Relevant bibliographies by topics / Spin wave

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Spin wave'

Author: Grafiati
Published: 4 June 2021
Last updated: 27 April 2022

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Journal articles on the topic "Spin wave"

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Zheng, Lei, Lichuan Jin, Tianlong Wen, Yulong Liao, Xiaoli Tang, Huaiwu Zhang, and Zhiyong Zhong. "Spin wave propagation in uniform waveguide: effects, modulation and its application." Journal of Physics D: Applied Physics 55, no. 26 (March 1, 2022): 263002. http://dx.doi.org/10.1088/1361-6463/ac4b58.

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Abstract Magnonics, or spin waves, are one of the most promising candidate technologies for information processing beyond complementary metal oxide semiconductors. Information encoded by spin waves, which uses the frequency, amplitude and/or phase to encode information, has a great many advantages such as extremely low energy loss and wideband frequency. Moreover, the nonlinear characteristics of spin waves can enhance the extra degrees of processing freedom for information. A typical spin wave device consists of a spin wave source (transmitter), spin wave waveguide and spin wave detector. The spin wave waveguide plays an important role of propagating and modulating the spin wave to fulfill the device’s function. This review provides a tutorial overview of the various effects of coherent spin wave propagation and recent research progress on a uniform spin wave waveguide. Furthermore, we summarize the methods of modulating propagation of a spin wave in a uniform waveguide, and analyze the experimental and calculated results of the spin wave propagation profile and dispersion curve under different modulation methods. This review may promote the development of information transmission technology based on spin waves.
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Froes, D., M. Arana, L. C. Sampaio, and J. P. Sinnecker. "Acoustic wave surfing: spin waves and spin pumping driven by elastic wave." Journal of Physics D: Applied Physics 54, no. 25 (April 6, 2021): 255001. http://dx.doi.org/10.1088/1361-6463/abed71.

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Long, M. W., and W. Yeung. "Spin waves in multiple-spin-density-wave systems." Journal of Physics C: Solid State Physics 19, no. 9 (March 30, 1986): 1409–29. http://dx.doi.org/10.1088/0022-3719/19/9/012.

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Long, Yang, Jie Ren, and Hong Chen. "Intrinsic spin of elastic waves." Proceedings of the National Academy of Sciences 115, no. 40 (September 18, 2018): 9951–55. http://dx.doi.org/10.1073/pnas.1808534115.

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Unveiling spins of physical systems usually gives people a fundamental understanding of the geometrical properties of waves from classical to quantum aspects. A great variety of research has shown that transverse waves can possess nontrivial spins and spin-related properties naturally. However, until now, we still lack essential physical insights about the spin nature of longitudinal waves. Here, demonstrated by elastic waves, we uncover spins for longitudinal waves and the mixed longitudinal–transverse waves that play essential roles in spin–momentum locking. Based on this spin perspective, several abnormal phenomena beyond pure transverse waves are attributed to the hybrid spin induced by mixed longitudinal–transverse waves. The unique hybrid spin reveals the complex spin essence in elastic waves and advances our understanding about their fundamental geometrical properties. We also show that these spin-dependent phenomena can be exploited to control the wave propagation, such as nonsymmetric elastic wave excitation by spin pairs, a unidirectional Rayleigh wave, and spin-selected elastic wave routing. These findings are generally applicable for wave cases with longitudinal and transverse components.
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Bertelli, Iacopo, Joris J. Carmiggelt, Tao Yu, Brecht G. Simon, Coosje C. Pothoven, Gerrit E. W. Bauer, Yaroslav M. Blanter, Jan Aarts, and Toeno van der Sar. "Magnetic resonance imaging of spin-wave transport and interference in a magnetic insulator." Science Advances 6, no. 46 (November 2020): eabd3556. http://dx.doi.org/10.1126/sciadv.abd3556.

