Your search keyword '"Ikhlas, Muhammad"' showing total 2 results

1. Giant Effective Damping of Octupole Oscillation in an Antiferromagnetic Weyl Semimetal.

Author

Miwa, Shinji, Iihama, Satoshi, Nomoto, Takuya, Tomita, Takahiro, Higo, Tomoya, Ikhlas, Muhammad, Sakamoto, Shoya, Otani, YoshiChika, Mizukami, Shigemi, Arita, Ryotaro, and Nakatsuji, Satoru

Abstract

A magnetic Weyl semimetal is a recent focus of extensive research as it may exhibit large and robust transport phenomena associated with topologically protected Weyl points in momentum space. Since a magnetic texture provides a handle for the configuration of the Weyl points and its transport response, understanding of magnetic dynamics forms the basis for future control of a topological magnet. Mn3Sn is an example of an antiferromagnetic Weyl semimetal that exhibits a large response comparable to the one observed in ferromagnets despite a vanishingly small magnetization. The noncollinear spin order in Mn3Sn can be viewed as a ferroic order of cluster magnetic octupole and breaks the time‐reversal symmetry, stabilizing Weyl points and the significantly enhanced Berry curvature near the Fermi energy. Herein, the first observation of time‐resolved octupole oscillation in Mn3Sn is reported. In particular, the giant effective damping of the octupole dynamics is found, and it is feasible to conduct an ultrafast switching at <10 ps, a hundred times faster than the case of spin‐magnetization in a ferromagnet. Moreover, high domain wall velocity over 10 km s−1 is theoretically predicted. This work paves the path toward realizing ultrafast electronic devices using the topological antiferromagnet. [ABSTRACT FROM AUTHOR]

Published

2021

2. Omnidirectional Control of Large Electrical Output in a Topological Antiferromagnet.

Author

Higo, Tomoya, Li, Yufan, Kondou, Kouta, Qu, Danru, Ikhlas, Muhammad, Uesugi, Ryota, Nishio‐Hamane, Daisuke, Chien, C. L., Otani, YoshiChika, and Nakatsuji, Satoru

Subjects

MAGNETIC anisotropy, MAGNETIC devices, ANOMALOUS Hall effect, DEMAGNETIZATION, MOMENTUM space, NERNST effect

Abstract

Control of magnetization direction is essential for the wide application of ferromagnets; it defines the signal size of memory and sensor. However, the magnetization itself causes a dilemma. While its size matters to obtain strong responses upon its reversal, the large magnetization concomitantly suppresses the range of its directional control because of the demagnetizing field. On the other hand, realization of the desired magnetic anisotropy requires careful engineering of crystalline and interfacial effects to overcome the demagnetization barrier. Thus, it would be ideal if one could find alternative magnets that carry no magnetization but strong responses. The discovery of a topological metallic state in the antiferromagnet Mn3Sn is significant; they host a large Berry curvature in momentum space, enabling the observation of disproportionately large transverse responses such as anomalous Hall and Nernst effects, the key functionalities for replacing ferromagnets in the magnetic devices. Here, the experimental realization of omnidirectional control of the large responses in an antiferromagnet is reported. In particular, it is demonstrated that the absence of shape anisotropy enables the omnidirectional control, and lifts the shape constraint in designing the magnetic devices. This work lays the technological foundation for developing simple‐structured high‐performance devices including multi‐level memory and heat flux sensor. [ABSTRACT FROM AUTHOR]

Published

2021