Abstract
Although solar steam generation strategy is efficient in desalinating seawater, it is still challenging to achieve continuous solar-thermal desalination of seawater and catalytic degradation of organic pollutants. Herein, dynamic regulations of hydrogen bonding networks and solvation structures are realized by designing an asymmetric bilayer membrane consisting of a bacterial cellulose/carbon nanotube/Co(2)(OH)(2)CO(3) nanorod top layer and a bacterial cellulose/Co(2)(OH)(2)CO(3) nanorod (BCH) bottom layer. Crucially, the hydrogen bonding networks inside the membrane can be tuned by the rich surface -OH groups of the bacterial cellulose and Co(2)(OH)(2)CO(3) as well as the ions and radicals in situ generated during the catalysis process. Moreover, both SO(4)(2-) and HSO(5)(-) can regulate the solvation structure of Na(+) and be adsorbed more preferentially on the evaporation surface than Cl(-), thus hindering the de-solvation of the solvated Na(+) and subsequent nucleation/growth of NaCl. Furthermore, the heat generated by the solar-thermal energy conversion can accelerate the reaction kinetics and enhance the catalytic degradation efficiency. This work provides a flow-bed water purification system with an asymmetric solar-thermal and catalytic membrane for synergistic solar thermal desalination of seawater/brine and catalytic degradation of organic pollutants.