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Spin waves—the elementary excitations of magnetic materials—are prime candidate signal carriers for low-dissipation information processing. Being able to image coherent spin-wave transport is crucial for developing interference-based spin-wave devices. We introduce magnetic resonance imaging of the microwave magnetic stray fields that are generated by spin waves as a new approach for imaging coherent spin-wave transport. We realize this approach using a dense layer of electronic sensor spins in a diamond chip, which combines the ability to detect small magnetic fields with a sensitivity to their polarization. Focusing on a thin-film magnetic insulator, we quantify spin-wave amplitudes, visualize spin-wave dispersion and interference, and demonstrate time-domain measurements of spin-wave packets. We theoretically explain the observed anisotropic spin-wave patterns in terms of chiral spin-wave excitation and stray-field coupling to the sensor spins. Our results pave the way for probing spin waves in atomically thin magnets, even when embedded between opaque materials.
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Franjic, F., and S. Sorella. "Spin-Wave Wave Function for Quantum Spin Models." Progress of Theoretical Physics 97, no. 3 (March 1, 1997): 399–406. http://dx.doi.org/10.1143/ptp.97.399.

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Zhou, Zhen-Wei, Xi-Guang Wang, Yao-Ghuang Nie, Qing-Lin Xia, and Guang-Hua Guo. "Strong high-frequency spin waves released periodically from a confined region." European Physical Journal Applied Physics 91, no. 3 (September 2020): 30601. http://dx.doi.org/10.1051/epjap/2020200144.

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Efficient excitation of spin waves is a key issue in magnonics. Here, by using micromagnetic simulation and analytical analysis, we study the excitation of spin waves confined in a limited region by a microwave field with assistance of spin-transfer torque. The results show that the spin-transfer torque can decrease the effective damping constant and increase the spin wave relaxation time substantially. As a result, the amplitude of the excited spin waves is increased greatly. By periodically lifting and establishing the blocking areas, strong spin-wave pulses are released from the confined region. Such generated spin-wave pulses are much stronger than traditionally excited spin waves, especially for high-frequency spin waves. Our study provides a new method to generate strong high-frequency spin waves.
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Wang, Q., T. Brächer, M. Mohseni, B. Hillebrands, V. I. Vasyuchka, A. V. Chumak, and P. Pirro. "Nanoscale spin-wave wake-up receiver." Applied Physics Letters 115, no. 9 (August 26, 2019): 092401. http://dx.doi.org/10.1063/1.5109623.

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Khitun, Alexander, Dmitri E. Nikonov, and Kang L. Wang. "Magnetoelectric spin wave amplifier for spin wave logic circuits." Journal of Applied Physics 106, no. 12 (December 15, 2009): 123909. http://dx.doi.org/10.1063/1.3267152.

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Han, Jiahao, Pengxiang Zhang, Justin T. Hou, Saima A. Siddiqui, and Luqiao Liu. "Mutual control of coherent spin waves and magnetic domain walls in a magnonic device." Science 366, no. 6469 (November 28, 2019): 1121–25. http://dx.doi.org/10.1126/science.aau2610.

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The successful implementation of spin-wave devices requires efficient modulation of spin-wave propagation. Using cobalt/nickel multilayer films, we experimentally demonstrate that nanometer-wide magnetic domain walls can be applied to manipulate the phase and magnitude of coherent spin waves in a nonvolatile manner. We further show that a spin wave can, in turn, be used to change the position of magnetic domain walls by means of the spin-transfer torque effect generated from magnon spin current. This mutual interaction between spin waves and magnetic domain walls opens up the possibility of realizing all-magnon spintronic devices, in which one spin-wave signal can be used to control others by reconfiguring magnetic domain structures.
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Dissertations / Theses on the topic "Spin wave"

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Lassalle-Balier, Rémy. "Spin wave propagation and interferometry." Paris 6, 2011. http://www.theses.fr/2011PA066030.

