Your search keyword '"Bykova, Iuliia"' showing total 6 results

1. High-resolution ptychographic imaging at a seeded free-electron laser source using OAM beams

Author

Pancaldi, Matteo, Guzzi, Francesco, Bevis, Charles S., Manfredda, Michele, Barolak, Jonathan, Bonetti, Stefano, Bykova, Iuliia, De Angelis, Dario, De Ninno, Giovanni, Fanciulli, Mauro, Novinec, Luka, Pedersoli, Emanuele, Ravindran, Arun, Rösner, Benedikt, David, Christian, Ruchon, Thierry, Simoncig, Alberto, Zangrando, Marco, Adams, Daniel E., Vavassori, Paolo, Sacchi, Maurizio, Kourousias, George, Mancini, Giulia F., Capotondi, Flavio, Pancaldi, Matteo, Guzzi, Francesco, Bevis, Charles S., Manfredda, Michele, Barolak, Jonathan, Bonetti, Stefano, Bykova, Iuliia, De Angelis, Dario, De Ninno, Giovanni, Fanciulli, Mauro, Novinec, Luka, Pedersoli, Emanuele, Ravindran, Arun, Rösner, Benedikt, David, Christian, Ruchon, Thierry, Simoncig, Alberto, Zangrando, Marco, Adams, Daniel E., Vavassori, Paolo, Sacchi, Maurizio, Kourousias, George, Mancini, Giulia F., and Capotondi, Flavio

Abstract

Electromagnetic waves possessing orbital angular momentum (OAM) are powerful tools for applications in optical communications, quantum technologies, and optical tweezers. Recently, they have attracted growing interest since they can be harnessed to detect peculiar helical dichroic effects in chiral molecular media and in magnetic nanostructures. In this work, we perform single-shot per position ptychography on a nanostructured object at a seeded free-electron laser, using extreme ultraviolet OAM beams of different topological charge orders ℓ generated with spiral zone plates. By controlling ℓ, we demonstrate how the structural features of OAM beam profiles determine an improvement of about 30% in image resolution with respect to conventional Gaussian beam illumination. This result extends the capabilities of coherent diffraction imaging techniques, and paves the way for achieving time-resolved high-resolution (below 100 nm) microscopy on large area samples.

Published

2024

2. Freezing and thawing magnetic droplet solitons

Author

Ahlberg, Martina, Chung, Sunjae, Jiang, Sheng, Frisk, Andreas, Khademi, Maha, Khymyn, Roman, Awad, Ahmad A., Le, Quang Tuan, Mazraati, Hamid, Mohseni, Majid, Weigand, Markus, Bykova, Iuliia, Gross, Felix, Goering, Eberhard, Schutz, Gisela, Grafe, Joachim, Åkerman, Johan, Ahlberg, Martina, Chung, Sunjae, Jiang, Sheng, Frisk, Andreas, Khademi, Maha, Khymyn, Roman, Awad, Ahmad A., Le, Quang Tuan, Mazraati, Hamid, Mohseni, Majid, Weigand, Markus, Bykova, Iuliia, Gross, Felix, Goering, Eberhard, Schutz, Gisela, Grafe, Joachim, and Åkerman, Johan

Abstract

Magnetic droplets are a type of non-topological magnetic soliton, which are stabilised and sustained by spin-transfer torques for instance. Without this, they would collapse. Here Ahlberg et al show that by decreasing the applied magnetic field, droplets can be frozen, forming a static nanobubble Magnetic droplets are non-topological magnetodynamical solitons displaying a wide range of complex dynamic phenomena with potential for microwave signal generation. Bubbles, on the other hand, are internally static cylindrical magnetic domains, stabilized by external fields and magnetostatic interactions. In its original theory, the droplet was described as an imminently collapsing bubble stabilized by spin transfer torque and, in its zero-frequency limit, as equivalent to a bubble. Without nanoscale lateral confinement, pinning, or an external applied field, such a nanobubble is unstable, and should collapse. Here, we show that we can freeze dynamic droplets into static nanobubbles by decreasing the magnetic field. While the bubble has virtually the same resistance as the droplet, all signs of low-frequency microwave noise disappear. The transition is fully reversible and the bubble can be thawed back into a droplet if the magnetic field is increased under current. Whereas the droplet collapses without a sustaining current, the bubble is highly stable and remains intact for days without external drive. Electrical measurements are complemented by direct observation using scanning transmission x-ray microscopy, which corroborates the analysis and confirms that the bubble is stabilized by pinning., QC 20220524

