Your search keyword '"Pablo-Navarro J"' showing total 29 results

1. Nanowire magnetic force sensors fabricated by focused electron beam induced deposition

Author

Mattiat, H., Rossi, N., Gross, B., Pablo-Navarro, J., Magén, C., Badea, R., Berezovsky, J., De Teresa, J. M., and Poggio, M.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics

Abstract

We demonstrate the use of individual magnetic nanowires (NWs), grown by focused electron beam induced deposition (FEBID), as scanning magnetic force sensors. Measurements of their mechanical susceptibility, thermal motion, and magnetic response show that the NWs posses high-quality flexural mechanical modes and a strong remanent magnetization pointing along their long axis. Together, these properties make the NWs excellent sensors of weak magnetic field patterns, as confirmed by calibration measurements on a micron-sized current-carrying wire and magnetic scanning probe images of a permalloy disk. The flexibility of FEBID in terms of the composition, geometry, and growth location of the resulting NWs, makes it ideal for fabricating scanning probes specifically designed for imaging subtle patterns of magnetization or current density., Comment: Main text: 22 pages, 4 figures; Supplementary information: 8 pages, 6 figures

Published

2019

2. Growth of Perpendicular Magnetic Anisotropy in Gallium-substituted Yttrium Iron Garnet Thin Films

Author

(0000-0001-5528-5080) Lenz, K., Gladii, O., Pablo-Navarro, J., Oelschlägel, A., Heller, R., (0000-0002-4955-515X) Lindner, J., Surzhenko, O., Dubs, C., (0000-0001-5528-5080) Lenz, K., Gladii, O., Pablo-Navarro, J., Oelschlägel, A., Heller, R., (0000-0002-4955-515X) Lindner, J., Surzhenko, O., and Dubs, C.

Abstract

We investigate the effect of Ga substitution on the magnetic properties of nanometer-thin Ga:YIG (Y_3Fe_5-xGa_xO_12) films grown by liquid phase epitaxy (LPE) [1,2]. The Ga content was varied between 1.1–1.3 f.u. and film thicknesses were 30 to 230 nm. The substitution of Fe sites by Ga ions reduces the remanent magnetization. Together with the tensile strain it causes a stronger out-of-plane uniaxial anisotropy (PMA) making thin Ga:YIG films perpendicularly magnetized. We also demonstrate that, independent of the thickness and of the substrate orientation, i.e. GGG(111) vs. (001), the PMA gradually increases with the Ga-content, resulting in a 14 times larger perpendicular anisotropy for the highest Ga content used in this study compared to pure YIG. This allows for an easy tuning of the PMA by variation of the Ga concentration. One feature of YIG almost remains: the Gilbertdamping increases only slightly with the amount of Ga. The inhomogeneous broadening shows a stronger dependence.

Published

2024

3. Laser-Induced Positional and Chemical Lattice Reordering Generating Ferromagnetism

Author

Pflug, T., Pablo-Navarro, J., Anwar, M. S., Olbrich, M., Magén, C., Ibarra, M. R., Potzger, K., (0000-0003-3893-9630) Faßbender, J., (0000-0002-4955-515X) Lindner, J., Horn, A., Bali, R., Pflug, T., Pablo-Navarro, J., Anwar, M. S., Olbrich, M., Magén, C., Ibarra, M. R., Potzger, K., (0000-0003-3893-9630) Faßbender, J., (0000-0002-4955-515X) Lindner, J., Horn, A., and Bali, R.

Abstract

Atomic scale reordering of lattices can induce local modulations of functional material properties, such as reflectance and ferromagnetism. Pulsed femtosecond laser irradiation enables lattice reordering in the picosecond range. However, the dependence of the phase transitions on the initial lattice order as well as the temporal dynamics of these transitions remain to be understood. This study investigates the laser-induced atomic reordering and the concomitant onset of ferromagnetism in thin Fe-based alloy films with vastly differing initial atomic orders. The optical response to single fs laser pulses on selected prototype systems, one that initially possesses positional disorder, Fe60V40, and a second system initially in a chemically ordered state, Fe60Al40, has been tracked with time. Despite the vastly different initial atomic orders the structure in both systems converges to a positionally ordered but chemically disordered state, accompanied by the onset of ferromagnetism. Time-resolved measurements of the transient reflectance combined with simulations of the electron and phonon temperature reveal that the reordering processes occur via the formation of a transient molten state with an approximate lifetime of 200 ps. These findings provide insights into fundamental processes involved in laser-induced atomic reordering, paving the way for controlling material properties in the picosecond range.

Published

2024

4. Laser-magnetization of Fe60Al40 investigated by pump-probe reflectometry

Author

Pflug, T., Pablo-Navarro, J., Olbrich, M., Horn, A., Bali, R., Pflug, T., Pablo-Navarro, J., Olbrich, M., Horn, A., and Bali, R.

