Your search keyword '"R. Huijink"' showing total 6 results

1. Control of speed and efficiency of ultrafast demagnetization by direct transfer of spin angular momentum

Author

PV Paresh Paluskar, J.H.H. Rietjens, Gregory Malinowski, B Bert Koopmans, Henk J. M. Swagten, F. Dalla Longa, R. Huijink, Physics of Nanostructures, and Eindhoven Hendrik Casimir institute

Subjects

Physics, Magnetization, Magnetization dynamics, Condensed Matter::Materials Science, Kerr effect, Ferromagnetism, Spintronics, Condensed matter physics, Total angular momentum quantum number, Condensed Matter::Superconductivity, Demagnetizing field, General Physics and Astronomy, Spin (physics)

Abstract

Separating two ferromagnetic layers with an appropriately chosen spacing layer enables the transfer of spin between the two, which increases the speed and degree of demagnetization induced by a laser pulse. Since the discovery in 1996 that the magnetization of a nickel thin film is reduced within a few picoseconds after femtosecond-laser excitation1, ultrafast demagnetization has attracted a thriving interest. This attraction is driven by the twofold challenge of understanding magnetization dynamics in a strongly out-of-equilibrium regime and controlling the magnetic properties of materials on the subpicosecond timescale, with potential applications in spintronics. In the past decade significant progress has been made in understanding the microscopic processes that govern ultrafast demagnetization2,3,4,5,6,7. The discussion has been particularly focused on the role of angular-momentum conservation during the demagnetization process8,9,10. Here, using the time-resolved magneto-optical Kerr effect, we demonstrate that interlayer transfer of spin angular momentum in specially engineered Co/Pt multilayers speeds up the demagnetization process, bypassing the mechanism responsible for the conservation of total angular momentum taking place in a single ferromagnetic layer. This new channel for spin-angular-momentum dissipation leads to a reduction of the demagnetization time of up to 25%, accompanied by an increase of the total demagnetization by almost the same amount.

Published

2008

2. Batch fabrication of scanning microscopy probes for thermal and magnetic imaging using standard micromachining

Author

Martin Herman Siekman, Rolf Vermeer, Edin Sarajlic, M.Y. Delalande, Leon Abelmann, Hiroyuki Fujita, and R. Huijink

Subjects

Materials science, MEMS fabrication, Nanowire, Nanotechnology, microfluidic components, RF MEMS resonators, Scanning probe microscopy, chemistry.chemical_compound, nanodevices, physical sensors, Microscopy, IR-74287, METIS-271106, TST-uSPAM: micro Scanning Probe Array Memory, Lithography, EWI-18714, nanomaterials, Energy harvesting, optical MEMS, Surface micromachining, Biosensors, Silicon nitride, chemistry, Chemical sensors, Scanning ion-conductance microscopy, electronics packaging, medical sensors, power MEMS, TST-SMI: Formerly in EWI-SMI, Actuators, Microfabrication

Abstract

We present a process for batch fabrication of a novel scanning microscopy probe for thermal and magnetic imaging using standard micromachining and conventional optical contact lithography. The probe features an AFM-type cantilever with a sharp pyramidal tip composed of four freestanding silicon nitride nanowires coated by conductive material. The nanowires form an electrical cross junction at the apex of the tip, addressable through the electrodes integrated on the cantilever. The cross junction on the tip apex can be utilized to produce heat and detect local temperature changes or to serve as a miniaturized Hall magnetometer enabling, in principle, thermal and magnetic imaging by scanning the probe tip over a surface. We have successfully fabricated a first probe prototype with a nanowire tip composed of 140 nm thick and 11 μ m long silicon nitride wires metallized by 6 nm titan and 30 nm gold layers. We have experimentally characterized electrical and thermal properties of the probe demonstrating its proper functioning. ©2010 IEEE.

Published

2010

3. Dynamics of dust structures in a dc discharge under action of axial magnetic field

Author

L. G. D'yachkov, Mikhail M. Vasiliev, Vladimir E. Fortov, S. N. Antipov, R. Huijink, and Oleg F. Petrov

Subjects

Physics, Dusty plasma, Planar, Physics::Plasma Physics, Dust particles, General Physics and Astronomy, Atomic physics, Magnetic field

Abstract

Results of experiments on the formation of dusty plasma structures in a stratified dc discharge in axial magnetic fields up to 2500 G are presented. The rotation of the rather small and planar dusty plasma structures has been observed. As the field increases, the inversion of the structure rotation occurs, and when it reaches 700 G, the displacement of dust particles from the axial region of the discharge to the periphery, along with the rotation continuation, is observed. The explanation of the features in the dynamical behavior of the dust particles in the discharge, in particular the rotation inversion, is proposed.