Published

2022

3. The Journal of Physical Chemistry C / X‑ray Microspectroscopy and Ptychography on Nanoscale Structures in Rock Varnish

Author

Förster, Jan-David, Förster, Jan-David, Bykova, Iuliia, Macholdt, Dorothea S., Jochum, Klaus Peter, Kappl, Michael, Kilcoyne, A. L. David, Müller, Maren, Sorowka, Antje, Weber, Bettina, Weigand, Markus, Schütz, Gisela, Andreae, Meinrat O., Pöhlker, Christopher, Förster, Jan-David, Förster, Jan-David, Bykova, Iuliia, Macholdt, Dorothea S., Jochum, Klaus Peter, Kappl, Michael, Kilcoyne, A. L. David, Müller, Maren, Sorowka, Antje, Weber, Bettina, Weigand, Markus, Schütz, Gisela, Andreae, Meinrat O., and Pöhlker, Christopher

Abstract

X-ray microspectroscopy is a powerful analytical method in geoscientific and environmental research as it provides a unique combination of nanoscale imaging with high spectroscopic sensitivity at relatively low beam-related sample damage. In this study, “classical” scanning transmission soft X-ray microscopy (STXM) with X-ray absorption spectroscopy and the recently established soft X-ray ptychography are applied to the analysis of selected rock varnish samples from urban and arid desert environments. X-ray ptychography enhances the spatial resolution relative to STXM by up to 1 order of magnitude. With its high chemical sensitivity, it can resolve nanoscale differences in valence states of the key varnish elements manganese (Mn) and iron. Our results emphasize the complex nanoarchitecture of rock varnish as well as the diverse mineralogy of the Mn oxy–hydroxide matrix and its embedded dust grains. In contrast to the fast-growing urban varnish, the slow-growing arid desert varnish revealed a remarkable nanoscale stratification of alternating Mn valence states, providing hints on the layer-wise and still enigmatic growth process., Version of record

Published

2021

4. The Journal of Physical Chemistry C / X‑ray Microspectroscopy and Ptychography on Nanoscale Structures in Rock Varnish

Author

Förster, Jan-David, Förster, Jan-David, Bykova, Iuliia, Macholdt, Dorothea S., Jochum, Klaus Peter, Kappl, Michael, Kilcoyne, A. L. David, Müller, Maren, Sorowka, Antje, Weber, Bettina, Weigand, Markus, Schütz, Gisela, Andreae, Meinrat O., Pöhlker, Christopher, Förster, Jan-David, Förster, Jan-David, Bykova, Iuliia, Macholdt, Dorothea S., Jochum, Klaus Peter, Kappl, Michael, Kilcoyne, A. L. David, Müller, Maren, Sorowka, Antje, Weber, Bettina, Weigand, Markus, Schütz, Gisela, Andreae, Meinrat O., and Pöhlker, Christopher

Abstract

X-ray microspectroscopy is a powerful analytical method in geoscientific and environmental research as it provides a unique combination of nanoscale imaging with high spectroscopic sensitivity at relatively low beam-related sample damage. In this study, “classical” scanning transmission soft X-ray microscopy (STXM) with X-ray absorption spectroscopy and the recently established soft X-ray ptychography are applied to the analysis of selected rock varnish samples from urban and arid desert environments. X-ray ptychography enhances the spatial resolution relative to STXM by up to 1 order of magnitude. With its high chemical sensitivity, it can resolve nanoscale differences in valence states of the key varnish elements manganese (Mn) and iron. Our results emphasize the complex nanoarchitecture of rock varnish as well as the diverse mineralogy of the Mn oxy–hydroxide matrix and its embedded dust grains. In contrast to the fast-growing urban varnish, the slow-growing arid desert varnish revealed a remarkable nanoscale stratification of alternating Mn valence states, providing hints on the layer-wise and still enigmatic growth process., Version of record