Abstract

Ultrashort pulsed laser irradiation enables the generation of ferromagnetism in initially non-ferromagnetic materials, such as B2-ordered Fe60Al40. The paramagnetic B2 phase, defined by atomic planes of pure Fe, separated by Al-rich planes is randomized due to irradiation leading to the formation of the disordered A2 Fe60Al40 being ferromagnetic. This phase transition has been reported to rely on melting and subsequent resolidification, estimated to occur within 5 ns. However, the physical dynamics during the B2-A2 transition have yet to be investigated. Here, we demonstrate the temporal evolution of the transient reflectance of Fe60Al40 during the B2-A2 transition measured by pump-probe reflectometry. The reflectance increases abruptly 5 ps after excitation with pulsed laser radiation (800 nm, 40 fs, 0.2 J/cm2) which can be attributed to the disordering process. Ex situ observations (Kerr microscopy, HR-TEM, electron holography) confirm that the laser-irradiated areas possess a high magnetization and the A2 structure. Furthermore, materials whose phase transition does not necessarily rely on resolidification may lead to a further reduction in the time needed for generating ferromagnetism by laser irradiation.

Published

2023

5. Local magnetic patterning of nanostructures using cobalt and dysprosium focused ion beams

Author

(0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-3195-219X) Kakay, A., (0000-0003-3968-7498) Bischoff, L., Narkovic, R., Mazarov, P., (0000-0002-5200-6928) Hübner, R., Meyer, F., Pilz, W., (0000-0002-4955-515X) Lindner, J., (0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-3195-219X) Kakay, A., (0000-0003-3968-7498) Bischoff, L., Narkovic, R., Mazarov, P., (0000-0002-5200-6928) Hübner, R., Meyer, F., Pilz, W., and (0000-0002-4955-515X) Lindner, J.

Abstract

We present results for direct maskless magnetic patterning of ferromagnetic nanostructures using a special liquid metal alloy ion source for focused ion beam (FIB) systems. We used a Co36Nd64 alloy as the FIB source [1]. A Wien mass filter allows for quick switching between the ion species in the alloy without changing the FIB source. A 5000×1000×50 nm3 permalloy strip served as the sample. Using the FIB we implanted a 300-nm-wide track with Co ions (see Fig.1). We observed the Co-induced changes by measuring the sample with microresonator ferromagnetic resonance before and after the implantation. Structures as small as 30 nm can be implanted up to a concentration of 10 % near the surface. Such lateral resolution is hard to reach for other lithographic methods. This allows for easy magnetic modification of edge-localized spin waves. In another set of samples, we implanted Dy ions to locally increase the damping in a stripe pattern of ~120-nm-wide strips with 400 nm periodicity on a total area of 1×1 mm². Thus, the Gilbert damping parameter can be easily increased by one order of magnitude with a lateral resolution of about 100 nm. In contrast to electron beam lithography in combination with broad-beam ion implantation, the maskless FIB process does not require the cumbersome and difficult removal of the ion-hardened resist if optical measurements like BLS or TR-MOKE are needed.

Published

2023

6. Tailoring crosstalk between localized 1D spin-wave nanochannels using focused ion beams

Author

(0000-0002-8553-7004) Iurchuk, V., Pablo-Navarro, J., (0000-0002-1811-8862) Hula, T., Narkovic, R., (0000-0001-7192-716X) Hlawacek, G., (0000-0001-8332-9669) Körber, L., (0000-0002-3195-219X) Kakay, A., (0000-0002-6727-5098) Schultheiß, H., (0000-0003-3893-9630) Faßbender, J., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., (0000-0002-8553-7004) Iurchuk, V., Pablo-Navarro, J., (0000-0002-1811-8862) Hula, T., Narkovic, R., (0000-0001-7192-716X) Hlawacek, G., (0000-0001-8332-9669) Körber, L., (0000-0002-3195-219X) Kakay, A., (0000-0002-6727-5098) Schultheiß, H., (0000-0003-3893-9630) Faßbender, J., (0000-0001-5528-5080) Lenz, K., and (0000-0002-4955-515X) Lindner, J.

Abstract

1D spin-wave conduits are envisioned as nanoscale components of magnonics-based logic and computing schemes for future generation electronics. A-la-carte methods of versatile control of the local magnetization dynamics in such nanochannels are highly desired for efficient steering of the spin waves in magnonic devices. Here, we present a study of localized dynamical modes in 1-$\mu$m-wide Permalloy conduits probed by microresonator ferromagnetic resonance technique. We clearly observe the lowest-energy edge mode in the microstrip after its edges were finely trimmed by means of focused Ne+ ion irradiation. Furthermore, after milling the microstrip along its long axis by focused ion beams, creating consecutively ~50 and ~100 nm gaps, additional resonances emerge and are attributed to modes localized at the inner edges of the separated strips. To visualize the mode distribution, spatially resolved Brillouin light scattering microscopy was used showing an excellent agreement with the ferromagnetic resonance data and confirming the mode localization at the outer/inner edges of the strips depending on the magnitude of the applied magnetic field. Micromagnetic simulations confirm that the lowest-energy modes are localized within $\sim$15-nm-wide regions at the edges of the strips and their frequencies can be tuned in a wide range (up to 5 GHz) by changing the magnetostatic coupling (i.e. spatial separation) between the microstrips.