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Ce travail a pour objectif l’observation d’interf´erence d’ondes de spin dans des structures magnétiques confinées. Le chemin jusqu’à cet objectif a mené à la conception un nouvel émetteur récepteur d’onde de spin qui permet l’observation du mode MsBVW qui est difficilement excitable. Ce transducteur a été modélisé en généralisant une théorie de transduction existante. L’utilisation d’un facteur démagnétisant constant a été identifiée comme la principale limite car cela ne permet pas de considérer proprement l’effet du confinement. Ensuite, l’émission et la réception d’onde de spin ont été caractérisées dans l’approche d’onde continue. Afin de compléter cette étude de propagation d’onde de spin dans des structures magnétiques confinées, une seconde expérience, dans l’espace temporel, a été utilisé pour observer les ondes de spin en mode pulsé. Ce ci a mené à la caractérisation de l’évolution du spectre d’onde de spin durant le régime transitoire. Enfin, deux types d’interférence ont été décrits, et deux types d’interféromtre ont été conçus. Les interférences par addition de champ ont été observées expérimentalement dans le cas des modes de surface. L’intégralité de ces travaux a été réalisée en utilisant du permalloy car il s’agit d’un alliage métallique ferromagnétique. Ce ci signifie qu’il est facilement déposable par pulvérisation cathodique ou par évaporation, qui sont deux techniques largement éprouvées dans l’industrie microélectronique. Même si ce matériaux présente un fort amortissement de la dynamique, il est un meilleur candidat pour l’intégration dans l’industrie que des matériaux à plus faible amortissement comme le YIG qui nécessite une lourde méthode
This work aims to observe spin wave interferences in confined magnetic structures. The way to this goal has led to the design of a new spin wave emitter and receiver that allows observation of MsBVW that are usually hard to excite. This transducer has been modeled by generalizing an existing spin wave transduction. The use of constant demagnetizing factor has been identified as its main limits as it does not consider properly confinement effect. Then, spin wave emission and reception has been characterized in continuous wave approach. To complete this study of propagating spin wave in confined magnetic structures, a second set-up, in time domain, has been used to observe spin wave in pulsed mode. This has led to characterization of spin wave spectrum evolution during transient. Finally, two kinds of spin wave interference have been described and two type of interferometer have been designed. Field addition interferences have been observed experimentally in the case of MsSW. All this work was done using only permalloy because it is a ferromagnetic metallic alloy. This means, it is easily deposited by sputtering or evaporation that are two methods widely used in microelectronic industry. Even if this material has a high damping, it would be more likely adopted by industry than low damping material such as YIG that requires heavy deposition technique, epitaxy
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Evers, Martin [Verfasser]. "Two antagonizing aspects of spin transport : spin-wave localization and spin superfluidity / Martin Evers." Konstanz : KOPS Universität Konstanz, 2019. http://d-nb.info/1230323309/34.

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Loutsenko, Igor. "Solitons in wave propagation and spin systems." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1999. http://www.collectionscanada.ca/obj/s4/f2/dsk1/tape9/PQDD_0013/NQ42468.pdf.

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Zheng, Liqiu. "Spin density wave phases in semiconductor superlattices." Connect to this title online, 2007. http://etd.lib.clemson.edu/documents/1202500635/.

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Li, Tian. "Spin wave propagation in ferromagnetic nano-structures." Doctoral thesis, Kyoto University, 2021. http://hdl.handle.net/2433/263500.

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Magnusson, Einar B. "High-spin impurities and surface acoustic waves in piezoelectric crystals for spin-lattice coupling." Thesis, University of Oxford, 2016. https://ora.ox.ac.uk/objects/uuid:09d23fb2-f501-4be2-a25f-b69ada0ce5b1.

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In this thesis we investigate various aspects of SAW devices and strain sensitive spin species in ZnO and LiNbO3 for coupling surface acoustic waves to spin ensembles. Firstly, we performed a series of ESR experiments exploring the potential of Fe3+ impurities in ZnO for spin-lattice coupling. This spin system has already been identified as a high potential quantum technology component due to its long coherence time. We show that the system also has good properties for spin-lattice coupling experiments, with a strain-coupling parameter G33 = 280 ± 5GHz/strain, which is about 16 times larger than the largest reported for NV centres in diamond. We found that the LEFE effect as well as the spin Hamiltonian parameter D have a linear temperature dependence. As the relative change in each coincide, this strongly supports the notion that the modification of D by an electric field is a multiplicative effect rather than an additive one, D = D0(1 + κΕ). The LEFE coefficient we measured is several times larger for Fe3+:ZnO than for Mn2+:ZnO. Secondly, we have fabricated and characterised SAW devices on bulk ZnO crystals and Fe doped lithium niobate. We found that the nominally pure ZnO was conductive at room temperature due to n-type intrinsic doping, and electrical losses inhibited any transmission through a SAW delay line above T = 200K. The one-port resonator measured down to milli-Kelvin temperatures showed excellent quality factors of up to Q ≃ 1.5 x 105 in its superconducting state. Finally, we performed a surface acoustic wave spin resonance (SAWSR) experiment using a one-port SAW resonator fabricated on Fe2+:LN. We observed a clear signal at T ≃ 25 K, at a field near the expected one for a Δms = 2 transition between the |−1⟩ and |+1⟩ states. We concluded it to be a transition induced by acoustic coupling since the signal intensity did not tend to zero when the magnetic field was parallel to the crystal anisotropy axis. Furthermore, this tells us that the coupling is due to a modulation of the E zero-field splitting parameter rather than D. We investigated the dependence on microwave power and found the saturation limit. We performed a measurement of Fe3+:LN as well to reassure ourselves that the resonance is not magnetically excited by the field around the IDT.
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Feiler, Laura [Verfasser]. "Nonlinear spin-wave excitation detected by the inverse spin-Hall effect / Laura Feiler." München : Verlag Dr. Hut, 2017. http://d-nb.info/1126296376/34.

