with the most popular ones operating at an EPR frequency of $263\mathsf{GHz}(9.4\mathsf{T})$, corresponding to a proton NMR frequency of $400\mathsf{MHz}$. These instruments use gyrotron as the source for the mm-wave magnetic field ($\mathsf{B}_{1}$ field) and cost far beyond 1 million €.}, author = {Chu, Anh and Kern, Michal and Khan, Khubaib and LiPS, Klaus and Anders, Jens}, booktitle = {2023 IEEE International Solid- State Circuits Conference (ISSCC)}, doi = {10.1109/ISSCC42615.2023.10067623}, issn = {2376-8606}, month = {02}, pages = {20-22}, title = {A 263GHz 32-Channel EPR-on-a-Chip Injection-Locked VCO-Array}, year = 2023 }
  DOI
  10.1109/ISSCC42615.2023.10067623
2. M. Kern, T. Klotz, M. Spiess, P. Mavridis, B. Blümich, and J. Anders, “Dead Time-Free Detection of NMR Signals Using Voltage-Controlled Oscillators,” Applied Magnetic Resonance, vol. 54, Art. no. 11, Dec. 2023, doi: 10.1007/s00723-023-01599-8.
  BibTeX
  @article{Kern2023, abstract = {In this paper, we introduce voltage-controlled oscillators (VCOs) as a new type of nuclear magnetic resonance (NMR) detector, enabling dead time-free detection of NMR signals after an excitation pulse as well as the real-time inductive detection of Rabi oscillations during the pulse. Together with the theory of operation, we present the details of a custom-designed prototype implementation of a VCO-based NMR detector with an operating frequency around 62 MHz. The proof-of-concept measurements obtained with this prototype clearly demonstrate the possibility of performing dead time-free NMR experiments with coherent spin manipulation. Moreover, we also experimentally verified the capability of VCO-based detectors for performing real-time inductive detection of Rabi oscillations during the excitation pulse.}, author = {Kern, Michal and Klotz, Tobias and Spiess, Maximilian and Mavridis, Petros and Bl{\"u}mich, Bernhard and Anders, Jens}, day = 01, doi = {10.1007/s00723-023-01599-8}, issn = {1613-7507}, journal = {Applied Magnetic Resonance}, month = {12}, number = 11, pages = {1649--1662}, title = {Dead Time-Free Detection of NMR Signals Using Voltage-Controlled Oscillators}, url = {https://doi.org/10.1007/s00723-023-01599-8}, volume = 54, year = 2023 }
  Link
  https://doi.org/10.1007/s00723-023-01599-8
  DOI
  10.1007/s00723-023-01599-8
3. K. Khan, M. A. Hassan, M. Kern, and J. Anders, “A 12.2 − 14.9 GHz amplitude-sensitive VCO-based EPR-on-a-chip detector achieving a spin sensitivity of 6 × 109 spins/ √ Hz,” in 2023 18th European Microwave Integrated Circuits Conference (EuMIC), IEEE, Sep. 2023. doi: 10.23919/eumic58042.2023.10288693.
  BibTeX
  @inproceedings{Khan_2023, author = {Khan, Khubaib and Hassan, Mohamed Atef and Kern, Michal and Anders, Jens}, booktitle = {2023 18th European Microwave Integrated Circuits Conference (EuMIC)}, doi = {10.23919/eumic58042.2023.10288693}, month = {09}, publisher = {IEEE}, title = {A 12.2 − 14.9 GHz amplitude-sensitive VCO-based EPR-on-a-chip detector achieving a spin sensitivity of 6 × 109 spins/ √ Hz}, url = {http://dx.doi.org/10.23919/EuMIC58042.2023.10288693}, year = 2023 }
  Link
  http://dx.doi.org/10.23919/EuMIC58042.2023.10288693
  DOI
  10.23919/eumic58042.2023.10288693
4. H. Lotfi et al., “A Diamond Quantum Magnetometer Based on a Chip-Integrated 4-way Transmitter in 130-nm SiGe BiCMOS,” in 2023 IEEE Radio Frequency Integrated Circuits Symposium (RFIC), Jun. 2023, pp. 253–256. doi: 10.1109/RFIC54547.2023.10186184.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{10186184, abstract = {Solid-state magnetometers based on color centers in diamond are emerging as one of the leading quantum sensors due to their outstanding room-temperature properties, such as high sensitivity and calibration-free long-term stability. However, their integration into compact systems is still an active area of research. To tackle this challenge, in this paper, we present a quantum magnetometer based on negatively charged nitrogen-vacancy (NV) centers using a custom-designed, chip-integrated 4-way transmitter. In combination with a custom-designed microcoil array, the 4-way transmitter delivers microwave magnetic fields up to 226 µT for carrier frequencies around 7 GHz with a conversion gain of ≥32 dB to NV centers. The local oscillator (LO) signal required to drive the on-chip quadrature upconversion mixer is generated by a custom-designed quadrature PLL, which provides a 22% tuning range between 6.4 and 8 GHz, and a low phase noise of -122 dBc/Hz at 1 MHz offset from a 7 GHz carrier, to enable broadband, low-noise magnetometry. To verify the excellent performance of the integrated electronics, we have embedded them into a widefield diamond magnetometer using off-chip scanning optics, achieving a state-of-the-art AC-magnetic field limit of detection of 300 pT/Hz1/2.}, author = {Lotfi, Hadi and Kern, Michal and Striegler, Nico and Unden, Thomas and Scharpf, Jochen and Schalberger, Patrick and Schwartz, Ilai and Neumann, Philipp and Anders, Jens}, booktitle = {2023 IEEE Radio Frequency Integrated Circuits Symposium (RFIC)}, doi = {10.1109/RFIC54547.2023.10186184}, issn = {2375-0995}, month = {06}, pages = {253-256}, title = {A Diamond Quantum Magnetometer Based on a Chip-Integrated 4-way Transmitter in 130-nm SiGe BiCMOS}, year = 2023 }
  DOI
  10.1109/RFIC54547.2023.10186184
2022
1. H. S. Funk et al., “Composition and magnetic properties of thin films grown by interdiffusion of Mn and Sn-Rich, Ge lattice matched SixGe1-x-ySny layers,” Journal of Magnetism and Magnetic Materials, vol. 546, p. 168731, Mar. 2022, doi: 10.1016/j.jmmm.2021.168731.
