Pertraction properties of poly(oxyethylene) diphosphoric and dicarboxylic acids as macroionophores in liquid membrane systems

“…The phosphate group is one of the essential components of a variety of biological macromolecules and synthetic materials. Considerable effort has been devoted to the development of synthetic analogues of nucleic acids, lipids and enzymes, as well as the mimicking of some processes that occur in living organisms, [1][2][3][4] for example, selective cation transport in liquid membrane systems 1,[5][6][7] and biomineralization. [8][9][10] Esters of phosphoric acid are often used as starting materials in the synthesis of coordination polymers formed by metal cations linked by organic ligands, molecular clusters, or hybrid inorganic-organic mesostructured lamellar systems.…”

Linear coordination polymers based on aluminum phosphates: synthesis, crystal structure and morphology

“…The phosphate group is one of the essential components of a variety of biological macromolecules and synthetic materials. Considerable effort has been devoted to the development of synthetic analogues of nucleic acids, lipids and enzymes, as well as the mimicking of some processes that occur in living organisms, [1][2][3][4] for example, selective cation transport in liquid membrane systems 1,[5][6][7] and biomineralization. [8][9][10] Esters of phosphoric acid are often used as starting materials in the synthesis of coordination polymers formed by metal cations linked by organic ligands, molecular clusters, or hybrid inorganic-organic mesostructured lamellar systems.…”

Linear coordination polymers based on aluminum phosphates: synthesis, crystal structure and morphology

2.14 Liquid Membranes

Treatment of multi-ionic solutions by a hybrid membrane system. Separation, concentration and recovery of Zn2+ cations