1/28/2024 0 Comments Low viscosity liquids![]() ![]() Super Low Viscosity Pure Silicone Fluids.An in situ coupling strategy toward porous carbon liquid with permanent porosity. Porous liquids: A promising class of media for gas separation. Porous liquids for gas capture, separation, and conversion: Narrowing the knowing-doing gap. Practical considerations in the design and use of porous liquids. Porous liquids-The future is looking emptier. Type II porous ionic liquid based on metal-organic cages that enables l-tryptophan identification. A bifunctional zeolitic porous liquid with incompatible Lewis pairs for antagonistic cascade catalysis. ![]() A hybrid absorptionadsorption method to efficiently capture carbon. Post-synthetic modification of UiO-66-OH toward porous liquids for CO 2 capture. A universal approach to turn UiO-66 into type 1 porous liquids via post-synthetic modification with corona-canopy species for CO 2 capture. Transforming metal-organic frameworks into porous liquids via a covalent linkage strategy for CO 2 capture. Efficient separation of butane isomers via ZIF-8 slurry on laboratory-and pilot-scale. High-performance porous ionic liquids for low-pressure CO 2 capture. Shining light on porous liquids: From fundamentals to syntheses, applications and future challenges. A review of CO 2 capture by absorption and adsorption. A review of techno-economic models for the retrofitting of conventional pulverised-coal power plants for post-combustion capture (PCC) of CO 2. Ionic-liquid-based CO 2 capture systems: Structure, interaction and process. Water-lean solvents for post-combustion CO 2 capture: Fundamentals, uncertainties, opportunities, and outlook. Fine-tuning the pore environment of the microporous Cu-MOF for high propylene storage and efficient separation of light hydrocarbons. Optimizing multivariate metal-organic frameworks for efficient C 2H 2/CO 2 separation. Multivariate polycrystalline metal-organic framework membranes for CO 2/CH 4 separation. Guest-molecule-induced self-adaptive pore engineering facilitates purification of ethylene from ternary mixture. Flexible metal-organic frameworks for gas storage and separation. The chemistry of metal-organic frameworks for CO 2 capture, regeneration and conversion. CO 2 capture and separations using MOFs: Computational and experimental studies. Data-driven design of metal-organic frameworks for wet flue gas CO 2 capture. Cooperative carbon capture and steam regeneration with tetraamine-appended metal-organic frameworks. Carbon sequestration during core formation implied by complex carbon polymerization. The technological and economic prospects for CO 2 utilization and removal. The many possible climates from the Paris Agreement’s aim of 1.5 ☌ warming. Land-use emissions play a critical role in land-based mitigation for Paris climate targets. Paris Agreement climate proposals need a boost to keep warming well below 2 ☌. Importantly, it’s worth noting that the strategy based on the rule of “like dissolves like” sheds light on the preparation of other types of PLs for task-specific applications. Furthermore, the generality of the synthesis strategy is confirmed by the successful construction of PLs using two other amino-metal-organic frameworks (MOFs) (MIL-53(Al)-NH 2 and MIL-88B(Fe)-NH 2). Besides, the porosity of P-UiO-66-PLs and the CO 2 sorption mechanism are demonstrated by molecular simulation. The gas sorption-desorption test shows that P-UiO-66-PLs have an enormous potential for CO 2/N 2 selective separation. Then, P-UiO-66 is dispersed into different types and amounts of sterically hindered solvents (PDMS400 or PDMS6000), obtaining a series of type III PLs (denoted by P-UiO-66-PLs) with permanent cavities and low viscosities. ![]() Specifically, the monoglycidyl ether terminated polydimethylsiloxane (denoted by E-PDMS) is attached to the surface of Universitetet i Oslo (UiO)-66-NH 2 via covalent linkage, constructing the pore generator (UiO-66-NH 2-E-PDMS, denoted by P-UiO-66). Herein, we demonstrate a generalizable and simple strategy to prepare type III PLs with low viscosity based on the rule of “like dissolves like”. However, the current construction methods are complicated and resulting PLs possess high viscosity values, which cannot meet the requirements of practical industrial applications. Porous liquids (PLs), an emerging porous material with permanent cavities, have attracted extensive attention in recent years. ![]()
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