  BibTeX
  @article{Funk_2022, author = {Funk, Hannes S. and Kern, Michal and Wei{\ss}haupt, David and Sürgers, Christoph and Fischer, Inga A. and Oehme, Michael and van Slageren, Joris and Schulze, Jörg}, doi = {10.1016/j.jmmm.2021.168731}, journal = {Journal of Magnetism and Magnetic Materials}, month = {03}, pages = 168731, publisher = {Elsevier {BV}}, title = {Composition and magnetic properties of thin films grown by interdiffusion of Mn and Sn-Rich, Ge lattice matched {SixGe}1-x-{ySny} layers}, url = {https://doi.org/10.1016%2Fj.jmmm.2021.168731}, volume = 546, year = 2022 }
  Link
  https://doi.org/10.1016%2Fj.jmmm.2021.168731
  DOI
  10.1016/j.jmmm.2021.168731
2. M. A. Hassan et al., “Towards single-cell pulsed EPR using VCO-based EPR-on-a-chip detectors,” Frequenz, vol. 76, Art. no. 11–12, 2022, doi: doi:10.1515/freq-2022-0096.
  BibTeX
  @article{HassanKernChuKalraShabratovaTsarapkinMacKinnonLipsTeutloffBittlKorvinkAnders+2022+699+717, author = {Hassan, Mohamed Atef and Kern, Michal and Chu, Anh and Kalra, Gatik and Shabratova, Ekaterina and Tsarapkin, Aleksei and MacKinnon, Neil and Lips, Klaus and Teutloff, Christian and Bittl, Robert and Korvink, Jan Gerrit and Anders, Jens}, doi = {doi:10.1515/freq-2022-0096}, journal = {Frequenz}, number = {11-12}, pages = {699--717}, title = {Towards single-cell pulsed EPR using VCO-based EPR-on-a-chip detectors}, url = {https://doi.org/10.1515/freq-2022-0096}, volume = 76, year = 2022 }
  Link
  https://doi.org/10.1515/freq-2022-0096
  DOI
  doi:10.1515/freq-2022-0096
3. K. Khan et al., “A 12.2 to 14.9 GHz injection-locked VCO array with an on-chip 50 MHz BW semi-digital PLL for transient spin manipulation and detection,” in 2022 IEEE 65th International Midwest Symposium on Circuits and Systems (MWSCAS), Aug. 2022, pp. 1–4. doi: 10.1109/MWSCAS54063.2022.9859288.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{9859288, abstract = {We present an injection-locked 12.2 to 14.9 GHz VCO array with an on-chip large bandwidth semi-digital PLL for the real-time manipulation and detection of electron spins. With its large bandwidth of 50 MHz, the on-chip PLL allows for the precise control of the phase of the electron spins from an external reference. Moreover, we demonstrate experimentally that the spin signal can be measured with high sensitivity outside the PLL loop bandwidth by FM demodulation of the frequency-divided VCO output signal. The system was manufactured in 40nm bulk CMOS technology and its versatility and performance are verified in continuous-wave, rapid scan, and pulsed EPR experiments. In these experiments, it achieves a competitive spin sensitivity of $6 \times 10^{10}$ spins/$\surd {Hz}$ over a large sensitive volume of 180 nl. Moreover, the presented system, for the first time, allowed for the real-time inductive detection of Rabi oscillations as well as an intrinsically dead-time-free detection of free induction decays (FIDs) after an excitation pulse.}, author = {Khan, Khubaib and Hassan, Mohamed Atef and Kern, Michal and Lips, Klaus and Schwartz, Ilai and Plenio, Martin and Jelezko, Fedor and Anders, Jens}, booktitle = {2022 IEEE 65th International Midwest Symposium on Circuits and Systems (MWSCAS)}, doi = {10.1109/MWSCAS54063.2022.9859288}, issn = {1558-3899}, month = {08}, pages = {1-4}, title = {A 12.2 to 14.9 GHz injection-locked VCO array with an on-chip 50 MHz BW semi-digital PLL for transient spin manipulation and detection}, year = 2022 }
  DOI
  10.1109/MWSCAS54063.2022.9859288
4. H. Lotfi, M. A. Hassan, M. Kern, and J. Anders, “A Compact C-band EPR-on-a-chip Transceiver in 130-nm SiGe BiCMOS,” in 2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME), Jun. 2022, pp. 157–160. doi: 10.1109/PRIME55000.2022.9816822.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{9816822, abstract = {We present a chip-integrated C-band transceiver for electron paramagnetic resonance (EPR) spectroscopy, implemented in a 130-nm SiGe BiCMOS technology. The presented EPR-on-a-chip transceiver displays an excellent minimum in-band noise Figure of 0.82 dB and a peak in-band output power $P_{\mathrm{sat}}$ of 9.8 dBm. Furthermore, the presented chip provides a wide operating frequency range from 6 GHz to 8 GHz, which is crucial for detecting wideband EPR signals. The receiver and two-stage four-way combined power amplifier provide (conversion) gains of 32.8 dB and 13 dB, respectively. In proof-of-concept EPR measurements using an off-chip PCB coil as a detector and the standard EPR sample BDPA ($\alpha,\gamma$-bisdiphenylene-$\beta$-phenylallyl), the presented chip achieves a competitive spin sensitivity of $8\times 10^{10}$ spins/$\sqrt{\mathrm{Hz}}$ over an active volume of 31 n1.}, author = {Lotfi, Hadi and Hassan, Mohamed Atef and Kern, Michal and Anders, Jens}, booktitle = {2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME)}, doi = {10.1109/PRIME55000.2022.9816822}, month = {06}, pages = {157-160}, title = {A Compact C-band EPR-on-a-chip Transceiver in 130-nm SiGe BiCMOS}, year = 2022 }
  DOI
  10.1109/PRIME55000.2022.9816822
5. A. Sakr, M. A. Hassan, K. Khan, M. Kern, and J. Anders, “A distributed amplitude control loop for VCO-array-based EPR-on-a-chip detectors,” in 2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME), Jun. 2022, pp. 13–16. doi: 10.1109/PRIME55000.2022.9816840.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{9816840, abstract = {This paper presents an amplitude control loop (ACL) for VCO-array-based electron paramagnetic resonance (EPR) detectors. The proposed ACL enhances the microwave magnetic field (B1) stability over the whole VCO frequency sweep range, against different sample environments and at varying experimental conditions. By introducing a distributed amplitude detection scheme, the proposed ACL implementation can regulate B1 field intensities in injection-locked VCO arrays with reduced loading effects and minimal phase noise degradation. Extracted-level circuit simulations on an example VCO array implementation demonstrate the functionality and excellent achievable performance of the proposed approach.}, author = {Sakr, Ayman and Hassan, Mohamed Atef and Khan, Khubaib and Kern, Michal and Anders, Jens}, booktitle = {2022 17th Conference on Ph.D Research in Microelectronics and Electronics (PRIME)}, doi = {10.1109/PRIME55000.2022.9816840}, month = {06}, pages = {13-16}, title = {A distributed amplitude control loop for VCO-array-based EPR-on-a-chip detectors}, year = 2022 }
  DOI
  10.1109/PRIME55000.2022.9816840
2021
1. A. Chu et al., “On the modeling of amplitude-sensitive electron spin resonance (ESR) detection using voltage-controlled oscillator (VCO)-based ESR-on-a-chip detectors,” Magnetic Resonance, vol. 2, Art. no. 2, Sep. 2021, doi: 10.5194/mr-2-699-2021.