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Mansfeld, Sebastian [Verfasser]. "Spin-Wave Optics: Refraction and Imaging / Sebastian Mansfeld." München : Verlag Dr. Hut, 2012. http://d-nb.info/1028785607/34.

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Tödt, Jan-Niklas [Verfasser]. "Control of spin-wave propagation / Jan-Niklas Tödt." München : Verlag Dr. Hut, 2017. http://d-nb.info/1126295949/34.

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Haidar, Mohammad. "Role of surfaces in magnetization dynamics and spin polarized transport : a spin wave study." Phd thesis, Université de Strasbourg, 2012. http://tel.archives-ouvertes.fr/tel-00869643.

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In this thesis, the interplay between electron transport and magnetization dynamics is explored in order to access to fundamental properties of ferromag- netic metal thin films. With the aim of extracting the influence of the electron surface scattering on the spin-dependent resistivities, thickness series of permal-loy (Ni80Fe20) films were grown and studied. In addition to standard electrical and magnetic measurements, a detailed study of the propagation of spin waves along these films was performed. Resorting to the current-induced spin-wave Doppler shift technique, the degree of spin-polarization of the electrical current was extracted. This degree of spin-polarization was found to decrease when the film thickness decreases, which suggests that the film surfaces contribute to the spin dependent resistivities and tend to depolarize the electrical current.
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Books on the topic "Spin wave"

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Lʹvov, V. S. Wave turbulence under parametric excitation: Applications to magnets. Berlin: Springer-Verlag, 1994.

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L'vov, Victor S. Wave Turbulence Under Parametric Excitation: Applications to Magnets. Berlin, Heidelberg: Springer Berlin Heidelberg, 1994.

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International Workshop on Application of Submillimeter Wave Electron Spin Resonance for Novel Magnetic Systems (2002 Tohoku University). Proceedings of the International Workshop on Application of Submillimeter Wave Electron Spin Resonance for Novel Magnetic Systems: June 13-14, 2002, IMR, Tohoku University, Sendai, Japan. Edited by Ohta Hitoshi, Nojiri Hiroyuki, Motokawa M, and Tōhoku Daigaku. Kinzoku Zairyō Kenkyūjo. Tokyo, Japan: Physical Society of Japan, 2003.

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Stancil, Daniel D., and Anil Prabhakar. Spin Waves. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-68582-9.

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D, Stancil Daniel, and SpringerLink (Online service), eds. Spin Waves: Theory and Applications. Boston, MA: Springer-Verlag US, 2009.

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Spin systems. Singapore: World Scientific, 1989.

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Viola Kusminskiy, Silvia. Quantum Magnetism, Spin Waves, and Optical Cavities. Cham: Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-13345-0.

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Coonts, Stephen. Death wave. London: Quercus, 2011.

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Alberola, Octavio. Spain, 1962: The third wave of the struggle against Franco. [London?]: Kate Sharpley Library, 1993.

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A, Melkov G., ed. Magnetization oscillations and waves. Boca Raton: CRC Press, 1996.

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Book chapters on the topic "Spin wave"

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Williams, Floyd. "Spin Wave Functions." In Topics in Quantum Mechanics, 233–52. Boston, MA: Birkhäuser Boston, 2003. http://dx.doi.org/10.1007/978-1-4612-0009-3_10.

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Auerbach, Assa. "Spin Wave Theory." In Graduate Texts in Contemporary Physics, 113–27. New York, NY: Springer New York, 1994. http://dx.doi.org/10.1007/978-1-4612-0869-3_11.