Published

2023

7. Direct magnetic manipulation of a permalloy nanostructure by a focused cobalt ion beam

Author

Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-3195-219X) Kakay, A., (0000-0003-3968-7498) Bischoff, L., Narkovic, R., Mazarov, P., (0000-0002-5200-6928) Hübner, R., Meyer, F., Pilz, W., (0000-0002-4955-515X) Lindner, J., (0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-3195-219X) Kakay, A., (0000-0003-3968-7498) Bischoff, L., Narkovic, R., Mazarov, P., (0000-0002-5200-6928) Hübner, R., Meyer, F., Pilz, W., (0000-0002-4955-515X) Lindner, J., and (0000-0001-5528-5080) Lenz, K.

Abstract

We present results of direct maskless magnetic patterning of ferromagnetic nanostructures using a cobalt focused ion beam (FIB) system. The liquid metal ion source of the FIB was made of a Co36Nd64 alloy. A Wien mass filter allows for selecting the ion species. Using the FIB, we implanted narrow tracks of Co ions into a nominal 5000×1000×50 nm3 permalloy strip. We observed the Co-induced changes of the magnetic properties by measuring the sample with microresonator ferromagnetic resonance before and after the implantation. Regions as small as 50 nm can be implanted up to concentrations of at.-10 % near the surface. This allows for easy magnetic modification of edge-localized spin waves with a lateral resolution otherwise hard to reach. The direct-write maskless FIB process is quick and convenient for optical measurement techniques, as it does not involve the virtually impossible removal of ion-hardened resist masks one would face when using lithography with broad-beam ion implantation

Published

2023

8. Data publication : Tailoring crosstalk between localized 1D spin-wave nanochannels using focused ion beams

Author

(0000-0002-8553-7004) Iurchuk, V., Pablo-Navarro, J., Hula, T., Narkowicz, R., Hlawacek, G., Koerber, L., Kakay, A., Schultheiss, H., Fassbender, J., Lenz, K., Lindner, J., (0000-0002-8553-7004) Iurchuk, V., Pablo-Navarro, J., Hula, T., Narkowicz, R., Hlawacek, G., Koerber, L., Kakay, A., Schultheiss, H., Fassbender, J., Lenz, K., and Lindner, J.

Abstract

This dataset contains raw data (SEM images, AFM, FMR, BLS, TetraX) used to study the dynamical edge modes in closely spaced permalloy microstrips.

Published

2023

9. Growth of Perpendicular Magnetic Anisotropy in Gallium-substituted Yttrium Iron Garnet Thin Films

Author

(0000-0001-5528-5080) Lenz, K., Gladii, O., Pablo-Navarro, J., Oelschlägel, A., Heller, R., (0000-0002-4955-515X) Lindner, J., Surzhenko, O., Dubs, C., (0000-0001-5528-5080) Lenz, K., Gladii, O., Pablo-Navarro, J., Oelschlägel, A., Heller, R., (0000-0002-4955-515X) Lindner, J., Surzhenko, O., and Dubs, C.

Abstract

We investigate the effect of Ga substitution on the magnetic properties of nanometer-thin Ga:YIG (Y_3Fe_5-xGa_xO_12) films grown by liquid phase epitaxy (LPE) [1,2]. The Ga content was varied between 1.1–1.3 f.u. and film thicknesses were 30 to 230 nm. The substitution of Fe sites by Ga ions reduces the remanent magnetization. Together with the tensile strain it causes a stronger out-of-plane uniaxial anisotropy (PMA) making thin Ga:YIG films perpendicularly magnetized. We also demonstrate that, independent of the thickness and of the substrate orientation, i.e. GGG(111) vs. (001), the PMA gradually increases with the Ga-content, resulting in a 14 times larger perpendicular anisotropy for the highest Ga content used in this study compared to pure YIG. This allows for an easy tuning of the PMA by variation of the Ga concentration. One feature of YIG almost remains: the Gilbertdamping increases only slightly with the amount of Ga. The inhomogeneous broadening shows a stronger dependence.

Published

2023

10. Data publication : Tailoring crosstalk between localized 1D spin-wave nanochannels using focused ion beams

Author

Iurchuk, V., Pablo-Navarro, J., Hula, T., Narkowicz, R., Hlawacek, G., Koerber, L., Kakay, A., Schultheiss, H., Fassbender, J., Lenz, K., and Lindner, J.

Abstract

This dataset contains raw data (SEM images, AFM, FMR, BLS, TetraX) used to study the dynamical edge modes in closely spaced permalloy microstrips.

Published

2023

11. Tailoring crosstalk between localized 1D spin-wave nanochannels using focused ion beams

Author

(0000-0002-8553-7004) Iurchuk, V., Pablo-Navarro, J., (0000-0002-1811-8862) Hula, T., Narkovic, R., (0000-0001-7192-716X) Hlawacek, G., (0000-0001-8332-9669) Körber, L., (0000-0002-3195-219X) Kakay, A., (0000-0002-6727-5098) Schultheiß, H., (0000-0003-3893-9630) Faßbender, J., (0000-0001-5528-5080) Lenz, K., (0000-0002-4955-515X) Lindner, J., (0000-0002-8553-7004) Iurchuk, V., Pablo-Navarro, J., (0000-0002-1811-8862) Hula, T., Narkovic, R., (0000-0001-7192-716X) Hlawacek, G., (0000-0001-8332-9669) Körber, L., (0000-0002-3195-219X) Kakay, A., (0000-0002-6727-5098) Schultheiß, H., (0000-0003-3893-9630) Faßbender, J., (0000-0001-5528-5080) Lenz, K., and (0000-0002-4955-515X) Lindner, J.

