Abstract
Many energy storage materials undergo large volume changes during charging and discharging. The resulting stresses often lead to defect formation in the bulk, but less so in nanosized systems. Here, we capture in real time the mechanism of one such transformation—the hydrogenation of single-crystalline palladium nanocubes from 15 to 80 nm—to better understand the reason for this durability. First, using environmental scanning transmission electron microscopy, we monitor the hydrogen absorption process in real time with 3 nm resolution. Then, using dark-field imaging, we structurally examine the reaction intermediates with 1 nm resolution. The reaction proceeds through nucleation and growth of the new phase in corners of the nanocubes. As the hydrogenated phase propagates across the particles, portions of the lattice misorient by 1.5%, diminishing crystal quality. Once transformed, all the particles explored return to a pristine state. The nanoparticles’ ability to remove crystallographic imperfections renders them more durable than their bulk counterparts.
Highlights
Many energy storage materials undergo large volume changes during charging and discharging
The large stresses resulting from volume changes cause the formation of several misfit dislocations and eventual fracture, which reduce the cyclability of the system[7,8,9,10,11,12]
The phase transformation behaviour of PdHx is well known in the bulk, but the changes at the level of individual nanoparticles are only starting to be addressed, thanks to the development of several single-particle techniques, including in situ transmission electron microscopy (TEM)[23,27,28], plasmonic nanospectroscopy[29,30] and coherent X-ray diffractive imaging[21]
Summary
Many energy storage materials undergo large volume changes during charging and discharging. The phase transformation behaviour of PdHx is well known in the bulk, but the changes at the level of individual nanoparticles are only starting to be addressed, thanks to the development of several single-particle techniques, including in situ transmission electron microscopy (TEM)[23,27,28], plasmonic nanospectroscopy[29,30] and coherent X-ray diffractive imaging[21].
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