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Parkinson, John B., and Damian J. J. Farnell. "Spin-Wave Theory." In An Introduction to Quantum Spin Systems, 77–88. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-13290-2_7.

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Stancil, Daniel D., and Anil Prabhakar. "Optical-Spin Wave Interactions." In Spin Waves, 223–61. Boston, MA: Springer US, 2009. http://dx.doi.org/10.1007/978-0-387-77865-5_8.

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Stancil, Daniel D., and Anil Prabhakar. "Optical-Spin Wave Interactions." In Spin Waves, 155–92. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-68582-9_8.

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Maki, K. "Spin Density Wave and Field Induced Spin Density Wave Transport." In Springer Proceedings in Physics, 91–96. Berlin, Heidelberg: Springer Berlin Heidelberg, 1990. http://dx.doi.org/10.1007/978-3-642-75424-1_19.

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Khitun, Alexander, and llya Krivorotov. "Spin Wave Logic Devices." In Spintronics Handbook: Spin Transport and Magnetism, Second Edition, 571–600. Second edition. | Boca Raton : Taylor & Francis, CRC Press, 2018. |: CRC Press, 2019. http://dx.doi.org/10.1201/9780429441189-18.

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Wojtczak, Leszek, and Helmut Gärtner. "Spin Wave Resonance Profiles." In Deformations of Mathematical Structures II, 307–16. Dordrecht: Springer Netherlands, 1994. http://dx.doi.org/10.1007/978-94-011-1896-5_14.

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Yosida, Kei. "Spin-Wave Theory of Ferromagnets." In Theory of Magnetism, 107–23. Berlin, Heidelberg: Springer Berlin Heidelberg, 1996. http://dx.doi.org/10.1007/978-3-662-03297-8_8.

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Yosida, Kei. "Spin-Wave Theory of Antiferromagnets." In Theory of Magnetism, 125–43. Berlin, Heidelberg: Springer Berlin Heidelberg, 1996. http://dx.doi.org/10.1007/978-3-662-03297-8_9.

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Conference papers on the topic "Spin wave"

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Alzate, J. G., J. Hockel, A. Bur, G. P. Carman, S. Bender, Y. Tserkovnyak, J. Zhu, et al. "Spin wave nanofabric update." In the 2012 IEEE/ACM International Symposium. New York, New York, USA: ACM Press, 2012. http://dx.doi.org/10.1145/2765491.2765526.

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Nakatani, Y., A. Thiaville, and J. Miltat. "Spin wave instability by spin-polarized current injection." In INTERMAG Asia 2005: Digest of the IEEE International Magnetics Conference. IEEE, 2005. http://dx.doi.org/10.1109/intmag.2005.1464026.

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Mahmoud, Abdulqader, Frederic Vanderveken, Christoph Adelmann, Florin Ciubotaru, Said Hamdioui, and Sorin Cotofana. "Achieving Wave Pipelining in Spin Wave Technology." In 2021 22nd International Symposium on Quality Electronic Design (ISQED). IEEE, 2021. http://dx.doi.org/10.1109/isqed51717.2021.9424264.

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Yoon, J., J. Lee, J. Kwon, P. Deorani, J. Sinha, K. Lee, M. Hayashi, and H. Yang. "Spin wave switch using giant nonreciprocal emission of spin waves in Ta/Py." In 2017 IEEE International Magnetics Conference (INTERMAG). IEEE, 2017. http://dx.doi.org/10.1109/intmag.2017.8007807.

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Papp, Adam, Gyorgy Csaba, George I. Bourianoff, and Wolfgang Porod. "Spin-wave-based computing devices." In 2014 IEEE 14th International Conference on Nanotechnology (IEEE-NANO). IEEE, 2014. http://dx.doi.org/10.1109/nano.2014.6968127.

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Shabadi, Prasad, Alexander Khitun, Kin Wong, P. Khalili Amiri, Kang L. Wang, and C. Andras Moritz. "Spin wave functions nanofabric update." In 2011 IEEE/ACM International Symposium on Nanoscale Architectures (NANOARCH). IEEE, 2011. http://dx.doi.org/10.1109/nanoarch.2011.5941491.

