The introduction of secondary metal ions into monometallic metal–organic frameworks (MOFs) has emerged as an effective strategy for enhancing energy storage properties compared to their monometallic counterparts. Bimetallic MOFs exhibit superior performance due to their increased active site density, optimized local crystallinity, and reduced long-range disorder. Using a facile room-temperature stirring method, we successfully synthesized Ni/Co bimetallic MOFs, with the Ni/Co-MOF (NC-7) material achieving an exceptional synthesis yield of 98.7%. Electrochemical characterization demonstrates that NC-7 delivers a reversible specific discharge capacity of 1063.2/1077.4 mAh·g−1 at 0.1 A·g−1, surpassing those of the corresponding Co- and Ni-based monometallic MOFs. Remarkably, the NC-7 electrode maintains outstanding cycling stability, retaining 70.42% of its capacity after 60 cycles at −30 °C and exhibiting a 37.1% enhancement at 60 °C. When assembled into full cells with LiFePO4 cathodes, the material retains a specific capacity of 191.0 mAh·g−1 after 100 cycles at 0.1 A·g−1. To further elucidate the lithium storage mechanism, we conducted in-situ Fourier-transform infrared (FTIR) spectroscopy to dynamically characterize the first-cycle charge–discharge process. The in-situ FTIR analysis revealed reversible C=C/COO− vibrational changes (1250–1310 cm−1) during lithiation/delithiation, confirming synergistic lithium storage via carboxylate-benzene conjugation in NC-7. These findings not only validate the potential of bimetallic MOFs in energy storage applications but also establish foundational guidelines for rational material design and performance optimization.
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In addition to their many well-known advantages (e.g., ultra-high porosity, good pore size distribution, easy functionalization, and structural tolerability), metal-organic frameworks (MOFs) are a new class of advanced functional materials. However, their backbones are highly susceptible to deformation after exposure to acidic or alkaline conditions. As a result of lithium-ion batteries embedding or detaching directly from MOFs, they irreversibly collapse. As a result, they fail to maintain their electrochemical performance. These factors have hindered the development of MOFs as direct electrode materials, making the design of MOF materials with controlled morphology and stable dimensions a new challenge. In this study, we adopted a versatile and effective method to synthesize a novel MOF material (NiCo-BP (BP = BTC/phen and BTC = 1,3,5-benzenetricarboxylic acid)) using the rigid ligands 1,10-phenanthroline and homobenzotrizoic acid, and the emergence of the Ni–O/N and Co–O/N coordination layers was observed by extended X-ray absorption fine structure (EXAFS) tests, indicating that Ni and Co were coordinated with heterocyclic N-given atoms to form a stable p–π conjugated structure. Meanwhile, the metal-ion is attached to the carboxylic acid ligand on the other side, making the metal-organic skeleton complete and robust. The nanosphere structure of NiCo-BP (~ 400 nm) allows for full exposure and utilisation of the active sites, especially the Ni, Co, and phenanthroline units, and exhibit impressively high specific capacity and cycling stability. At a high current density of 1.0 A·g−1, a high discharge specific capacity of 631.6 mAh·g−1 was obtained after 1000 cycles. The co-participation of two organic ligands in the coordination is in accordance with the theory of soft and hard acids and bases, which contributes to the ability of the material to maintain a high capacity in cycling as well as its cyclic stability.
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