  BibTeX
  @article{2021, author = {Chu, Anh and Schlecker, Benedikt and Kern, Michal and Goodsell, Justin L. and Angerhofer, Alexander and Lips, Klaus and Anders, Jens}, doi = {10.5194/mr-2-699-2021}, journal = {Magnetic Resonance}, month = {09}, number = 2, pages = {699--713}, publisher = {Copernicus {GmbH}}, title = {On the modeling of amplitude-sensitive electron spin resonance ({ESR}) detection using voltage-controlled oscillator ({VCO})-based {ESR}-on-a-chip detectors}, url = {https://doi.org/10.5194%2Fmr-2-699-2021}, volume = 2, year = 2021 }
  Link
  https://doi.org/10.5194%2Fmr-2-699-2021
  DOI
  10.5194/mr-2-699-2021
2. A. V. Funes et al., “Single Molecule Magnet Features in the Butterfly CoIII2LnIII2 Pivalate Family with Alcohol-Amine Ligands,” European Journal of Inorganic Chemistry, vol. 2021, Art. no. 31, 2021, doi: https://doi.org/10.1002/ejic.202100467.
  BibTeX
  @article{https://doi.org/10.1002/ejic.202100467, abstract = {Abstract We are reporting the synthesis and structural characterization of a new family of butterfly complexes with formula [Co2IIILn2III−(μ3−(OR))2] where −OR is an alcohol-amine type ligand, in this case N-methyldiethanolamine (H2mdea) with Ln=Tb, Dy, Ho, Er and Yb. This new family adds to the previously reported one, where the alcohol-amine ligand is triethanolamine (H3tea), and allows a one-to-one comparison between them. From a combined experimental study, that included DC and AC magnetometry as well as HF-EPR measurements, and a theoretical approach based on Broken-Symmetry DFT and CASSCF-SA-SOC ab-initio computations, we discuss the single molecule magnet (SMM) performance in these complexes. We focus in a few key structural parameters that correlate with the magnetization relaxation behaviour observed along the different explored lanthanide ions.}, author = {Funes, Alejandro V. and Perfetti, Mauro and Kern, Michal and Rußegger, Nadine and Carrella, Luca and Rentschler, Eva and van Slageren, Joris and Alborés, Pablo}, doi = {https://doi.org/10.1002/ejic.202100467}, eprint = {https://onlinelibrary.wiley.com/doi/pdf/10.1002/ejic.202100467}, journal = {European Journal of Inorganic Chemistry}, number = 31, pages = {3191-3210}, title = {Single Molecule Magnet Features in the Butterfly [CoIII2LnIII2] Pivalate Family with Alcohol-Amine Ligands}, url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/ejic.202100467}, volume = 2021, year = 2021 }
  Link
  https://onlinelibrary.wiley.com/doi/abs/10.1002/ejic.202100467
  DOI
  https://doi.org/10.1002/ejic.202100467
3. M. A. Hassan, T. Elrifai, A. Sakr, M. Kern, K. Lips, and J. Anders, “A 14-channel 7 GHz VCO-based EPR-on-a-chip sensor with rapid scan capabilities,” in 2021 IEEE Sensors, Oct. 2021, pp. 1–4. doi: 10.1109/SENSORS47087.2021.9639513.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{9639513, abstract = {This paper presents a VCO-based EPR-on-a-chip (EPRoC) sensor for portable, battery-operated electron paramagnetic resonance (EPR) spectrometers. The proposed chip contains an array of 14 injection-locked VCOs as the sensing element for an improved sensitive volume and phase noise performance. By cointegrating a high-bandwidth PLL, the presented design allows for continuous-wave and rapid-scan EPR experiments with a minimum number of external components. The active loop filter introduces an assisted replica charge pump that mitigates the slewing requirements on the loop-filter amplifier. The measured spin sensitivity of 2×10<sup>9</sup> spins/$\sqrt {{\text{Hz}}} $ together with the large active volume of 210 nl lead to an 8-fold improvement in concentration sensitivity compared to the state-of-the-art in EPRoC detectors.}, author = {Hassan, Mohamed Atef and Elrifai, Tarek and Sakr, Ayman and Kern, Michal and Lips, Klaus and Anders, Jens}, booktitle = {2021 IEEE Sensors}, doi = {10.1109/SENSORS47087.2021.9639513}, issn = {2168-9229}, month = {10}, pages = {1-4}, title = {A 14-channel 7 GHz VCO-based EPR-on-a-chip sensor with rapid scan capabilities}, year = 2021 }
  DOI
  10.1109/SENSORS47087.2021.9639513
4. D. Krüger, F. Dreyer, M. Kern, and J. Anders, “An S-band EPR-on-a-chip Receiver in 0.13 μm BiCMOS,” in 2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS), IEEE, Nov. 2021, pp. 1–5. doi: 10.1109/ICECS53924.2021.9665504.