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Mahmoud, Abdulqader, Frederic Vanderveken, Florin Ciubotaru, Christoph Adelmann, Sorin Cotofana, and Said Hamdioui. "Spin Wave Based Full Adder." In 2021 IEEE International Symposium on Circuits and Systems (ISCAS). IEEE, 2021. http://dx.doi.org/10.1109/iscas51556.2021.9401524.

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Girard, M., E. Barthel, and C. Bourbonnais. "Phason and spin wave contributions to nuclear relaxation in the spin-density-wave state." In International Conference on Science and Technology of Synthetic Metals. IEEE, 1994. http://dx.doi.org/10.1109/stsm.1994.835913.

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Bao, Mingqiang, Kin Wong, Alexander Khitun, and Kang L. Wang. "Nonreciprocal amplification of spin-wave signals." In 2010 68th Annual Device Research Conference (DRC). IEEE, 2010. http://dx.doi.org/10.1109/drc.2010.5551853.

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Funada, S., T. Nishimura, Y. Shiota, S. Kasukawa, M. Ishibashi, T. Moriyama, and T. Ono. "Spin Wave Propagation in Ferrimagnetic GdCo." In 2019 International Conference on Solid State Devices and Materials. The Japan Society of Applied Physics, 2019. http://dx.doi.org/10.7567/ssdm.2019.ps-9-08.

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Reports on the topic "Spin wave"

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Cahill, David. Extraordinary Spin-Wave Thermal Conductivity in Low-Dimensional Copper Oxides. Fort Belvoir, VA: Defense Technical Information Center, January 2015. http://dx.doi.org/10.21236/ada622603.

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Savukov, Igor Mykhaylovich, and Alexander Malyzhenkov. Simulations of non-local spin interaction in atomic magnetometers using LANL’s D-Wave 2X. Office of Scientific and Technical Information (OSTI), April 2017. http://dx.doi.org/10.2172/1356167.

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Fernandez-Baca, J. A., E. Fawcett, H. L. Alberts, V. Yu Galkin, and Y. Endoh. Effect of pressure on the magnetic phase diagram of the antiferromagnetic spin-density-wave alloy Cr-1.6% Si. Office of Scientific and Technical Information (OSTI), December 1996. http://dx.doi.org/10.2172/425297.

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Pechan, M. Investigation of magnetic anisotropy and spin wave modes in transition metal multilayers: Technical progress report, August 1988--July 1989. Office of Scientific and Technical Information (OSTI), January 1989. http://dx.doi.org/10.2172/5948675.

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Williams, Michael. Measurement of Differential Cross Sections and Spin Density matrix elements along with a Partial Wave Analysis for γp → pω Using CLAS at JLab. Office of Scientific and Technical Information (OSTI), November 2007. http://dx.doi.org/10.2172/955709.

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Rahmani, Mehran, and Manan Naik. Structural Identification and Damage Detection in Bridges using Wave Method and Uniform Shear Beam Models: A Feasibility Study. Mineta Transportation Institute, February 2021. http://dx.doi.org/10.31979/mti.2021.1934.

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This report presents a wave method to be used for the structural identification and damage detection of structural components in bridges, e.g., bridge piers. This method has proven to be promising when applied to real structures and large amplitude responses in buildings (e.g., mid-rise and high-rise buildings). This study is the first application of the method to damaged bridge structures. The bridge identification was performed using wave propagation in a simple uniform shear beam model. The method identifies a wave velocity for the structure by fitting an equivalent uniform shear beam model to the impulse response functions of the recorded earthquake response. The structural damage is detected by measuring changes in the identified velocities from one damaging event to another. The method uses the acceleration response recorded in the structure to detect damage. In this study, the acceleration response from a shake-table four-span bridge tested to failure was used. Pairs of sensors were identified to represent a specific wave passage in the bridge. Wave velocities were identified for several sensor pairs and various shaking intensities are reported; further, actual observed damage in the bridge was compared with the detected reductions in the identified velocities. The results show that the identified shear wave velocities presented a decreasing trend as the shaking intensity was increased, and the average percentage reduction in the velocities was consistent with the overall observed damage in the bridge. However, there was no clear correlation between a specific wave passage and the observed reduction in the velocities. This indicates that the uniform shear beam model was too simple to localize the damage in the bridge. Instead, it provides a proxy for the overall extent of change in the response due to damage.
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