Ultrafast Helicity-Independent All-Optical Switching in Amorphous (Gd,Tb)Co Thin Films

Ultrafast control of the magnetization in ps timescales by fs laser pulses offers an attractive avenue for applications such as fast magnetic devices for logic and memory. However, ultrafast helicity-independent all-optical switching (HI-AOS) of the magnetization has thus far only been observed in Gd-based, ferrimagnetic rare earth-transition metal (RE-TM) systems, and a comprehensive understanding of the reversal mechanism remains elusive. Here, we report HI-AOS in amorphous (\textit{a}-), ferrimagnetic \textit{a}-Gd$_{22-x}$Tb$_x$Co$_{78}$ thin films, from x = 0 to x = 18, and elucidate the role of Gd in HI-AOS in RE-TM alloys and multilayers. Increasing Tb content results in slower remagnetization rates and higher critical fluences for switching. Simulations of the atomistic spin dynamics based on the two-temperature model reproduce these results qualitatively and predict that the low damping on the RE sublattice arising from the small spin-orbit coupling of Gd (with $L = 0$) is instrumental for the faster dynamics and lower critical fluences of the Gd-rich alloys. Increasing the RE damping on \textit{a}-Gd$_{10}$Tb$_{12}$Co$_{78}$ sublattice by annealing leads to slower dynamics, confirming this prediction. These simulations strongly indicate that taking account of element specific damping, rather than a net damping of the system, is crucial in understanding HI-AOS phenomena, and the results suggest that engineering the element specific damping of materials can open up new classes of materials that exhibit low-energy, ultrafast HI-AOS.