  - BibTeX
  - DOI
  BibTeX
  @inproceedings{9665504, abstract = {We present a chip-integrated receiver for electron paramagnetic resonance (EPR), designed for operation in the S-band (2-4 GHz). This EPR-on-a-chip receiver consists of a low-noise amplifier, followed by quadrature downconversion mixers and intermediate-frequency variable gain amplifiers. It also incorporates a frequency generation block. The chip is realized in a $0.13-\mu \mathrm{m}$ SiGe BiCMOS technology and occupies an area of $1100 \times 900\ \mu \mathrm{m}^{2}$. The receiver's measured input-referred voltage noise density within the band of interest is $720 \text{pV}/\sqrt{\text{Hz}}$. Proof-of-concept EPR measurements validate the proposed approach.}, author = {Krüger, Daniel and Dreyer, Frederik and Kern, Michal and Anders, Jens}, booktitle = {2021 28th IEEE International Conference on Electronics, Circuits, and Systems (ICECS)}, doi = {10.1109/ICECS53924.2021.9665504}, month = {11}, pages = {1-5}, publisher = {IEEE}, title = {An S-band EPR-on-a-chip Receiver in 0.13 μm BiCMOS}, year = 2021 }
  DOI
  10.1109/ICECS53924.2021.9665504
5. L. Tesi et al., “Plasmonic Metasurface Resonators to Enhance Terahertz Magnetic Fields for High-Frequency Electron Paramagnetic Resonance,” Small Methods, p. 2100376, Jul. 2021, doi: 10.1002/smtd.202100376.
  BibTeX
  @article{Tesi_2021, author = {Tesi, Lorenzo and Bloos, Dominik and Hrto{\v{n}}, Martin and Bene{\v{s}}, Adam and Hentschel, Mario and Kern, Michal and Leavesley, Alisa and Hillenbrand, Rainer and K{\v{r}}{\'{a}}pek, Vlastimil and {\v{S}}ikola, Tom{\'{a}}{\v{s}} and Slageren, Joris}, doi = {10.1002/smtd.202100376}, journal = {Small Methods}, month = {07}, pages = 2100376, publisher = {Wiley}, title = {Plasmonic Metasurface Resonators to Enhance Terahertz Magnetic Fields for High-Frequency Electron Paramagnetic Resonance}, url = {https://doi.org/10.1002%2Fsmtd.202100376}, year = 2021 }
  Link
  https://doi.org/10.1002%2Fsmtd.202100376
  DOI
  10.1002/smtd.202100376
6. D. Weißhaupt et al., “Weak localization and weak antilocalization in doped Ge 1- y Sn y layers with up to 8% Sn,” Journal of Physics: Condensed Matter, vol. 33, Art. no. 8, 2021, doi: 10.1088/1361-648X/abcb68.
  BibTeX
  @article{weisshaupt2021localization, abstract = {Low-temperature magnetoresistance measurements of n- and p-doped germanium–tin (Ge1-ySny) layers with Sn concentrations up to 8% show contributions arising from effects of weak localization for n-type and weak antilocalization for p-type doped samples independent of the Sn concentration. Calculations of the magnetoresistance using the Hikami–Larkin–Nagaoka model for two-dimensional transport allow us to extract the phase-coherence length for all samples as well as the spin–orbit length for the p-type doped samples. For pure Ge, we find phase-coherence lengths as long as (349.0 ± 1.4) nm and (614.0 ± 0.9) nm for n-type and p-type doped samples, respectively. The phase-coherence length decreases with increasing Sn concentration. From the spin–orbit scattering length, we determine the spin-diffusion scattering length in the range of 20–30 nm for all highly degenerate p-type doped samples irrespective of Sn concentration. These results show that Ge1-ySny is a promising material for future spintronic applications.}, author = {Weißhaupt, David and Funk, Hannes Simon and Kern, Michal and Dettling, Marco M. and Schwarz, Daniel and Oehme, Michael and Sürgers, Christoph and van Slageren, Joris and Fischer, Inga Anita and Schulze, Jörg}, doi = {10.1088/1361-648X/abcb68}, journal = {Journal of Physics: Condensed Matter}, number = 8, pages = 085703, title = {Weak localization and weak antilocalization in doped Ge 1- y Sn y layers with up to 8% Sn}, url = {https://iopscience.iop.org/article/10.1088/1361-648X/abcb68}, volume = 33, year = 2021 }
  Link
  https://iopscience.iop.org/article/10.1088/1361-648X/abcb68
  DOI
  10.1088/1361-648X/abcb68
2020
1. M. Kern et al., “Hybrid Spintronic Materials from Conducting Polymers with Molecular Quantum Bits,” Advanced Functional Materials, 2020, doi: 10.1002/adfm.202006882.
