Electrochemical Activation, Sintering, and Reconstruction in Energy‐Storage Technologies: Origin, Development, and Prospects

Abstract: Her research interests focus on the design of nano/micromaterials toward energy storage and conversion (i.e., Li-, Na-, and K-ion batteries) application. She joined Prof. Shibing Ni's group at the China Three Gorges University in 2020. Now she works as a lecturer at the College of Materials and Chemical Engineering, and concentrates on the morphological and structural evolution of electrode materials during cycling.

“…A slow increase in the capacity during cycling may stem from the electrochemical activation of electrodes with continuous charge/discharge processes. 44 The capacity and cyclability of the LVO@NC NSs electrode at low current densities were also distinctly improved compared to those of the reported LVO/C electrodes (Table 1). Meanwhile, the representative charge/ discharge profiles of the LVO@NC NSs exhibit the highest reproducibility (Figure S8), which suggests the best durability of the LVO@NC NSs in cycling.…”

“…Obviously, except for the initial capacity loss caused by the presence of the SEI film, the LVO@NC NSs electrode presents ultrahigh stability with the highest capacity of 628.4 mAh g –1 at the 300th cycle. A slow increase in the capacity during cycling may stem from the electrochemical activation of electrodes with continuous charge/discharge processes . The capacity and cyclability of the LVO@NC NSs electrode at low current densities were also distinctly improved compared to those of the reported LVO/C electrodes (Table ).…”

“…59 More importantly, the specific primary architecture of the LVO@NC NSs, i.e., ultrasmall LVO nanoparticles integrated in the NC layer (LVO@NC), is self-adaptive in cycling: (1) the LVO nanoparticles could be gradually activated with decreased size, showing enhanced Li + diffusion; 44 (2) the in situ activated LVO could deliver reinforced contact with the NC layer. 8,44 As a result, the excellent charge transport kinetics of the LVO@NC NSs could be obtained and well sustained during charge/discharge processes, leading to the enhanced high-rate and long lifespan Li-ion storage. 60−63 On the basis of the prominent electrochemical performance, the potential prospect application of the LVO@NC NSs was preliminarily assessed.…”

“…In addition, the integral morphology and the microstructure of the LVO@NC NSs endow it with excellent reaction kinetics: (1) the integral 2D morphology facilitates efficient electrolyte permeation and reactions with the active material; (2) the interconnected C network is advantageous for rapid electron transfer; (3) the small LVO particles are beneficial for fast Li + diffusion . More importantly, the specific primary architecture of the LVO@NC NSs, i.e., ultrasmall LVO nanoparticles integrated in the NC layer (LVO@NC), is self-adaptive in cycling: (1) the LVO nanoparticles could be gradually activated with decreased size, showing enhanced Li + diffusion; (2) the in situ activated LVO could deliver reinforced contact with the NC layer. , As a result, the excellent charge transport kinetics of the LVO@NC NSs could be obtained and well sustained during charge/discharge processes, leading to the enhanced high-rate and long lifespan Li-ion storage. − …”

Hierarchical Self-Assembly Strategy for Scalable Synthesis of Li₃VO₄/N Doped C Nanosheets for High-Rate Li-Ion Storage

“…A slow increase in the capacity during cycling may stem from the electrochemical activation of electrodes with continuous charge/discharge processes. 44 The capacity and cyclability of the LVO@NC NSs electrode at low current densities were also distinctly improved compared to those of the reported LVO/C electrodes (Table 1). Meanwhile, the representative charge/ discharge profiles of the LVO@NC NSs exhibit the highest reproducibility (Figure S8), which suggests the best durability of the LVO@NC NSs in cycling.…”

“…Obviously, except for the initial capacity loss caused by the presence of the SEI film, the LVO@NC NSs electrode presents ultrahigh stability with the highest capacity of 628.4 mAh g –1 at the 300th cycle. A slow increase in the capacity during cycling may stem from the electrochemical activation of electrodes with continuous charge/discharge processes . The capacity and cyclability of the LVO@NC NSs electrode at low current densities were also distinctly improved compared to those of the reported LVO/C electrodes (Table ).…”

“…59 More importantly, the specific primary architecture of the LVO@NC NSs, i.e., ultrasmall LVO nanoparticles integrated in the NC layer (LVO@NC), is self-adaptive in cycling: (1) the LVO nanoparticles could be gradually activated with decreased size, showing enhanced Li + diffusion; 44 (2) the in situ activated LVO could deliver reinforced contact with the NC layer. 8,44 As a result, the excellent charge transport kinetics of the LVO@NC NSs could be obtained and well sustained during charge/discharge processes, leading to the enhanced high-rate and long lifespan Li-ion storage. 60−63 On the basis of the prominent electrochemical performance, the potential prospect application of the LVO@NC NSs was preliminarily assessed.…”

“…In addition, the integral morphology and the microstructure of the LVO@NC NSs endow it with excellent reaction kinetics: (1) the integral 2D morphology facilitates efficient electrolyte permeation and reactions with the active material; (2) the interconnected C network is advantageous for rapid electron transfer; (3) the small LVO particles are beneficial for fast Li + diffusion . More importantly, the specific primary architecture of the LVO@NC NSs, i.e., ultrasmall LVO nanoparticles integrated in the NC layer (LVO@NC), is self-adaptive in cycling: (1) the LVO nanoparticles could be gradually activated with decreased size, showing enhanced Li + diffusion; (2) the in situ activated LVO could deliver reinforced contact with the NC layer. , As a result, the excellent charge transport kinetics of the LVO@NC NSs could be obtained and well sustained during charge/discharge processes, leading to the enhanced high-rate and long lifespan Li-ion storage. − …”

Hierarchical Self-Assembly Strategy for Scalable Synthesis of Li₃VO₄/N Doped C Nanosheets for High-Rate Li-Ion Storage

“…[1,2] Aqueous hybrid supercapacitors use capacitive materials as the negative electrode and battery-type materials as the positive electrode, combining the fast charging/discharging and long lifespan of capacitive materials with the high capacity of battery-type It should be noted that the reconstruction phenomenon in an electrochemical environment is a common problem prevalent in the field of electrocatalysis and electrochemical energy storage. [19][20][21][22] This reconstruction process is inevitable for TMCs, etc., and can be predicted by thermodynamics, and TMCs actually act as a self-sacrificing precursor. [23,24] TMCs, etc.…”

Potentiostatic Reconstruction of Nickel‐Cobalt Hydroxysulfate with Self‐Optimized Structure for Enhancing Energy Storage

Flexible Polymer Hydrogels for Wearable Energy Storage Applications