Abstract

1D spin-wave conduits are envisioned as nanoscale components of magnonics-based logic and computing schemes for future generation electronics. A-la-carte methods of versatile control of the local magnetization dynamics in such nanochannels are highly desired for efficient steering of the spin waves in magnonic devices. Here, we present a study of localized dynamical modes in 1-$\mu$m-wide Permalloy conduits probed by microresonator ferromagnetic resonance technique. We clearly observe the lowest-energy edge mode in the microstrip after its edges were finely trimmed by means of focused Ne+ ion irradiation. Furthermore, after milling the microstrip along its long axis by focused ion beams, creating consecutively ~50 and ~100 nm gaps, additional resonances emerge and are attributed to modes localized at the inner edges of the separated strips. To visualize the mode distribution, spatially resolved Brillouin light scattering microscopy was used showing an excellent agreement with the ferromagnetic resonance data and confirming the mode localization at the outer/inner edges of the strips depending on the magnitude of the applied magnetic field. Micromagnetic simulations confirm that the lowest-energy modes are localized within $\sim$15-nm-wide regions at the edges of the strips and their frequencies can be tuned in a wide range (up to 5 GHz) by changing the magnetostatic coupling (i.e. spatial separation) between the microstrips.

Published

2022

12. Maskless magnetic patterning using cobalt and dysprosium focused ion beams

Author

(0000-0001-5528-5080) Lenz, K., Pablo Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-9971-0824) Samad, F., Narkovic, R., (0000-0002-5200-6928) Hübner, R., Pilz, W., Meyer, F., Mazarov, P., (0000-0003-3968-7498) Bischoff, L., Lindner, J., (0000-0001-5528-5080) Lenz, K., Pablo Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-9971-0824) Samad, F., Narkovic, R., (0000-0002-5200-6928) Hübner, R., Pilz, W., Meyer, F., Mazarov, P., (0000-0003-3968-7498) Bischoff, L., and Lindner, J.

Abstract

We present results for direct maskless magnetic patterning of ferromagnetic nanostructures using a special liquid metal alloy ion source for focused ion beam (FIB) systems. We used a Co36Nd64 alloy as the FIB source [1]. A Wien mass filter allows for quick switching between the ion species in the alloy without changing the FIB source. A 5000×1000×50 nm3 permalloy strip served as the sample. Using the FIB we implanted a 300-nm-wide track with Co ions (see Fig.1). We observed the Co-induced changes by measuring the sample with microresonator ferromagnetic resonance before and after the implantation. Structures as small as 30 nm can be implanted up to a concentration of 10 % near the surface. Such lateral resolution is hard to reach for other lithographic methods. This allows for easy magnetic modification of edge-localized spin waves. In another set of samples, we implanted Dy ions to locally increase the damping in a stripe pattern of ~120-nm-wide strips with 400 nm periodicity on a total area of 1×1 mm². Thus, the Gilbert damping parameter can be easily increased by one order of magnitude with a lateral resolution of about 100 nm. In contrast to electron beam lithography in combination with broad-beam ion implantation, the maskless FIB process does not require the cumbersome and difficult removal of the ion-hardened resist if optical measurements like BLS or TR-MOKE are needed.

Published

2022

13. Magnetic patterning using Ne, Co, and Dy FIB

Author

(0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-9971-0824) Samad, F., Narkovic, R., (0000-0002-5200-6928) Hübner, R., (0000-0002-3195-219X) Kakay, A., Canzever, H., Pilz, W., Meyer, F., Mazarov, P., (0000-0003-3968-7498) Bischoff, L., Bali, R., (0000-0002-4955-515X) Lindner, J., (0000-0001-5528-5080) Lenz, K., Pablo-Navarro, J., (0000-0001-9539-5874) Klingner, N., (0000-0001-7192-716X) Hlawacek, G., (0000-0002-9971-0824) Samad, F., Narkovic, R., (0000-0002-5200-6928) Hübner, R., (0000-0002-3195-219X) Kakay, A., Canzever, H., Pilz, W., Meyer, F., Mazarov, P., (0000-0003-3968-7498) Bischoff, L., Bali, R., and (0000-0002-4955-515X) Lindner, J.