  BibTeX
  @article{noauthororeditor, abstract = {Hybrid materials consisting of organic semiconductors and molecular quantum bits promise to provide a novel platform for quantum spintronic applications. However, investigations of such materials, elucidating both the electrical and quantum dynamical properties of the same material have never been reported. Here the preparation of hybrid materials consisting of conducting polymers and molecular quantum bits is reported. Organic field-effect transistor measurements demonstrate that the favorable electrical properties are preserved in the presence of the qubits. Chemical doping introduces charge carriers into the material, and variable-temperature charge transport measurements reveal the existence of mobile charge carriers at temperatures as low as 15 K. Importantly, quantum coherence of the qubit is shown to be preserved up to temperatures of at least 30 K, that is, in the presence of mobile charge carriers. These results pave the way for employing such hybrid materials in novel molecular quantum spintronic architectures.}, author = {Kern, Michal and Tesi, Lorenzo and Neusser, David and Rußegger, Nadine and Winkler, Mario and Allgaier, Alexander and Gross, Yannic M and Bechler, Stefan and Funk, Hannes S and Chang, Li-te and Schulze, Jörg and Ludwigs, Sabine and Slageren, Joris Van}, doi = {10.1002/adfm.202006882}, journal = {Advanced Functional Materials}, title = {Hybrid Spintronic Materials from Conducting Polymers with Molecular Quantum Bits}, url = {https://onlinelibrary.wiley.com/doi/full/10.1002/adfm.202006882}, year = 2020 }
  Link
  https://onlinelibrary.wiley.com/doi/full/10.1002/adfm.202006882
  DOI
  10.1002/adfm.202006882
2. D. Neusser, C. Malacrida, M. Kern, Y. M. Gross, J. van Slageren, and S. Ludwigs, “High Conductivities of Disordered P3HT Films by an Electrochemical Doping Strategy,” Chemistry of Materials, vol. 32, Art. no. 14, Jul. 2020, doi: 10.1021/acs.chemmater.0c01293.
  BibTeX
  @article{Neusser_2020, author = {Neusser, David and Malacrida, Claudia and Kern, Michal and Gross, Yannic M. and van Slageren, Joris and Ludwigs, Sabine}, doi = {10.1021/acs.chemmater.0c01293}, journal = {Chemistry of Materials}, month = {07}, number = 14, pages = {6003--6013}, publisher = {American Chemical Society ({ACS})}, title = {High Conductivities of Disordered P3HT Films by an Electrochemical Doping Strategy}, url = {https://doi.org/10.1021%2Facs.chemmater.0c01293}, volume = 32, year = 2020 }
  Link
  https://doi.org/10.1021%2Facs.chemmater.0c01293
  DOI
  10.1021/acs.chemmater.0c01293
2019
1. J. Hrubý et al., “A graphene-based hybrid material with quantum bits prepared by the double Langmuir–Schaefer method,” RSC Adv., vol. 9, Art. no. 42, 2019, doi: 10.1039/C9RA04537F.
  BibTeX
  @article{C9RA04537F, abstract = {The scalability and stability of molecular qubits deposited on surfaces is a crucial step for incorporating them into upcoming electronic devices. Herein{,} we report on the preparation and characterisation of a molecular quantum bit{,} copper(ii)dibenzoylmethane [Cu(dbm)2]{,} deposited by a modified Langmuir–Schaefer (LS) technique onto a graphene-based substrate. A double LS deposition was used for the preparation of a few-layer-graphene (FLG) on a Si/SiO2 substrate with subsequent deposition of the molecules. Magnetic properties were probed by high-frequency electron spin resonance (HF-ESR) spectroscopy and found maintained after deposition. Additional spectroscopic and imaging techniques{,} such as Raman spectroscopy (RS){,} X-ray photoelectron spectroscopy (XPS){,} atomic force microscopy (AFM){,} and scanning electron microscopy (SEM) were performed to characterise the deposited sample. Our approach demonstrated the possibility to utilise a controlled wet-chemistry protocol to prepare an array of potential quantum bits on a disordered graphene-based substrate. The deployed spectroscopic techniques showed unambiguously the robustness of our studied system with a potential to fabricate large-scale{,} intact{,} and stable quantum bits.}, author = {Hrubý, Jakub and Santana, Vinicius T. and Kostiuk, Dmytro and Bouček, Martin and Lenz, Samuel and Kern, Michal and Šiffalovič, Peter and van Slageren, Joris and Neugebauer, Petr}, doi = {10.1039/C9RA04537F}, journal = {RSC Adv.}, number = 42, pages = {24066-24073}, publisher = {The Royal Society of Chemistry}, title = {A graphene-based hybrid material with quantum bits prepared by the double Langmuir–Schaefer method}, url = {http://dx.doi.org/10.1039/C9RA04537F}, volume = 9, year = 2019 }
  Link
  http://dx.doi.org/10.1039/C9RA04537F
  DOI
  10.1039/C9RA04537F
2. R. Magnall et al., “Photolytic and Reductive Activations of 2-Arsaethynolate in a Uranium–Triamidoamine Complex: Decarbonylative Arsenic-Group Transfer Reactions and Trapping of a Highly Bent and Reduced Form,” Chemistry - A European Journal, vol. 25, Art. no. 62, 2019, doi: 10.1002/chem.201903973.
  - BibTeX
  - DOI
  BibTeX
  @article{Magnall2019, abstract = {Little is known about the chemistry of the 2-arsaethynolate anion, but to date it has exclusively undergone fragmentation reactions when reduced. Herein, we report the synthesis of [U(TrenTIPS)(OCAs)] (2, TrenTIPS=N(CH2CH2NSiiPr3)3), which is the first isolable actinide-2-arsaethynolate linkage. UV-photolysis of 2 results in decarbonylation, but the putative [U(TrenTIPS)(As)] product was not isolated and instead only [{\{}U(TrenTIPS){\}}2($\mu$-$\eta$2:$\eta$2-As2H2)] (3) was formed. In contrast, reduction of 2 with [U(TrenTIPS)] gave the mixed-valence arsenido [{\{}U(TrenTIPS){\}}2($\mu$-As)] (4) in very low yield. Complex 4 is unstable which precluded full characterisation, but these photolytic and reductive reactions testify to the tendency of 2-arsaethynolate to fragment with CO release and As transfer. However, addition of 2 to an electride mixture of potassium-graphite and 2,2,2-cryptand gives [{\{}U(TrenTIPS){\}}2{\{}$\mu$-$\eta$2(OAs):$\eta$2(CAs)-OCAs{\}}][K(2,2,2-cryptand)] (5). The coordination mode of the trapped 2-arsaethynolate in 5 is unique, and derives from a new highly reduced and bent form of this ligand with the most acute O-C-As angle in any complex to date (O-C-As {\textless} ≈128°). The trapping rather than fragmentation of this highly reduced O-C-As unit is unprecedented, and quantum chemical calculations reveal that reduction confers donor–acceptor character to the O-C-As unit.}, author = {Magnall, Rosie and Bal{\'{a}}zs, G{\'{a}}bor and Lu, Erli and Kern, Michal and van Slageren, Joris and Tuna, Floriana and Wooles, Ashley J. and Scheer, Manfred and Liddle, Stephen T.}, doi = {10.1002/chem.201903973}, file = {:C$\backslash$:/Users/iismike/Downloads/chem.201903973.pdf:pdf}, issn = {15213765}, journal = {Chemistry - A European Journal}, number = 62, pages = {14246--14252}, pmid = {31478589}, title = {Photolytic and Reductive Activations of 2-Arsaethynolate in a Uranium–Triamidoamine Complex: Decarbonylative Arsenic-Group Transfer Reactions and Trapping of a Highly Bent and Reduced Form}, volume = 25, year = 2019 }
  DOI
  10.1002/chem.201903973
2018
1. S. Bechler et al., “Formation of Mn5Ge3 by thermal annealing of evaporated Mn on doped Ge on Si(111),” Semiconductor Science and Technology, vol. 33, Art. no. 9, 2018, doi: 10.1088/1361-6641/aad4cf.
