Morphology-dependent electrochemical performance of Ni-1,3,5-benzenetricarboxylate metal-organic frameworks as an anode material for Li-ion batteries

“…During the subsequent cycles, the slope voltage plateaus shifted to about 1.95 V, which could be assigned to the insertion process of Li + . [26] In the 50 th and 100 th charging curve the discharging platform at 1.95, 0.57 V, and the charging platform at 2.74 V showed up, consistent with the CV diagrams.…”

“…[19,20] Recently, pristine MOFs have been studied as electrode materials for lithium batteries and displayed high specific capacities. [21][22][23][24][25][26] The corresponding mechanism has been adequately addressed, which is inspiring for the further development of LIBs. However, it is still elusive that the electrochemical performances of MOFs are occasionally erratic in different reports.…”

“…[21] However, the same substance synthesized by Ji and Wang displayed insignificant lithium storage capacity. [27,28] Also, Ni-BTC with different morphologies showed great differences in electrochemical performance, [26] and the cycle stability was imperfect, as speculated from the small charge and discharge cycle number. Till now, a series of MOFs were reported as excellent functional materials for LIBs, while these reports mainly focused on the synthesis and design of the chemical composition, molecular structure, and morphology, [22,26] whereas the electrode preparation process is also crucial.…”

“…[29] Also, the measured specific capacity of MOFs is relevant to the higher activation temperature. [21,26] Therefore, in this work Cu-BTC is taken as a MOF example to explore the better fabrication conditions to improve the electrochemical performance of MOFs. The effects of polymer binders, activation temperature, and synthesis methods on the lithium storage performance of Cu-BTC are carefully studied.…”

Strategies to Optimize the Lithium Storage Capability of the Metal‐Organic Framework Copper‐1,3,5‐Trimesic Acid (Cu‐BTC)

“…During the subsequent cycles, the slope voltage plateaus shifted to about 1.95 V, which could be assigned to the insertion process of Li + . [26] In the 50 th and 100 th charging curve the discharging platform at 1.95, 0.57 V, and the charging platform at 2.74 V showed up, consistent with the CV diagrams.…”

“…[19,20] Recently, pristine MOFs have been studied as electrode materials for lithium batteries and displayed high specific capacities. [21][22][23][24][25][26] The corresponding mechanism has been adequately addressed, which is inspiring for the further development of LIBs. However, it is still elusive that the electrochemical performances of MOFs are occasionally erratic in different reports.…”

“…[21] However, the same substance synthesized by Ji and Wang displayed insignificant lithium storage capacity. [27,28] Also, Ni-BTC with different morphologies showed great differences in electrochemical performance, [26] and the cycle stability was imperfect, as speculated from the small charge and discharge cycle number. Till now, a series of MOFs were reported as excellent functional materials for LIBs, while these reports mainly focused on the synthesis and design of the chemical composition, molecular structure, and morphology, [22,26] whereas the electrode preparation process is also crucial.…”

“…[29] Also, the measured specific capacity of MOFs is relevant to the higher activation temperature. [21,26] Therefore, in this work Cu-BTC is taken as a MOF example to explore the better fabrication conditions to improve the electrochemical performance of MOFs. The effects of polymer binders, activation temperature, and synthesis methods on the lithium storage performance of Cu-BTC are carefully studied.…”

Strategies to Optimize the Lithium Storage Capability of the Metal‐Organic Framework Copper‐1,3,5‐Trimesic Acid (Cu‐BTC)

“…From the TG curve, the initial weight loss of about 2.7% from room temperature to 100 °C, which can be considered as the removal of water molecules adsorbed on the surface. The weight loss between 100 and 300 °C was about 23.9% due to the solvent vaporization in the ink bottle structure of the Cu–MOF . The decomposition of the tetracarboxylate linker and the subsequent collapse of the MOF frame occurred at 300–400 °C, and thus the weight decreased by 60.05%.…”

Metal‐organic Framework of [Cu₂(BIPA‐TC)(DMA)₂]n: A Promising Anode Material for Lithium‐Ion Battery

Synthesis of Tostadas‐Shaped Metal‐Organic Frameworks for Remitting Capacity Fading of Li‐Ion Batteries