Robust Vertical Exchange Bias Modulates Spin Decoherence in 0D Core–Shell Nanoparticles

While recent advancements in spin manipulation have utilized topological insulators and non-collinear antiferromagnets confined to two-dimensional films, dimensional limitations have hindered the realization of truly freestanding spin-dependent quantum nanodevices (nm3). Here, we exploit a robust vertical exchange bias confined within core–shell FePt@MnO nanoparticles (D ∼ 9 nm) to control the spin decoherence time of Fe and Mn magnetic atoms. The magnitude (approximately 17% of interfacial spins are fully pinned) and robustness (the pinned spins remain stable even under a negative field of −5 T) of this anomalous exchange bias arise from a coherent interface where strain-induced lattice distortion displaces Mn cations by ångström-scale distances from their equilibrium positions, aligning them with Fe cations. This interfacial coherence enhances interfacial spin–spin exchange couplingmanifested as the anomalous exchange-bias effectwhich directly modulates spin decoherence dynamics: τ2 for Mn2+ spins shortens by 9.8% (108.3 ps → 98.5 ps), while Fe spins exhibit a concomitant τ2 enhancement. This work establishes a direct link between spin decoherence time and the exchange-bias effect, offering a pathway for the coherent engineering of quantum nanomaterials.