Spin Wave Confinement: Propagating Waves, Second Edition
by Sergej O. Demokritov /
2017 / English / PDF
15.6 MB Download
Since the publication of the first edition of
Since the publication of the first edition ofSpin-Wave
Confinement
Spin-Wave
Confinement, the magnetic community’s interest in
dynamic excitations in magnetic systems of reduced dimensions has
been increasing. Although the concept of spin waves and their
quanta (magnons) as propagating excitation of magnetic media was
introduced more than 80 years ago, this field has been repeatedly
bringing us fascinating new physical phenomena. The successful
development of magnonics as an emerging subfield of spintronics,
which considers confined spin waves as a basis for smaller,
faster, more robust, and more power-efficient electronic devices,
inevitably demands reduction in the sizes and dimensions of the
magnetic systems being studied.
, the magnetic community’s interest in
dynamic excitations in magnetic systems of reduced dimensions has
been increasing. Although the concept of spin waves and their
quanta (magnons) as propagating excitation of magnetic media was
introduced more than 80 years ago, this field has been repeatedly
bringing us fascinating new physical phenomena. The successful
development of magnonics as an emerging subfield of spintronics,
which considers confined spin waves as a basis for smaller,
faster, more robust, and more power-efficient electronic devices,
inevitably demands reduction in the sizes and dimensions of the
magnetic systems being studied.
The unique features of magnons, including the possibility of
carrying spin information over relatively long distances, the
possibility of achieving submicrometer wavelength at microwave
frequencies, and controllability by electronic signal via
magnetic fields, make magnonic devices distinctively suited for
implementation of novel integrated electronic schemes
characterized by high speed, low power consumption, and extended
functionalities.
The unique features of magnons, including the possibility of
carrying spin information over relatively long distances, the
possibility of achieving submicrometer wavelength at microwave
frequencies, and controllability by electronic signal via
magnetic fields, make magnonic devices distinctively suited for
implementation of novel integrated electronic schemes
characterized by high speed, low power consumption, and extended
functionalities.
Edited by S. O. Demokritov, a prominent magnonics researcher who
has successfully collected the results of cutting-edge research
by almost all main players in the field, this book is for
everyone involved in nanotechnology, spintronics, magnonics, and
nanomagnetism.
Edited by S. O. Demokritov, a prominent magnonics researcher who
has successfully collected the results of cutting-edge research
by almost all main players in the field, this book is for
everyone involved in nanotechnology, spintronics, magnonics, and
nanomagnetism.