High Mass Loading of Edge-Exposed Cu3P Nanocrystal in 3D Freestanding Matrix Regulating Lithiophilic Sites for High-Performance Lithium Metal Anode

• Published in: ACS applied materials & interfaces Vol. 15; no. 24; pp. 29352 - 29362
• Main Authors: Zhang, Xuzi, Chen, Jiawei, Li, Pengcheng, Ayranci, Cagri, Li, Ge
• Format: Journal Article
• Language: English
• Published: American Chemical Society 21.06.2023
• Subjects: anodes; carbon; carbon nanofibers; electric potential difference; Functional Nanostructured Materials (including low-D carbon); hysteresis; lithium; nanocrystals; nanoparticles; limit Li; edge-exposed Cu3P nanocrystal; abundant exposed P3− sites; 3D carbon matrix; dominant facets
• ISSN: 1944-8244; 1944-8252; 1944-8252
• DOI: 10.1021/acsami.3c00740

Lithium (Li) dendrites and volume expansion during repeated Li plating and stripping processes are the major obstacles to the development of advanced Li metal batteries. Li nucleation and dendrite growth can be controlled and inhibited spatially by using 3-dimensional (3D) hosts together with efficient lithiophilic materials. To realize next-generation Li-metal batteries, it is critical to effectively regulate the surface structure of the lithiophilic crystals. Herein, exposed-edged Cu3P faceted nanoparticles anchored along the interlaced carbon nanofibers (ECP@CNF) are developed as a highly efficient 3D Li host. Through the 3D interlaced rigid carbon skeleton, volume expansion can be accommodated. The (300)-dominant edged crystal facets of Cu3P with abundant exposed P3– sites not only exhibit strong micro-structural Li affinity but also have relatively high charge transference to nucleate uniformly and effectively, resulting in reduced polarization. Consequently, under a high current density of 10 mA cm–2 with a high discharge of depth (60%), ECP@CNF/Li symmetric cells demonstrate outstanding cycling stability for 500 h with a small voltage hysteresis of 32.8 mV. Notably, the ECP@CNF/Li∥LiFePO4 full cell exhibits a more stable cycling performance for 650 cycles under a high rate of 1 C, with capacity retention up to 92% (N/P = 10, 4.7 mg cm–2 LiFePO4). Even under a limit Li (3.4 mA h) with an N/P ratio of 2 (8.9 mg cm–2 LiFePO4), ECP@CNF/Li∥LiFePO4 full cell can also demonstrate excellent reversibility and stable cycling performance with higher utilization of Li. This work provides an insight view into constructing high-performance Li-metal batteries under more strict conditions.