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Multi-scale computer-aided design and photo-controlled macromolecular synthesis boosting uranium harvesting from seawater

Zeyu Liu, Youshi Lan, Jianfeng Jia, Yiyun Geng, Xiaobin Dai, Li‐Tang Yan, Tongyang Hu, Jing Chen, Krzysztof Matyjaszewski, Gang Ye

2022Nature Communications68 citationsDOIOpen Access PDF

Abstract

Abstract By integrating multi-scale computational simulation with photo-regulated macromolecular synthesis, this study presents a new paradigm for smart design while customizing polymeric adsorbents for uranium harvesting from seawater. A dissipative particle dynamics (DPD) approach, combined with a molecular dynamics (MD) study, is performed to simulate the conformational dynamics and adsorption process of a model uranium grabber, i.e., PAO m - b -PPEGMA n , suggesting that the maximum adsorption capacity with atomic economy can be achieved with a preferred block ratio of 0.18. The designed polymers are synthesized using the PET-RAFT polymerization in a microfluidic platform, exhibiting a record high adsorption capacity of uranium (11.4 ± 1.2 mg/g) in real seawater within 28 days. This study offers an integrated perspective to quantitatively assess adsorption phenomena of polymers, bridging metal-ligand interactions at the molecular level with their spatial conformations at the mesoscopic level. The established protocol is generally adaptable for target-oriented development of more advanced polymers for broadened applications.

Topics & Concepts

SeawaterUraniumMacromoleculeMolecular dynamicsAdsorptionComputer scienceDissipative particle dynamicsNanotechnologyBiological systemChemistryMaterials sciencePolymerComputational chemistryPhysical chemistryBiochemistryBiologyMetallurgyOrganic chemistryEcologyRadioactive element chemistry and processingChemical Synthesis and CharacterizationCovalent Organic Framework Applications
Multi-scale computer-aided design and photo-controlled macromolecular synthesis boosting uranium harvesting from seawater | Litcius