  - BibTeX
  - DOI
  BibTeX
  @article{Bechler2018, abstract = {Mn5Ge3 can be used as a ferromagnetic contact material to fabricate spintronic devices. Here, we show that Mn5Ge3 can be fabricated with a simple germanidation process by evaporating Mn on undoped and doped Ge on Si followed by a thermal annealing step to form the ferromagnetic Mn5Ge3 phase. This solid phase preparation of Mn5Ge3 is a robust process with a minor dependence on the annealing parameters. The formation of Mn5Ge3 can be realized using undoped as well as highly doped p-Ge and n-Ge with different doping levels. The interface of Mn5Ge3 is atomically sharp which leads to very low contact resistivities < 1 × 10−7 Ωcm2.}, author = {Bechler, Stefan and Kern, Michal and Funk, Hannes Simon and Colston, Gerard and Fischer, Inga Anita and Wei{\ss}haupt, David and Myronov, Maksym and {Van Slageren}, Joris and Schulze, J{\"{o}}rg}, doi = {10.1088/1361-6641/aad4cf}, file = {:C$\backslash$:/Users/iismike/AppData/Local/Mendeley Ltd./Mendeley Desktop/Downloaded/Bechler et al. - 2018 - Formation of Mn5Ge3 by thermal annealing of evaporated Mn on doped Ge on Si(111).pdf:pdf}, issn = {13616641}, journal = {Semiconductor Science and Technology}, number = 9, pages = 95008, title = {Formation of Mn5Ge3 by thermal annealing of evaporated Mn on doped Ge on Si(111)}, volume = 33, year = 2018 }
  DOI
  10.1088/1361-6641/aad4cf
2. F. Moro et al., “Room Temperature Uniaxial Magnetic Anisotropy Induced By Fe-Islands in the InSe Semiconductor Van Der Waals Crystal,” Advanced Science, vol. 5, Art. no. 7, 2018, doi: 10.1002/advs.201800257.
  - BibTeX
  - DOI
  BibTeX
  @article{Moro2018, abstract = {The controlled manipulation of the spin and charge of electrons in a semiconductor has the potential to create new routes to digital electronics beyond Moore's law, spintronics, and quantum detection and imaging for sensing applications. These technologies require a shift from traditional semiconducting and magnetic nanostructured materials. Here, a new material system is reported, which comprises the InSe semiconductor van der Waals crystal that embeds ferromagnetic Fe-islands. In contrast to many traditional semiconductors, the electronic properties of InSe are largely preserved after the incorporation of Fe. Also, this system exhibits ferromagnetic resonances and a large uniaxial magnetic anisotropy at room temperature, offering opportunities for the development of functional devices that integrate magnetic and semiconducting properties within the same material system.}, author = {Moro, Fabrizio and Bhuiyan, Mahabub A. and Kudrynskyi, Zakhar R. and Puttock, Robert and Kazakova, Olga and Makarovsky, Oleg and Fay, Michael W. and Parmenter, Christopher and Kovalyuk, Zakhar D. and Fielding, Alistar J. and Kern, Michal and van Slageren, Joris and Patan{\`{e}}, Amalia}, doi = {10.1002/advs.201800257}, file = {:P$\backslash$:/Work-Archive/Papers/InSeFe/advs.201800257.pdf:pdf}, issn = {21983844}, journal = {Advanced Science}, number = 7, title = {Room Temperature Uniaxial Magnetic Anisotropy Induced By Fe-Islands in the InSe Semiconductor Van Der Waals Crystal}, volume = 5, year = 2018 }
  DOI
  10.1002/advs.201800257
3. P. Neugebauer et al., “Ultra-broadband EPR spectroscopy in field and frequency domains,” Phys. Chem. Chem. Phys., vol. 20, Art. no. 22, 2018, doi: 10.1039/C7CP07443C.
  BibTeX
  @article{C7CP07443C, abstract = {Electron paramagnetic resonance (EPR) is a powerful technique to investigate the electronic and magnetic properties of a wide range of materials. We present the first combined terahertz (THz) field and frequency domain electron paramagnetic resonance (HFEPR/FDMR) spectrometer designed to investigate the electronic structure and magnetic properties of molecular systems{,} thin films and solid state materials in a very broad frequency range of 85–1100 GHz. In this paper{,} we show high resolution frequency-field (Zeeman) maps (170–380 GHz by 0–15 T) recorded on two single-molecule magnets{,} [Mn2(saltmen)2(ReO4)2] and [Mn2(salpn)2(H2O)2](ClO4)2{,} which give direct access to the field-dependence of the energy level diagram. Furthermore{,} supression of standing waves in the described system and the sensitivity in field and frequency domain operations is evaluated and discussed.}, author = {Neugebauer, P. and Bloos, D. and Marx, R. and Lutz, P. and Kern, M. and Aguilà, D. and Vaverka, J. and Laguta, O. and Dietrich, C. and Clérac, R. and van Slageren, J.}, doi = {10.1039/C7CP07443C}, journal = {Phys. Chem. Chem. Phys.}, number = 22, pages = {15528-15534}, publisher = {The Royal Society of Chemistry}, title = {Ultra-broadband EPR spectroscopy in field and frequency domains}, url = {http://dx.doi.org/10.1039/C7CP07443C}, volume = 20, year = 2018 }
  Link
  http://dx.doi.org/10.1039/C7CP07443C
  DOI
  10.1039/C7CP07443C
4. P. Zhang et al., “Exchange coupling and single molecule magnetism in redox-active tetraoxolene-bridged dilanthanide complexes,” Chem. Sci., vol. 9, Art. no. 5, 2018, doi: 10.1039/C7SC04873D.