Abstract

Magnetic nanostructures needed for magnonics and spintronics are usually processed by conventional lithography techniques in combination with lift-off or broad-beam ion etching. However, it has been shown [1] that the quality and shape of the structures’ edges play an important role for the magnetization dynamics as structures become smaller and smaller. Furthermore, regarding optical measurement techniques, hard-to-remove resist masks that become hardened by ion etching are problematic. Direct-writing focused ion beams (FIB) do not have these issues. In addition, using non-standard ion species opens various paths for local magnetic patterning, i.e., influencing the magnetic properties locally. I will present results for maskless magnetic patterning of ferromagnetic nanostructures using He and Ne ions as well as a few liquid metal alloy ion sources (LMAIS) for FIB systems. He/Ne FIBs are well established and commercially available. Irradiation of (paramagnetic) FeAl films by Ne ions creates local ferromagnetic nanostructures caused by disorder that are embedded in a paramagnetic matrix [2]. The precise Ne FIB also enables us to trim the edges of magnetic nanostructures enhancing their magnetic fidelity and creating certain localized magnon states at the edges of the samples. Using specifically developed LMAIS, like e.g., Co36Nd64, CoDy, or CuDy [3,4] in combination with a Wien mass filter offers further new paths for magnetic patterning. I will present results on the modification of Ni80Fe20 (permalloy) strip samples. Using the CoNd LMAIS a narrow track of Co ions was implanted. The induced magnetic changes were measured with microresonator ferromagnetic resonance (FMR) before and after the implantation. Structures as small as 30 nm can be implanted up to a concentration of 10 % near the surface. Such lateral resolution is hard to reach for other lithographic methods. Using Dy ions one can locally increase the Gilbert damping parameter of the magnetization dynamics

Published

2022

14. Maskless magnetic patterning using cobalt and dysprosium focused ion beams

Author

Lenz, K., Pablo Navarro, J., Klingner, N., Hlawacek, G., Samad, F., Narkovic, R., Hübner, R., Pilz, W., Meyer, F., Mazarov, P., Bischoff, L., and Lindner, J.

Subjects

focused ion beams, ferromagnetic resonance, nanostructures, implantation

Abstract

We present results for direct maskless magnetic patterning of ferromagnetic nanostructures using a special liquid metal alloy ion source for focused ion beam (FIB) systems. We used a Co36Nd64 alloy as the FIB source [1]. A Wien mass filter allows for quick switching between the ion species in the alloy without changing the FIB source. A 5000×1000×50 nm3 permalloy strip served as the sample. Using the FIB we implanted a 300-nm-wide track with Co ions (see Fig.1). We observed the Co-induced changes by measuring the sample with microresonator ferromagnetic resonance before and after the implantation. Structures as small as 30 nm can be implanted up to a concentration of 10 % near the surface. Such lateral resolution is hard to reach for other lithographic methods. This allows for easy magnetic modification of edge-localized spin waves. In another set of samples, we implanted Dy ions to locally increase the damping in a stripe pattern of ~120-nm-wide strips with 400 nm periodicity on a total area of 1×1 mm². Thus, the Gilbert damping parameter can be easily increased by one order of magnitude with a lateral resolution of about 100 nm. In contrast to electron beam lithography in combination with broad-beam ion implantation, the maskless FIB process does not require the cumbersome and difficult removal of the ion-hardened resist if optical measurements like BLS or TR-MOKE are needed.

Published

2022

15. Focused-electron-beam engineering of 3d magnetic nanowires

Author

Magén, C., Pablo-Navarro, J., and De Teresa, J.M.

Abstract

Focused-electron-beam-induced deposition (FEBID) is the ultimate additive nanofabrica-tion technique for the growth of 3D nanostructures. In the field of nanomagnetism and its techno-logical applications, FEBID could be a viable solution to produce future high-density, low-power, fast nanoelectronic devices based on the domain wall conduit in 3D nanomagnets. While FEBID has demonstrated the flexibility to produce 3D nanostructures with almost any shape and geometry, the basic physical properties of these out-of-plane deposits are often seriously degraded from their bulk counterparts due to the presence of contaminants. This work reviews the experimental efforts to understand and control the physical processes involved in 3D FEBID growth of nanomagnets. Co and Fe FEBID straight vertical nanowires have been used as benchmark geometry to tailor their dimensions, microstructure, composition and magnetism by smartly tuning the growth parameters, post-growth purification treatments and heterostructuring.

Published

2021

16. Nanowire Magnetic Force Sensors Fabricated by Focused-Electron-Beam-Induced Deposition

Author

Mattiat, H., primary, Rossi, N., additional, Gross, B., additional, Pablo-Navarro, J., additional, Magén, C., additional, Badea, R., additional, Berezovsky, J., additional, De Teresa, J. M., additional, and Poggio, M., additional

Published

2020

17. NanoSQUID Magnetometry on Individual As-grown and Annealed Co Nanowires at Variable Temperature

Author

Martínez-Pérez, M. J., primary, Pablo-Navarro, J., additional, Müller, B., additional, Kleiner, R., additional, Magén, C., additional, Koelle, D., additional, de Teresa, J. M., additional, and Sesé, J., additional

Published

2018

18. Transmission XMCD-PEEM imaging of an engineered vertical FEBID cobalt nanowire with a domain wall

Author

Wartelle, A, primary, Pablo-Navarro, J, additional, Staňo, M, additional, Bochmann, S, additional, Pairis, S, additional, Rioult, M, additional, Thirion, C, additional, Belkhou, R, additional, Teresa, J M de, additional, Magén, C, additional, and Fruchart, O, additional

