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Title: Angular and temperature dependence of current induced spin-orbit effective fields in Ta/CoFeB/MgO nanowires
Authors: Qiu, X.
Deorani, P.
Narayanapillai, K.
Lee, K.-S.
Lee, K.-J.
Lee, H.-W.
Yang, H. 
Issue Date: 27-Mar-2014
Citation: Qiu, X., Deorani, P., Narayanapillai, K., Lee, K.-S., Lee, K.-J., Lee, H.-W., Yang, H. (2014-03-27). Angular and temperature dependence of current induced spin-orbit effective fields in Ta/CoFeB/MgO nanowires. Scientific Reports 4 : -. ScholarBank@NUS Repository.
Abstract: Current induced spin-orbit effective magnetic fields in metal/ferromagnet/oxide trilayers provide a new way to manipulate the magnetization, which is an alternative to the conventional current induced spin transfer torque arising from noncollinear magnetization. Ta/CoFeB/MgO structures are expected to be useful for non-volatile memories and logic devices due to its perpendicular anisotropy and large current induced spin-orbit effective fields. However many aspects such as the angular and temperature dependent phenomena of the effective fields are little understood. Here, we evaluate the angular and temperature dependence of the current-induced spin-orbit effective fields considering contributions from both the anomalous and planar Hall effects. The longitudinal and transverse components of effective fields are found to have strong angular dependence on the magnetization direction at 300â..K. The transverse field decreases significantly with decreasing temperature, whereas the longitudinal field shows weaker temperature dependence. Our results reveal important features and provide an opportunity for a more comprehensive understanding of current induced spin-orbit effective fields.
Source Title: Scientific Reports
ISSN: 20452322
DOI: 10.1038/srep04491
Appears in Collections:Staff Publications

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