Performance
degradation of lithium/sodium-ion capacitors (LICs/SICs)
mainly originates from anode pulverization, particularly the alloying
and conversion types, and has spurred research for alternatives with
an insertion mechanism. Three-dimensional (3D) topotactic host materials
remain much unexplored compared to two-dimensional (2D) ones (graphite, etc.). Herein, vanadium monophosphide (VP) is designed as
a 3D topotactic host anode. Ex situ electrochemical
characterizations reveal that there are no phase changes during (de)intercalation,
which follows the topotactic intercalation mechanism. Computational
simulations also confirm the metallic feature and topotactic structure
of VP with a spacious interstitial position for the accommodation
of guest species. To boost the electrochemical performance, carbon
nano-onions (CNOs) are coupled with 3D VP. Superior specific capacity
and rate capability of VP-CNOs vs lithium/sodium
can be delivered due to the fast ion diffusion nature. An exceptional
capacity retention of above 86% is maintained after 20 000
cycles, benefitting from the topotactic intercalation process. The
optimized LICs/SICs exhibit high energy/power densities and an ultrastable
lifespan of 20 000 cycles, which outperform most of the state-of-the-art
LICs and SICs, demonstrating the potential of VP-CNOs as insertion
anodes. This exploration would draw attention with regard to insertion
anodes with 3D topotactic host topology and provide new insights into
anode selection for LICs/SICs.