Published

2017

19. Spin-to-Charge Conversion in All-Oxide La 2/3 Sr 1/3 MnO 3 /SrIrO 3 Heterostructures.

Author

Martin-Rio S, Konstantinovic Z, Pomar A, Balcells L, Pablo-Navarro J, Ibarra MR, Magén C, Mestres N, Frontera C, and Martínez B

Abstract

Spin injection and spin-charge conversion processes in all-oxide La 2/3 Sr 1/3 MnO 3 /SrIrO 3 (LSMO/SIO) heterostructures with different SIO layer thickness and interfacial features have been studied. Ferromagnetic resonance (FMR) technique has been used to generate pure spin currents by spin pumping (SP) in ferromagnetic (FM) half-metallic LSMO. The change of the resonance linewidth in bare LSMO layers and LSMO/SIO heterostructures suggests a successful spin injection into the SIO layers. However, low values of the spin mixing conductance, compared to more traditional permalloy (Py)/Pt or yttrium iron garnet (YIG)/Pt systems, are found. A thorough analysis of the interfaces by high-resolution scanning transmission electron microscopy (HR-STEM) imaging suggests that they are structurally clean and atomic sharp, but a compositional analysis by energy-dispersive X-ray spectroscopy (EDS) reveals the interdiffusion of La, Ir, and Mn atomic species in the first atomic layers close to the interface. Inverse spin Hall effect (ISHE) measurements evidence that interfacial features play a very relevant role in controlling the effectiveness of the spin injection process and low transversal ISHE voltage signals are detected. In addition, it is found that larger voltage signals are detected for the lowest SIO layer thickness highlighting the role of the spin diffusion length (λ sd )/SIO layer thickness ratio. The values of ISHE voltage are rather low but allow us to determine the spin Hall angle of SIO (θ SH ≈ 1.12% at T = 250 K), which is remarkably similar to that obtained for the well-known Py/Pt system, therefore suggesting that SIO could be a promising spin-Hall material.

Published

2023

20. Tailoring crosstalk between localized 1D spin-wave nanochannels using focused ion beams.

Author

Iurchuk V, Pablo-Navarro J, Hula T, Narkowicz R, Hlawacek G, Körber L, Kákay A, Schultheiss H, Fassbender J, Lenz K, and Lindner J

Abstract

1D spin-wave conduits are envisioned as nanoscale components of magnonics-based logic and computing schemes for future generation electronics. À-la-carte methods of versatile control of the local magnetization dynamics in such nanochannels are highly desired for efficient steering of the spin waves in magnonic devices. Here, we present a study of localized dynamical modes in 1-[Formula: see text]m-wide permalloy conduits probed by microresonator ferromagnetic resonance technique. We clearly observe the lowest-energy edge mode in the microstrip after its edges were finely trimmed by means of focused Ne[Formula: see text] ion irradiation. Furthermore, after milling the microstrip along its long axis by focused ion beams, creating consecutively [Formula: see text]50 and [Formula: see text]100 nm gaps, additional resonances emerge and are attributed to modes localized at the inner edges of the separated strips. To visualize the mode distribution, spatially resolved Brillouin light scattering microscopy was used showing an excellent agreement with the ferromagnetic resonance data and confirming the mode localization at the outer/inner edges of the strips depending on the magnitude of the applied magnetic field. Micromagnetic simulations confirm that the lowest-energy modes are localized within [Formula: see text]15-nm-wide regions at the edges of the strips and their frequencies can be tuned in a wide range (up to 5 GHz) by changing the magnetostatic coupling (i.e., spatial separation) between the microstrips., (© 2023. The Author(s).)

Published

2023

21. Focused-Electron-Beam Engineering of 3D Magnetic Nanowires.

Author

Magén C, Pablo-Navarro J, and De Teresa JM

Abstract

Focused-electron-beam-induced deposition (FEBID) is the ultimate additive nanofabrication technique for the growth of 3D nanostructures. In the field of nanomagnetism and its technological applications, FEBID could be a viable solution to produce future high-density, low-power, fast nanoelectronic devices based on the domain wall conduit in 3D nanomagnets. While FEBID has demonstrated the flexibility to produce 3D nanostructures with almost any shape and geometry, the basic physical properties of these out-of-plane deposits are often seriously degraded from their bulk counterparts due to the presence of contaminants. This work reviews the experimental efforts to understand and control the physical processes involved in 3D FEBID growth of nanomagnets. Co and Fe FEBID straight vertical nanowires have been used as benchmark geometry to tailor their dimensions, microstructure, composition and magnetism by smartly tuning the growth parameters, post-growth purification treatments and heterostructuring.

