SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4200129774> ?p ?o ?g. }

Showing items 1 to 100 of ±160 with 100 items per page.

W4200129774 endingPage "47" @default.
W4200129774 startingPage "32" @default.
W4200129774 abstract "Porous materials for gas storage and separations have had limited success in reaching working capacity goals because of fundamental limitations in how the gas is adsorbed within the microporous structures. Light-induced photoirradiation has distinct advantages over many other stimulus approaches, including being non-destructive, having high spatial and periodic resolution, and generating a more accurate and predictable response over the desired pressure range. The main strategies for light-induced switchable adsorption (LISA) are through the incorporation of photoresponsive molecules as guests (type 1), pendant groups (type 2), and backbones (type 3). Despite the relative infancy of the application of LISA to targeted gas storage and separations, preliminary research has shown promising advances, and we expect a diverse array of discoveries to be forthcoming in the next few years. Despite the long history of porous materials as adsorbates, fundamental limitations remain regarding the efficient capture and release of the gas molecules, with the working capacity of the material often overlooked. In microporous materials, the uptake is dominated by low-pressure adsorption, with much of this being at pressures below the minimum working threshold for many gas utilization processes. Thus, research has focused on several advances in porous materials, including photoresponsive organic units for light-induced switchable adsorption. This process utilizes light to trigger structural or electronic changes, alter the gas uptake, and change the working capacity. While a relatively recent development, there is a significant body of research regarding the use of light to control gas storage performance. Despite the long history of porous materials as adsorbates, fundamental limitations remain regarding the efficient capture and release of the gas molecules, with the working capacity of the material often overlooked. In microporous materials, the uptake is dominated by low-pressure adsorption, with much of this being at pressures below the minimum working threshold for many gas utilization processes. Thus, research has focused on several advances in porous materials, including photoresponsive organic units for light-induced switchable adsorption. This process utilizes light to trigger structural or electronic changes, alter the gas uptake, and change the working capacity. While a relatively recent development, there is a significant body of research regarding the use of light to control gas storage performance. two phenyl rings joined by two nitrogen atoms in an N–N double bond. The phenyl rings can also be functionalized with other functional groups. crystalline porous materials synthesized through covalent bonding of organic monomers, sometimes referred to as crystalline PPNs. electronic energy transfer from a ligand to a metal. a light-induced response that can result in switchable gas adsorption properties of a material. The reaction is often immediately reversible with the presence or absence of a photo trigger. a light-induced switchable catalytic state. crystalline porous materials comprising organic and inorganic components synthesized from ionic or coordination bonds. electronic energy transfer from a metal center to a ligand. also called MOPs; highly ordered porous materials maintaining their pore structures in solution. They are made from metal clusters and organic linkers like MOFs but are typically single pore units in size. thin films of porous materials constructed from polymers. These can have multiple phases or layers and can be made into composite materials with PCCs/MOPs, MOFs, or PPNs. also called POPs; non-crystalline porous materials synthesized from organic building blocks into a polymer matrix. two phenyl rings joined by two carbon atoms in a bridging C–C double bond. Also called the carbon analog of azobenzene." @default.
W4200129774 created "2021-12-31" @default.
W4200129774 creator A5000510762 @default.
W4200129774 creator A5015148498 @default.
W4200129774 creator A5020594354 @default.
W4200129774 creator A5023573296 @default.
W4200129774 creator A5063381985 @default.
W4200129774 date "2022-01-01" @default.
W4200129774 modified "2023-10-11" @default.
W4200129774 title "Light-induced switchable adsorption in azobenzene- and stilbene-based porous materials" @default.
W4200129774 cites W1847510314 @default.
W4200129774 cites W1964156475 @default.
W4200129774 cites W1964599718 @default.
W4200129774 cites W1996004329 @default.
W4200129774 cites W2001724436 @default.
W4200129774 cites W2004265232 @default.
W4200129774 cites W2009277649 @default.
W4200129774 cites W2010176012 @default.
W4200129774 cites W2011464571 @default.
W4200129774 cites W2020874610 @default.
W4200129774 cites W2027788760 @default.
W4200129774 cites W2031558116 @default.
W4200129774 cites W2034782728 @default.
W4200129774 cites W2049541689 @default.
W4200129774 cites W2050078897 @default.
W4200129774 cites W2058042244 @default.
W4200129774 cites W2094145140 @default.
W4200129774 cites W2099851263 @default.
W4200129774 cites W2120596235 @default.
W4200129774 cites W2131961830 @default.
W4200129774 cites W2138126703 @default.
W4200129774 cites W2141429466 @default.
W4200129774 cites W2156824383 @default.
W4200129774 cites W2169198664 @default.
W4200129774 cites W2267759310 @default.
W4200129774 cites W2268519466 @default.
W4200129774 cites W2304801951 @default.
W4200129774 cites W2318957155 @default.
W4200129774 cites W2325265950 @default.
W4200129774 cites W2328635673 @default.
W4200129774 cites W2330565354 @default.
W4200129774 cites W2333685671 @default.
W4200129774 cites W2414485309 @default.
W4200129774 cites W2462295742 @default.
W4200129774 cites W2473753148 @default.
W4200129774 cites W2492819455 @default.
W4200129774 cites W2503953373 @default.
W4200129774 cites W2547620857 @default.
W4200129774 cites W2555775636 @default.
W4200129774 cites W2562922011 @default.
W4200129774 cites W2566685601 @default.
W4200129774 cites W2572045154 @default.
W4200129774 cites W2594459458 @default.
W4200129774 cites W2598167162 @default.
W4200129774 cites W2604416598 @default.
W4200129774 cites W2608667462 @default.
W4200129774 cites W2642972369 @default.
W4200129774 cites W2725928156 @default.
W4200129774 cites W2755463012 @default.
W4200129774 cites W2763670838 @default.
W4200129774 cites W2765884406 @default.
W4200129774 cites W2772599650 @default.
W4200129774 cites W2780825361 @default.
W4200129774 cites W2793736652 @default.
W4200129774 cites W2800329184 @default.
W4200129774 cites W2864175154 @default.
W4200129774 cites W2884613252 @default.
W4200129774 cites W2884886715 @default.
W4200129774 cites W2885744802 @default.
W4200129774 cites W2885973333 @default.
W4200129774 cites W2889976681 @default.
W4200129774 cites W2905623109 @default.
W4200129774 cites W2908920516 @default.
W4200129774 cites W2925268164 @default.
W4200129774 cites W2936968448 @default.
W4200129774 cites W2937623993 @default.
W4200129774 cites W2944363863 @default.
W4200129774 cites W2958638597 @default.
W4200129774 cites W2965773817 @default.
W4200129774 cites W2972144010 @default.
W4200129774 cites W2975372932 @default.
W4200129774 cites W2979290397 @default.
W4200129774 cites W2979853869 @default.
W4200129774 cites W2981542837 @default.
W4200129774 cites W2990737414 @default.
W4200129774 cites W2994151882 @default.
W4200129774 cites W2995012224 @default.
W4200129774 cites W2995012518 @default.
W4200129774 cites W3002099271 @default.
W4200129774 cites W3012344908 @default.
W4200129774 cites W3014548446 @default.
W4200129774 cites W3016327953 @default.
W4200129774 cites W3020063010 @default.
W4200129774 cites W3038419485 @default.
W4200129774 cites W3081651812 @default.
W4200129774 cites W3089743169 @default.
W4200129774 cites W3127049286 @default.
W4200129774 cites W3153956949 @default.