Picosecond pump pulses probe the relevance of hot electrons for the laser-induced phase transition in FeRh

Recent ultrafast photoemission experiments showed signatures of an ultrafast modification of the electronic band structure in FeRh indicative of a ferromagnetic (FM) state that is initiated by a non-equilibrium occupation of the electronic states upon femtosecond laser excitation. We use ultrafast x-ray diffraction to examine the impact of hot electrons on the antiferromagnetic (AFM) to FM phase transition. By increasing the pump-pulse duration up to $10.5\,\text{ps}$, we eliminate hot electrons and see that the nucleation of FM domains still proceeds at the intrinsic timescale of $8\,\text{ps}$, which starts when the deposited energy surpasses the threshold energy. For long pulses, the phase transition proceeds considerably faster than predicted by a convolution of the dynamics observed for ultrafast excitation with the long pump pulse duration. We predict that quite generally, slow photoexcitation can result in a fast response, if the non-linear threshold behavior of a first-order phase transition is involved.