Reprogrammability and Scalability of Magnonic Fibonacci Quasicrystals

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Modern Magnetic Systems Article 2019

Modern Magnetic Systems

Felix Groß

Modern Magnetic Systems

Iuliia Bykova

Postdoctoral Researcher

Modern Magnetic Systems

Eberhard Goering

Research Group Leader

Modern Magnetic Systems

Gisela Schütz

Director

Modern Magnetic Systems

Joachim Gräfe

Research Group Leader

Magnonic crystals are systems that can be used to design and tune the dynamic properties of magnetization. Here, we focus on one-dimensional Fibonacci magnonic quasicrystals. We confirm the existence of collective spin waves propagating through the structure as well as dispersionless modes; the reprogammability of the resonance frequencies, dependent on the magnetization order; and dynamic spin-wave interactions. With the fundamental understanding of these properties, we lay a foundation for the scalable and advanced design of spin-wave band structures for spintronic, microwave, and magnonic applications.

Author(s):	Filip Lisiecki and Justyna Rychły and Piotr Kuświk and Hubert Głowiński and Jarosław W. Kłos and Felix Groß and Iuliia Bykova and Markus Weigand and Mateusz Zelent and Eberhard J. Goering and Gisela Schütz and Gianluca Gubbiotti and Maciej Krawczyk and Feliks Stobiecki and Janusz Dubowik and Joachim Gräfe
Journal:	Physical Review Applied
Volume:	11
Number (issue):	5
Pages:	054003
Year:	2019
Publisher:	American Physical Society

Bibtex Type:	Article (article)

DOI:	https://doi.org/10.1103/PhysRevApplied.11.054003
URL:	https://doi.org/10.1103/PhysRevApplied.11.054003

Address:	College Park, Md. [u.a.]
Electronic Archiving:	grant_archive
Language:	eng

BibTex

@article{lisiecki2019r,
  title = {Reprogrammability and Scalability of Magnonic Fibonacci Quasicrystals},
  journal = {Physical Review Applied},
  abstract = {Magnonic crystals are systems that can be used to design and tune the dynamic properties of magnetization. Here, we focus on one-dimensional Fibonacci magnonic quasicrystals. We confirm the existence of collective spin waves propagating through the structure as well as dispersionless modes; the reprogammability of the resonance frequencies, dependent on the magnetization order; and dynamic spin-wave interactions. With the fundamental understanding of these properties, we lay a foundation for the scalable and advanced design of spin-wave band structures for spintronic, microwave, and magnonic applications.},
  volume = {11},
  number = {5},
  pages = {054003},
  publisher = {American Physical Society},
  address = {College Park, Md. [u.a.]},
  year = {2019},
  slug = {lisiecki2019r},
  author = {Lisiecki, Filip and Rychły, Justyna and Kuświk, Piotr and Głowiński, Hubert and Kłos, Jarosław W. and Groß, Felix and Bykova, Iuliia and Weigand, Markus and Zelent, Mateusz and Goering, Eberhard J. and Sch{\"u}tz, Gisela and Gubbiotti, Gianluca and Krawczyk, Maciej and Stobiecki, Feliks and Dubowik, Janusz and Gr{\"a}fe, Joachim},
  url = {https://doi.org/10.1103/PhysRevApplied.11.054003}
}