Exploiting one dimensional polymer for environmental monitoring: Co based coordination polymer for efficient removal of cationic dyes

“…The essential factors affecting dye adsorption capacity from wastewater are the surface properties of the material framework and the functional and structural behavior of the dye molecules. Ion exchange, hydrogen bonds, acid–base interactions, electrostatic interactions, and π–π interactions are among the many processes that control adsorption as has already been documented in previous studies . In the present work, the plausible adsorption mechanism could be explained on the basis of electrostatic cation−π and π–π interactions that are responsible for the quick adsorption of cationic dye to the surface of 2D Cu-MON as depicted in Figure .…”

“…Ion exchange, hydrogen bonds, acid−base interactions, electrostatic interactions, and π−π interactions are among the many processes that control adsorption as has already been documented in previous studies. 66 In the present work, the plausible adsorption mechanism could be explained on the basis of electrostatic cation−π and π−π interactions that are responsible for the quick adsorption of cationic dye to the surface of 2D Cu-MON as depicted in Figure 14. The primary reason for enhanced MB and RhB dye adsorption could be attributed to the cationic nature of both the dyes that interact electrostatically with the nucleophilic aromatic ring of the TMDP ligand present in 2D Cu-MON.…”

Synthesis of 2D Metal–Organic Nanosheets (MONs) by Liquid Phase Exfoliation: Applications in Effective Delivery of Antiulcer Drugs and Selective Adsorption and Removal of Cationic Dyes

“…The essential factors affecting dye adsorption capacity from wastewater are the surface properties of the material framework and the functional and structural behavior of the dye molecules. Ion exchange, hydrogen bonds, acid–base interactions, electrostatic interactions, and π–π interactions are among the many processes that control adsorption as has already been documented in previous studies . In the present work, the plausible adsorption mechanism could be explained on the basis of electrostatic cation−π and π–π interactions that are responsible for the quick adsorption of cationic dye to the surface of 2D Cu-MON as depicted in Figure .…”

“…Ion exchange, hydrogen bonds, acid−base interactions, electrostatic interactions, and π−π interactions are among the many processes that control adsorption as has already been documented in previous studies. 66 In the present work, the plausible adsorption mechanism could be explained on the basis of electrostatic cation−π and π−π interactions that are responsible for the quick adsorption of cationic dye to the surface of 2D Cu-MON as depicted in Figure 14. The primary reason for enhanced MB and RhB dye adsorption could be attributed to the cationic nature of both the dyes that interact electrostatically with the nucleophilic aromatic ring of the TMDP ligand present in 2D Cu-MON.…”

Synthesis of 2D Metal–Organic Nanosheets (MONs) by Liquid Phase Exfoliation: Applications in Effective Delivery of Antiulcer Drugs and Selective Adsorption and Removal of Cationic Dyes

“…Some more prominent ligands belong to N-and O-donor ligands (imidazole, terephthalic acid, etc.). [85][86][87][88][89] These ligands undergo different decomposition pathways during pyrolysis and can yield carbon materials with drastically different physiochemical properties. 36,80,90 Depending on the desired characteristics and performance, MOFs can be designed to provide highly specific adsorption sites and well-defined pore sizes.…”

A mini review on metal–organic framework-based electrode materials for capacitive deionization

“…Consequently, the multi-functional MOFs with different dimensions (1D–3D) and interesting properties (luminescent sensing, dye adsorption, photocatalysis and proton conduction) may be constructed from the ligands and different metal ions. 3–10…”

Syntheses, crystal structures and thermal decomposition studies of two novel Mn(ii)-MOFs with tetrazole-based carboxylic acids