Light-responsive materials with high adsorp on capacity and sunlight-triggered regenerability are highly desired for low-cost and environmentally friendly industrial separa on processes. Here we report a poly(spiropyran acrylate) (PSP) func onalized metal-organic framework (MOF) as sunlight-regenerable ion adsorbent for sustainable water desalina on. Under dark condi ons, the zwi erionic isomer quickly adsorbs mul ple ca ons and anions from water within 30 minutes with high ion adsorp on loading up to 2.88 mmol•g −1 . With sunlight illumina on, the neutral isomer rapidly releases these adsorbed salts within 4 minutes. Single-column desalina on experiments show that PSP-MOF works efficiently for desalina ng saline water. A fresh water yield of 1 139.5 L•kg −1 •per day and a low energy consump on of 0.11 Wh•L −1 would be reached for desalina ng 2,233 ppm synthe c brackish water. Importantly, this adsorbent shows excellent stability and cycling performance. This work opens up a new direc on for designing responsive materials for energy-efficient and sustainable desalina on and water purifica on.Desalina on has been increasingly used to address the escala ng water shortage. Its popularity is due to the wide availability of brackish water and seawater, but even more because desalinated produc on is reliable, easily incorporated into the exis ng urban water supply systems, and has minimal health risks 1,2 . Thermal desalina on processes by evapora on, such as mul -stage flash (MSF) and mul ple effect dis lla on (MED), are widely used to produce fresh water. However, these thermal technologies are highly energy-intensive, e.g., 14-27 kWh•m −3 for MSF or MED, because a minimum latent heat of 2260 kJ•kg −1 is essen al for the vaporiza on of subcooled water 3,4 . An alterna ve approach is to take mineral ions out of salt waters using separa ng mediums, e.g., semipermeable membranes or adsorbents 2,5 . By membrane-based techniques, such as the dominant desalina on technology of reverse osmosis (RO), it consumes a much lower energy of 1.5-2.5 kWh•m −3 for trea ng brackish water, and 4-6 kWh•m −3 for seawater desalina on 4 .However, RO has some drawbacks such as rela vely high energy consump on, and chemical usage in membrane cleaning and dechlorina on 4,6 . Membrane dis lla on as another membrane process requires over 100 kWh•m -3 thermal energy, but it consumes around 1.0 kWh•m -3 of electricity if waste heat or renewable hea ng energy is u lized 7 . Electrochemical process, such as electrodialysis (ED) and capaci ve deioniza on (CDI), are also compe ve