  BibTeX
  @article{C7SC04873D, abstract = {Tetraoxolene radical-bridged lanthanide SMM systems were prepared for the first time by reduction of the respective neutral compounds. Magnetic measurements reveal the profound influence of the radical center on magnetic behavior. Strong magnetic couplings are revealed in the radical species{,} which switch on SMM behavior under zero applied field for DyIII and TbIII compounds. HFEPR spectra unravel the contributions of the magnetic coupling and the magnetic anisotropy. For GdIII this results in much more accurate magnetic coupling parameters with respect to bulk magnetic measurements.}, author = {Zhang, Peng and Perfetti, Mauro and Kern, Michal and Hallmen, Philipp P. and Ungur, Liviu and Lenz, Samuel and Ringenberg, Mark R. and Frey, Wolfgang and Stoll, Hermann and Rauhut, Guntram and van Slageren, Joris}, doi = {10.1039/C7SC04873D}, journal = {Chem. Sci.}, number = 5, pages = {1221-1230}, publisher = {The Royal Society of Chemistry}, title = {Exchange coupling and single molecule magnetism in redox-active tetraoxolene-bridged dilanthanide complexes}, url = {http://dx.doi.org/10.1039/C7SC04873D}, volume = 9, year = 2018 }
  Link
  http://dx.doi.org/10.1039/C7SC04873D
  DOI
  10.1039/C7SC04873D
5. A. Øwre, M. Vinum, M. Kern, J. van Slageren, J. Bendix, and M. Perfetti, “Chiral, Heterometallic Lanthanide–Transition Metal Complexes by Design,” Inorganics, vol. 6, Art. no. 3, Jul. 2018, doi: 10.3390/inorganics6030072.
  BibTeX
  @article{_wre_2018, abstract = {Achieving control over coordination geometries in lanthanide complexes remains a challenge to the coordination chemist. This is particularly the case in the field of molecule-based magnetism, where barriers for magnetic relaxation processes as well as tunneling pathways are strongly influenced by the lanthanide coordination geometry. Addressing the challenge of design of 4f-element coordination environments, the ubiquitous Ln(hfac)3 moieties have been shown to be applicable as Lewis acids coordinating transition metal acetylacetonates facially leading to simple, chiral lanthanide–transition metal heterodinuclear complexes. The broad scope of this approach is illustrated by the synthesis of a range of such complexes LnM: LnM(hfac)3(μ2-acac-O,O,O′)3 (Ln = La, Pr, Gd; M = Cr, Fe, Ga), with approximate three-fold symmetry. The complexes have been crystallographically characterized and exhibit polymorphism for some combinations of 4f and 3d metal centers. However, an isostructural set of systems spanning several lanthanides which exhibit spontaneous resolution in the orthorhombic Sohncke space group P212121 is presented here. The electronic structure and ensuing magnetic properties have been studied by EPR spectroscopy and magnetometry. The GdFe, PrFe, and PrCr complexes exhibit ferromagnetic coupling, while GdCr exhibits antiferromagnetic coupling. GdGa exhibits slow relaxation of the magnetization in applied static fields.}, author = {{\O}wre, Anders and Vinum, Morten and Kern, Michal and van Slageren, Joris and Bendix, Jesper and Perfetti, Mauro}, doi = {10.3390/inorganics6030072}, journal = {Inorganics}, month = {07}, number = 3, pages = 72, publisher = {{MDPI} {AG}}, title = {Chiral, Heterometallic Lanthanide{\textendash}Transition Metal Complexes by Design}, url = {https://doi.org/10.3390%2Finorganics6030072}, volume = 6, year = 2018 }
  Link
  https://doi.org/10.3390%2Finorganics6030072
  DOI
  10.3390/inorganics6030072
2017
1. I. Nemec, R. Herchel, M. Kern, P. Neugebauer, J. van Slageren, and Z. Trávnícek, “Magnetic anisotropy and field-induced slow relaxation of magnetization in tetracoordinate CoII compound Co(CH_3(-im)_2Cl2,” Materials, vol. 10, Art. no. 3, 2017, doi: 10.3390/ma10030249.
  - BibTeX
  - DOI
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  @article{Nemec2017a, abstract = {Static and dynamic magnetic properties of the tetracoordinate CoII complex [Co(CH3-im)2Cl2], (1, CH3-im = N-methyl-imidazole), studied using thorough analyses of magnetometry, and High-Frequency and -Field EPR (HFEPR) measurements, are reported. The study was supported by ab initio complete active space self-consistent field (CASSCF) calculations. It has been revealed that 1 possesses a large magnetic anisotropy with a large rhombicity (magnetometry: D = -13.5 cm-1, E/D = 0.33; HFEPR: D = -14.5(1) cm-1, E/D = 0.16(1)). These experimental results agree well with the theoretical calculations (D = -11.2 cm-1, E/D = 0.18). Furthermore, it has been revealed that 1 behaves as a field-induced single-ion magnet with a relatively large spin-reversal barrier (Ueff = 33.5 K). The influence of the Cl-Co-Cl angle on magnetic anisotropy parameters was evaluated using the CASSCF calculations.}, author = {Nemec, Ivan and Herchel, Radovan and Kern, Michal and Neugebauer, Petr and van Slageren, Joris and Tr{\'{a}}vn{\'{i}}{\v{c}}ek, Zden{\v{e}}k}, doi = {10.3390/ma10030249}, file = {:P$\backslash$:/Work-Archive/Papers/DC39/materials-10-00249-v3.pdf:pdf}, issn = {19961944}, journal = {Materials}, number = 3, pages = {1--14}, title = {Magnetic anisotropy and field-induced slow relaxation of magnetization in tetracoordinate CoII compound [Co(CH_3(-im)_2Cl2]}, volume = 10, year = 2017 }
  DOI
  10.3390/ma10030249
2016
1. M. Dörfel et al., “Torque-Detected Electron Spin Resonance as a Tool to Investigate Magnetic Anisotropy in Molecular Nanomagnets,” Magnetochemistry, vol. 2, Art. no. 2, 2016, doi: 10.3390/magnetochemistry2020025.