Published

2011

4. Sub-micrometer four-point probe transport measurements on graphene.

Author

Vonk K, Verbakel JD, Huijink R, and Zandvliet HJW

Abstract

Usually, electronic transport measurements on two-dimensional materials, such as graphene and transition metal dichalcogenides, require deposition of electrodes on top of the material, in, for instance, the form of a Hall bar device. In this work, we show that by making use of a collinear micro-four-point probe, electrical transport measurements on small flakes of graphene can be performed without having to fabricate electrodes on top of the flakes. Using probes with probe pitches down to sub-micrometer scale, we show back-gate tuned transport measurements in graphene on silicon oxide and on hexagonal boron nitride. The charge carrier mobilities and the minimum conductivity of graphene are in good agreement with conventional transport measurements. In addition, we assess the possible damage caused by landing these probes on graphene., (© 2023 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2023

5. Nanofluidic chips for cryo-EM structure determination from picoliter sample volumes.

Author

Huber ST, Sarajlic E, Huijink R, Weis F, Evers WH, and Jakobi AJ

Subjects

Cryoelectron Microscopy instrumentation, Proteasome Endopeptidase Complex, Water chemistry, Cryoelectron Microscopy methods, Microfluidics instrumentation, Microfluidics methods, Protein Array Analysis methods, Specimen Handling instrumentation, Specimen Handling methods

Abstract

Cryogenic electron microscopy has become an essential tool for structure determination of biological macromolecules. In practice, the difficulty to reliably prepare samples with uniform ice thickness still represents a barrier for routine high-resolution imaging and limits the current throughput of the technique. We show that a nanofluidic sample support with well-defined geometry can be used to prepare cryo-EM specimens with reproducible ice thickness from picoliter sample volumes. The sample solution is contained in electron-transparent nanochannels that provide uniform thickness gradients without further optimisation and eliminate the potentially destructive air-water interface. We demonstrate the possibility to perform high-resolution structure determination with three standard protein specimens. Nanofabricated sample supports bear potential to automate the cryo-EM workflow, and to explore new frontiers for cryo-EM applications such as time-resolved imaging and high-throughput screening., Competing Interests: SH, FW, WE, AJ No competing interests declared, ES, RH ES and RH are inventors on a provisional patent application by SmartTip B.V. (NL2026627) for the use of microcantilevers with nanofluidic sample cells, (© 2022, Huber et al.)

Published

2022

6. Twente Photoacoustic Mammoscope 2: system overview and three-dimensional vascular network images in healthy breasts.

Author

Schoustra SM, Piras D, Huijink R, Op 't Root TJPM, Alink L, Kobold WM, Steenbergen W, and Manohar S

Subjects

Adult, Algorithms, Equipment Design, Female, Healthy Volunteers, Humans, Image Processing, Computer-Assisted, Lasers, Normal Distribution, Ultrasonography, Breast diagnostic imaging, Breast Neoplasms diagnostic imaging, Imaging, Three-Dimensional, Mammography instrumentation, Mammography methods, Photoacoustic Techniques

Abstract

We present the Twente Photoacoustic Mammoscope 2, a photoacoustic breast imaging system employing a tomographic configuration. It images one breast pendant inside an imaging tank filled with water while a woman lies prone on a bed. A dual-head laser (755 and 1064 nm) illuminates the breast with one beam directed at the nipple and nine beams directed at the sides. Ultrasound signals are detected using 12 arc-shaped arrays, each curving along the pendant breast. Each array comprises 32 piezocomposite elements each with a center frequency of 1 MHz. The imaging tank and the ultrasound arrays rotate around the breast in steps to obtain additional multiple projections. Three-dimensional images are reconstructed using a filtered backprojection algorithm. The system is described in detail, and measurements on a test object are presented. As part of a preliminary study to assess the system's in vivo performance, the breasts of two healthy volunteers were imaged. These images show the breast contour, the nipple, and the vascular anatomy within the breast. In the nipple of one case, multiple high-intensity "hot spots" are observed, which we suspect are associated with the lactiferous ducts terminating in the nipple.

Published

2019