Published

2021

22. Half-hedgehog spin textures in sub-100 nm soft magnetic nanodots.

Author

Berganza E, Jaafar M, Fernandez-Roldan JA, Goiriena-Goikoetxea M, Pablo-Navarro J, García-Arribas A, Guslienko K, Magén C, De Teresa JM, Chubykalo-Fesenko O, and Asenjo A

Abstract

Topologically non-trivial structures such as magnetic skyrmions are nanometric spin textures of outstanding potential for spintronic applications due to their unique features. It is well known that Néel skyrmions of definite chirality are stabilized by the Dzyaloshinskii-Moriya exchange interaction (DMI) in bulk non-centrosymmetric materials or ultrathin films with strong spin-orbit coupling at the interface. In this work, we show that soft magnetic (permalloy) hemispherical nanodots are able to host three-dimensional chiral structures (half-hedgehog spin textures) with non-zero tropological charge. They are observed at room temperature, in absence of DMI interaction and they can be further stabilized by the magnetic field arising from the Magnetic Force Microscopy probe. Micromagnetic simulations corroborate the experimental data. Our work implies the existence of a new degree of freedom to create and manipulate complex 3D spin-textures in soft magnetic nanodots and opens up future possibilities to explore their magnetization dynamics.

Published

2020

23. Writing 3D Nanomagnets Using Focused Electron Beams.

Author

Fernández-Pacheco A, Skoric L, De Teresa JM, Pablo-Navarro J, Huth M, and Dobrovolskiy OV

Abstract

Focused electron beam induced deposition (FEBID) is a direct-write nanofabrication technique able to pattern three-dimensional magnetic nanostructures at resolutions comparable to the characteristic magnetic length scales. FEBID is thus a powerful tool for 3D nanomagnetism which enables unique fundamental studies involving complex 3D geometries, as well as nano-prototyping and specialized applications compatible with low throughputs. In this focused review, we discuss recent developments of this technique for applications in 3D nanomagnetism, namely the substantial progress on FEBID computational methods, and new routes followed to tune the magnetic properties of ferromagnetic FEBID materials. We also review a selection of recent works involving FEBID 3D nanostructures in areas such as scanning probe microscopy sensing, magnetic frustration phenomena, curvilinear magnetism, magnonics and fluxonics, offering a wide perspective of the important role FEBID is likely to have in the coming years in the study of new phenomena involving 3D magnetic nanostructures.

Published

2020

24. Artificial Double-Helix for Geometrical Control of Magnetic Chirality.

Author

Sanz-Hernández D, Hierro-Rodriguez A, Donnelly C, Pablo-Navarro J, Sorrentino A, Pereiro E, Magén C, McVitie S, de Teresa JM, Ferrer S, Fischer P, and Fernández-Pacheco A

Abstract

Chirality plays a major role in nature, from particle physics to DNA, and its control is much sought-after due to the scientific and technological opportunities it unlocks. For magnetic materials, chiral interactions between spins promote the formation of sophisticated swirling magnetic states such as skyrmions, with rich topological properties and great potential for future technologies. Currently, chiral magnetism requires either a restricted group of natural materials or synthetic thin-film systems that exploit interfacial effects. Here, using state-of-the-art nanofabrication and magnetic X-ray microscopy, we demonstrate the imprinting of complex chiral spin states via three-dimensional geometric effects at the nanoscale. By balancing dipolar and exchange interactions in an artificial ferromagnetic double-helix nanostructure, we create magnetic domains and domain walls with a well-defined spin chirality, determined solely by the chiral geometry. We further demonstrate the ability to create confined 3D spin textures and topological defects by locally interfacing geometries of opposite chirality. The ability to create chiral spin textures via 3D nanopatterning alone enables exquisite control over the properties and location of complex topological magnetic states, of great importance for the development of future metamaterials and devices in which chirality provides enhanced functionality.

Published

2020

25. Customized MFM probes based on magnetic nanorods.

Author

Jaafar M, Pablo-Navarro J, Berganza E, Ares P, Magén C, Masseboeuf A, Gatel C, Snoeck E, Gómez-Herrero J, de Teresa JM, and Asenjo A

Abstract

Focused Electron Beam Induced Deposition (FEBID) for magnetic tip fabrication is presented in this work as an alternative to conventional sputtering-based Magnetic Force Microscopy (MFM) tips. FEBID enables the growth of a high-aspect-ratio magnetic nanorod with customized geometry and composition to overcome the key technical limitations of MFM probes currently on the market. The biggest advantage of these tips, in comparison with CoCr coated pyramidal probes, lies in the capability of creating sharp ends, nearly 10 nm in diameter, which provides remarkable (topographic and magnetic) lateral resolution in samples with magnetic features close to the resolution limits of the MFM technique itself. The shape of the nanorods produces a very confined magnetic stray field, whose interaction with the sample is extremely localized and perpendicular to the surface, with negligible in-plane components. This effect can lead to a better analytical and numerical modelling of the MFM probes and to an increase in the sensitivity without perturbing the magnetic configuration of soft samples. Besides, the high-aspect ratio achievable in FEBID nanorod tips makes them magnetically harder than the commercial ones, reaching coercive fields higher than 900 Oe. According to the results shown, tips based on magnetic nanorods grown by FEBID can be eventually used for quantitative analysis in MFM measurements. Moreover, the customized growth of Co- or Fe-based tips onto levers with different mechanical properties allows MFM studies that demand different measuring conditions. To showcase the versatility of this type of probe, as a last step, MFM is performed in a liquid environment, which still remains a challenge for the MFM community largely due to the lack of appropriate probes on the market. This opens up new possibilities in the investigation of magnetic biological samples.

