Crosslinked MnO₂ Nanowires Anchored in Sulfur Self‐Doped Porous Carbon Skeleton with Superior Lithium Storage Performance

Abstract: A facile process for the in‐situ anchoring of crosslinked MnO2 nanowires (MNs) in a preformed sulfur self‐doped porous carbon material (SPC) derived from antibiotic bacterial residues (ABRs) was developed, only involving impregnation of potassium permanganate aqueous solution into SPC and consequently occurring in‐situ redox reaction at room‐temperature. In the obtained SPC@MNs composite, SPC serves as a conductive collector for accelerating lithium‐ion transfer and a buffer carrier for reliving the volume‐exp… Show more

“…The presence of N and S in the porous carbon derived from ABRs is advantageous to enhance the conductivity of carbon matrix [24,27] . The pore size and specific surface area characteristics of NSPC and FF@NSPC were studied by the N 2 absorption/desorption measurements and presented in Figure 3c and d. Figure 3c reveals a typical type‐I isotherm in the NSPC, suggesting the existence of major micropores and partial mesopores [28] . After filling with FeF 3 ⋅ 0.33H 2 O, the pattern of FF@NSPC presents typical type‐IV isotherm corresponding to primary mesopores and fractional micropores [19] …”

N, S Co‐Doped Porous Carbon from Antibiotic Bacteria Residues Enables a High‐Performance FeF₃ ⋅ 0.33H₂O Cathode for Li‐Ion Batteries

“…The presence of N and S in the porous carbon derived from ABRs is advantageous to enhance the conductivity of carbon matrix [24,27] . The pore size and specific surface area characteristics of NSPC and FF@NSPC were studied by the N 2 absorption/desorption measurements and presented in Figure 3c and d. Figure 3c reveals a typical type‐I isotherm in the NSPC, suggesting the existence of major micropores and partial mesopores [28] . After filling with FeF 3 ⋅ 0.33H 2 O, the pattern of FF@NSPC presents typical type‐IV isotherm corresponding to primary mesopores and fractional micropores [19] …”

N, S Co‐Doped Porous Carbon from Antibiotic Bacteria Residues Enables a High‐Performance FeF₃ ⋅ 0.33H₂O Cathode for Li‐Ion Batteries

Encapsulation of N-doped carbon layer via in situ dopamine polymerization endows nanostructured NaTi2(PO4)3 with superior lithium storage performance

First-row transition metal compounds for aqueous metal ion batteries