  BibTeX
  @article{magnetochemistry2020025, abstract = {The method of choice for in-depth investigation of the magnetic anisotropy in molecular nanomagnets is high-frequency electron spin resonance (HFESR) spectroscopy. It has the benefits of high resolution and facile access to large energy splittings. However, the sensitivity is limited to about 107 spins for a reasonable data acquisition time. In contrast, methods based on the measurement of the deflection of a cantilever were shown to enable single spin magnetic resonance sensitivity. In the area of molecular nanomagnets, the technique of torque detected electron spin resonance (TDESR) has been used sporadically. Here, we explore the applicability of that technique by investigating molecular nanomagnets with different types of magnetic anisotropy. We also assess different methods for the detection of the magnetic torque. We find that all types of samples are amenable to these studies, but that sensitivities do not yet rival those of HFESR.}, author = {Dörfel, María and Kern, Michal and Bamberger, Heiko and Neugebauer, Petr and Bader, Katharina and Marx, Raphael and Cornia, Andrea and Mitra, Tamoghna and Müller, Achim and Dressel, Martin and Bogani, Lapo and van Slageren, Joris}, doi = {10.3390/magnetochemistry2020025}, issn = {2312-7481}, journal = {Magnetochemistry}, number = 2, pages = 25, title = {Torque-Detected Electron Spin Resonance as a Tool to Investigate Magnetic Anisotropy in Molecular Nanomagnets}, url = {http://www.mdpi.com/2312-7481/2/2/25}, volume = 2, year = 2016 }
  Link
  http://www.mdpi.com/2312-7481/2/2/25
  DOI
  10.3390/magnetochemistry2020025
2. R. Koerner et al., “The Zener-Emitter: A novel superluminescent Ge optical waveguide-amplifier with 4.7 dB gain at 92 mA based on free-carrier modulation by direct Zener tunneling monolithically integrated on Si,” in 2016 IEEE International Electron Devices Meeting (IEDM), Dec. 2016, p. 22. doi: 10.1109/IEDM.2016.7838474.
  BibTeX
  @inproceedings{7838474, abstract = {We report on the first experimental demonstration of a monolithic integrated Group-IV Ge semiconductor optical amplifier (SOA) - the Ge Zener-Emitter (ZE). The ZE is a device featuring light amplification up to 4.7 dB (92 mA) at center wavelength of 1700 nm and gain-bandwidth of 98 nm on Si (100). Our novel direct Zener band-to-band tunneling (BTBT) injection method enables low-voltage electron emission beyond the Boltzmann-limit (38 mV/dec at 1.55 K, 88 mV/dec at 300 K), achieving population-inversion at 0.45 V (41 mA). The ZE possesses a Si-Ge-Si hetero-structure with excellent CMOS integration compatibility by planar device design (550 nm) and an ultra-thin (100 nm) Ge virtual substrate (VS) on Si (100). Moreover, the ZE shows superior light emission properties with pulsed lasing at 1667 nm and superluminescent LED characteristic (150 cm-1 max. gain at 270 K, 100 cm-1 max. gain at 300 k). The developed ZE device presents a promising feature to monolithic Si-photonics filling the gap for energy-efficient light emission and amplification in a small footprint (1 mm) integrated waveguide-amplifier.}, author = {{Koerner}, R. and {Schwaiz}, D. and {Fischer}, I. A. and {Augel}, L. and {Bechler}, S. and {Haenel}, L. and {Kern}, M. and {Oehme}, M. and {Rolseth}, E. and {Schwartz}, B. and {Weisshaupt}, D. and {Zhang}, W. and {Schulze}, J.}, booktitle = {2016 IEEE International Electron Devices Meeting (IEDM)}, doi = {10.1109/IEDM.2016.7838474}, issn = {2156-017X}, month = {12}, pages = {22.5.1-22.5.4}, title = {The Zener-Emitter: A novel superluminescent Ge optical waveguide-amplifier with 4.7 dB gain at 92 mA based on free-carrier modulation by direct Zener tunneling monolithically integrated on Si}, url = {https://ieeexplore.ieee.org/document/7838474/}, year = 2016 }
  Link
  https://ieeexplore.ieee.org/document/7838474/
  DOI
  10.1109/IEDM.2016.7838474

Lebenslauf

Seit 2020
PostDoc bei Prof. Anders an der Universität Stuttgart

2015 - 2020
Promotion in Physikalische Chemie “Integration of Molecular Quantum Bits with Semiconductor Spintronics” bei Prof. van Slageren an der Universität Stuttgart

2015
Masterarbeit: Torque Detected Electron Spin Resonance an der Universität Stuttgart

2014
7 Monate ERASMUS Praktikum mit Schwerpunkt Hochfeld Elektronspinresonanz an der Universität Stuttgart

2012 - 2014
Konstrukteur bei Honeywell Turbocharger Testing Laboratory, Brno, Czech Republic

2013 - 2015
Master studium der Physikalische Ingenieurwissenschaften an Brno University of Technology, Czech Republic

2010 - 2013
Bachelor studium der Physikalische Ingenieurwissenschaften an Brno University of Technology, Czech Republic

Michal Kern

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