Published

2021

5. Direct Observation of Zhang-Li Torque Expansion of Magnetic Droplet Solitons

Author

Chung, Sunjae, Le, Q. Tuan, Ahlberg, Martina, Awad, Ahmad A., Weigand, Markus, Bykova, Iuliia, Khymyn, Roman, Dvornik, Mykola, Mazraati, Hamid, Houshang, Afshin, Jiang, Sheng, Anh Nguyen, T. N., Goering, Eberhard, Schuetz, Gisela, Gräfe, Joachim, Åkerman, Johan, Chung, Sunjae, Le, Q. Tuan, Ahlberg, Martina, Awad, Ahmad A., Weigand, Markus, Bykova, Iuliia, Khymyn, Roman, Dvornik, Mykola, Mazraati, Hamid, Houshang, Afshin, Jiang, Sheng, Anh Nguyen, T. N., Goering, Eberhard, Schuetz, Gisela, Gräfe, Joachim, and Åkerman, Johan

Abstract

Magnetic droplets are nontopological dynamical soli tons that can be nucleated in nanocontact based spin torque nano-oscillators (STNOs) with perpendicular magnetic anisotropy free layers. While theory predicts that the droplet should be of the same size as the nanocontact, its inherent drift instability has thwarted attempts at observing it directly using microscopy techniques. Here, we demonstrate highly stable magnetic droplets in all-perpendicular STNOs and present the first detailed droplet images using scanning transmission X-ray microscopy. In contrast to theoretical predictions, we find that the droplet diameter is about twice as large as the nanocontact. By extending the original droplet theory to properly account for the lateral current spread underneath the nanocontact, we show that the large discrepancy primarily arises from current-in-plane Zhang-Li torque adding an outward pressure on the droplet perimeter. Electrical measurements on droplets nucleated using a reversed current in the antiparallel state corroborate this picture.

Published

2018

6. Direct Observation of Zhang-Li Torque Expansion of Magnetic Droplet Solitons

Author

Chung, Sunjae, Le, Q. Tuan, Ahlberg, Martina, Awad, Ahmad A., Weigand, Markus, Bykova, Iuliia, Khymyn, Roman, Dvornik, Mykola, Mazraati, Hamid, Houshang, Afshin, Jiang, Sheng, Anh Nguyen, T. N., Goering, Eberhard, Schuetz, Gisela, Graefe, Joachim, Åkerman, Johan, Chung, Sunjae, Le, Q. Tuan, Ahlberg, Martina, Awad, Ahmad A., Weigand, Markus, Bykova, Iuliia, Khymyn, Roman, Dvornik, Mykola, Mazraati, Hamid, Houshang, Afshin, Jiang, Sheng, Anh Nguyen, T. N., Goering, Eberhard, Schuetz, Gisela, Graefe, Joachim, and Åkerman, Johan

Abstract

Magnetic droplets are nontopological dynamical soli tons that can be nucleated in nanocontact based spin torque nano-oscillators (STNOs) with perpendicular magnetic anisotropy free layers. While theory predicts that the droplet should be of the same size as the nanocontact, its inherent drift instability has thwarted attempts at observing it directly using microscopy techniques. Here, we demonstrate highly stable magnetic droplets in all-perpendicular STNOs and present the first detailed droplet images using scanning transmission X-ray microscopy. In contrast to theoretical predictions, we find that the droplet diameter is about twice as large as the nanocontact. By extending the original droplet theory to properly account for the lateral current spread underneath the nanocontact, we show that the large discrepancy primarily arises from current-in-plane Zhang-Li torque adding an outward pressure on the droplet perimeter. Electrical measurements on droplets nucleated using a reversed current in the antiparallel state corroborate this picture., QC 20180619

Published

2018