Disentangling Electronic and Magnetic Order in NdNiO$_3$ at Ultrafast Timescales

Understanding how emergent phases arise from microscopic interactions in quantum materials is of fundamental importance. Long range order can be strongly influenced by cooperative or competing interactions, an important example being lattice and magnetic degrees of freedom operative in numerous materials exhibiting insulator-to-metal transitions (IMTs). Ultrashort x-ray pulses provide a powerful approach to temporally disentangle magnetic and structural dynamics, yielding new insights into the subtleties of cooperative or competitive behavior that influence IMTs. Here we utilize femtosecond soft x-ray pulses to simultaneously probe the magnetic and electronic order following optical excitation in NdNiO$_3$ (NNO), a model nickelate exhibiting structural and magnetic dynamics that conspire to induce an IMT. During the course of the photoinduced IMT (above gap excitation), we observe an ultrafast ($<$ 180fs) quenching of magnetic order followed by a slower collapse of the insulating phase probed by X-ray absorption and THz transmission ($\sim$450fs). Pump wavelength dependence indicates that an intersite charge transfer (ICT) excitation is a crucial ingredient to initiate the non-thermal IMT dynamics. Density functional theory (DFT) calculations reveal a consistent scenario where ICT drives a collapse of antiferromagnetic order, dynamically preparing NNO for subsequent octahedral breathing mode relaxation that leads to the metallic phase.