Published

2020

26. Diameter modulation of 3D nanostructures in focused electron beam induced deposition using local electric fields and beam defocus.

Author

Pablo-Navarro J, Sangiao S, Magén C, and de Teresa JM

Abstract

Focused electron beam induced deposition (FEBID) is a leading nanolithography technique in terms of resolution and the capability for three-dimensional (3D) growth of functional nanostructures. However, FEBID still presents some limitations with respect to the precise control of the dimensions of the grown nano-objects as well as its use on insulating substrates. In the present work, we overcome both limitations by employing electrically-biased metal structures patterned on the surface of insulating substrates. Such patterned metal structures serve for charge dissipation and also allow the application of spatially-dependent electric fields. We demonstrate that such electric fields can dramatically change the dimensions of the growing 3D nanostructures by acting on the primary electron beam and the generated secondary electrons. In the performed experiments, the diameter of Pt-C and W-C vertical nanowires grown on quartz, MgO and amorphous SiO 2 is tuned by application of moderate voltages (up to 200 V) on the patterned metal microstructures during growth, achieving diameters as small as 50 nm. We identify two competing effects arising from the generated electric fields: a slight change in the primary beam focus point and a strong action on the secondary electrons. Beam defocus is exploited to achieve the in situ modulation of the diameter of 3D FEBID structures during growth.

Published

2019

27. Transmission XMCD-PEEM imaging of an engineered vertical FEBID cobalt nanowire with a domain wall.

Author

Wartelle A, Pablo-Navarro J, Staňo M, Bochmann S, Pairis S, Rioult M, Thirion C, Belkhou R, Teresa JM, Magén C, and Fruchart O

Abstract

Using focused electron-beam-induced deposition, we fabricate a vertical, platinum-coated cobalt nanowire with a controlled three-dimensional structure. The latter is engineered to feature bends along the height: these are used as pinning sites for domain walls, which are obtained at remanence after saturation of the nanostructure in a horizontally applied magnetic field. The presence of domain walls is investigated using x-ray magnetic circular dichroism (XMCD) coupled to photoemission electron microscopy (PEEM). The vertical geometry of our sample combined with the low incidence of the x-ray beam produce an extended wire shadow which we use to recover the wire's magnetic configuration. In this transmission configuration, the whole sample volume is probed, thus circumventing the limitation of PEEM to surfaces. This article reports on the first study of magnetic nanostructures standing perpendicular to the substrate with XMCD-PEEM. The use of this technique in shadow mode enabled us to confirm the presence of a domain wall without direct imaging of the nanowire.

Published

2018

28. Suspended tungsten-based nanowires with enhanced mechanical properties grown by focused ion beam induced deposition.

Author

Córdoba R, Lorenzoni M, Pablo-Navarro J, Magén C, Pérez-Murano F, and De Teresa JM

Abstract

The implementation of three-dimensional (3D) nano-objects as building blocks for the next generation of electro-mechanical, memory and sensing nano-devices is at the forefront of technology. The direct writing of functional 3D nanostructures is made feasible by using a method based on focused ion beam induced deposition (FIBID). We use this technique to grow horizontally suspended tungsten nanowires and then study their nano-mechanical properties by three-point bending method with atomic force microscopy. These measurements reveal that these nanowires exhibit a yield strength up to 12 times higher than that of the bulk tungsten, and near the theoretical value of 0.1 times the Young's modulus (E). We find a size dependence of E that is adequately described by a core-shell model, which has been confirmed by transmission electron microscopy and compositional analysis at the nanoscale. Additionally, we show that experimental resonance frequencies of suspended nanowires (in the MHz range) are in good agreement with theoretical values. These extraordinary mechanical properties are key to designing electro-mechanically robust nanodevices based on FIBID tungsten nanowires.

Published

2017

29. Three-dimensional core-shell ferromagnetic nanowires grown by focused electron beam induced deposition.

Author

Pablo-Navarro J, Magén C, and de Teresa JM

Abstract

Functional nanostructured materials often rely on the combination of more than one material to confer the desired functionality or an enhanced performance of the device. Here we report the procedure to create nanoscale heterostructured materials in the form of core-shell nanowires by focused electron beam induced deposition (FEBID) technologies. In our case, three-dimensional (3D) nanowires (<100 nm in diameter) with metallic ferromagnetic cores of Co- and Fe-FEBID have been grown and coated with a protective Pt-FEBID shell (ranging 10-20 nm in thickness) aimed to minimize the degradation of magnetic properties caused by the surface oxidation of the core to a non-ferromagnetic material. The structure, chemistry and magnetism of nanowire cores of Co and Fe have been characterized in Pt-coated and uncoated nanostructures to demonstrate that the morphology of the shell is conserved during Pt coating, the surface oxidation is suppressed or confined to the Pt layer, and the average magnetization of the core is strengthened up to 30%. The proposed approach paves the way to the fabrication of 3D FEBID nanostructures based on the smart alternate deposition of two or more materials combining different physical properties or added functionalities.

Published

2016