Understanding
the phase transition and Li-ion diffusion kinetics
of Li-ion storage nanomaterials holds promising keys to further improve
the cycle life and charge rate of the Li-ion battery. Traditional
electrochemical studies were often based on a bulk electrode consisting
of billions of electroactive nanoparticles, which washed out the intrinsic
heterogeneity among individuals. Here, we employ optical microscopy,
termed surface plasmon resonance microscopy (SPRM), to image electrochemical
current of single LiCoO2 nanoparticles down to 50 fA during
electrochemical cycling, from which the phase transition and Li-ion
diffusion kinetics can be quantitatively resolved in a single nanoparticle,
in operando and high throughput manner. SPRM maps the refractive index
(RI) of single LiCoO2 nanoparticles, which significantly
decreases with the gradual extraction of Li-ions, enabling the optical
read-out of single nanoparticle electrochemistry. Further scanning
electron microscopy characterization of the same batch of nanoparticles
led to a bottom-up strategy for studying the structure–activity
relationship. As RI is an intrinsic property of any material, the
present approach is anticipated to be applicable for versatile kinds
of anode and cathode materials, and to facilitate the rational design
and optimization toward durable and fast-charging electrode materials.