Special on DW propagation in nanowires

Spin wave emission in field-driven domain wall motion.
X. S. Wang and X. R. Wang
Phys. Rev. B 90, 184415 (2014)

(a) Schematic diagram of a 1D head-to-head DW (top-left inset) and the snapshot of s components at t=200 for α=0,J=53.7,Dz=0.317,Dz/Dx=10, and H=0.5. Lower-left inset: The s profile of DW. Symbols are numerical results, the vertical dashed line indicates the DW center position at z=0.9, and solid lines are the Walker profile (4) with ϕ=Ht and Z=0.9. Right inset: The simulated motion evolution of the DW center (black curve), the time dependence of the DW center by the collective coordinate model (red curve), and their difference (blue curve). (b) The field dependence of average DW speed v for different Dz and Dx. Vertical dashed and solid lines correspond to critical fields Hc1 and Hc2, respectively. Inset: Simulated DW center for fields below and above Hc1 (indicated by arrows in the main figure).

Domain wall pinning in notched nanowires.
H. Y. Yuan and X. R. Wang

Phys. Rev. B 89, 054423 (2014)

Snapshots of the spin configuration around the notch as the field increases from zero up over the depinning field. (a) H=0 Oe, (b) H=100 Oe, (c) H=170 Oe, and (d) H=180 Oe. For clarity, each spin represents the average magnetization of four 4 × 4 × 4 nm cells. The nanowire dimensions are 1000 × 64 × 4 nm, and the notch dimensions are 40 × 32 × 4 nm. (e) The evolution of m¯zCD and m¯zEF with applied field.

Instability of Walker Propagating Domain Wall in Magnetic Nanowires

B. Hu and X. R. Wang

Phys. Rev. Lett. 111, 027205 (2013)

Illustration of transverse head-to-head DW of width Δ in a nanowire, with easy axis along ẑ and hard axis along x̂. In the absence of external magnetic field (upper), a static DW exists between two domains with m_z=±1. Under a field parallel to the easy axis, the Walker propagating DW moves towards the energy minimum state (m_z=-1) at a speed v while the DW profile is preserved.

Direct Imaging of Thermally Driven Domain Wall Motion in Magnetic Insulators.
Wanjun Jiang, Pramey Upadhyaya, Yabin Fan, Jing Zhao, Minsheng Wang, Li-Te Chang, Murong Lang, Kin L. Wong, Mark Lewis, Yen-Ting Lin, Jianshi Tang, Sergiy Cherepov, Xuezhi Zhou, Yaroslav Tserkovnyak, Robert N. Schwartz, and Kang L. Wang
Phys. Rev. Lett. 110, 177202 (2013)

Experimental demonstration of DW motion driven by a temperature gradient. (a) The schematic illustration of polar MOKE microscope for DW imaging. (b) and (c) M vs H hysteresis loops measured using a MOKE magnetometer for polar and longitudinal orientations, respectively. (d) Snapshots of the position of the DW as a function of time in the cold region, and hot region (e), respectively. It is noted that there is no time correlation between figures (d) and (e). The blue color corresponds to magnetization along +z direction, and white color associates with the magnetization along -z direction. Each fingerlike pattern thus contains two parallel DWs

Domain Wall Propagation through Spin Wave Emission.
X. S. Wang, P. Yan, Y. H. Shen, G. E. W. Bauer, and X. R. Wang
Phys. Rev. Lett. 109, 167209 (2012)

Schematic transverse head-to-head DW of width Δ in a magnetic nanowire. H⃗ is an external field along the wire axis defined as the z direction. DW breathing and other types of periodic DW deformations emit spin waves, denoted by the wavy lines with arrows.