Preparation of porous biomass-derived hydrothermal carbon modified with terminal amino hyperbranched polymer for prominent Cr(VI) removal from water

“…3 Therefore, there is an urgent demand for the mitigation of CO 2 emissions, resulting in extensive efforts worldwide to develop novel and inexpensive strategies for CO 2 adsorption. 4 For this purpose, various porous solid-based adsorbents for CO 2 capture such as metal-organic frameworks (MOFs), 5 aminesilica, 6 zeolites, 7 porous polymers, 8 metal oxides, 9 aminecontaining materials, 10 and carbonaceous materials 7 have been developed with suboptimal CO 2 adsorption performance mainly originating from their low N-doped content. Nitrogen functional groups have been found to increase the electron donor properties of carbon by affecting its spin density, resulting in the enhanced isosteric heat of adsorption and chemisorption of adsorbents even at high temperatures.…”

“…For this purpose, various porous solid-based adsorbents for CO 2 capture such as metal-organic frameworks (MOFs), aminesilica, zeolites, porous polymers, metal oxides, amine-containing materials, and carbonaceous materials have been developed with suboptimal CO 2 adsorption performance mainly originating from their low N-doped content. Nitrogen functional groups have been found to increase the electron donor properties of carbon by affecting its spin density, resulting in the enhanced isosteric heat of adsorption and chemisorption of adsorbents even at high temperatures. , Therefore, recent efforts have been aimed at the modification of the porous framework of carbon with nitrogen by impregnating chemically synthesized nitrogen-containing precursors such as melamine and urea.…”

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

“…3 Therefore, there is an urgent demand for the mitigation of CO 2 emissions, resulting in extensive efforts worldwide to develop novel and inexpensive strategies for CO 2 adsorption. 4 For this purpose, various porous solid-based adsorbents for CO 2 capture such as metal-organic frameworks (MOFs), 5 aminesilica, 6 zeolites, 7 porous polymers, 8 metal oxides, 9 aminecontaining materials, 10 and carbonaceous materials 7 have been developed with suboptimal CO 2 adsorption performance mainly originating from their low N-doped content. Nitrogen functional groups have been found to increase the electron donor properties of carbon by affecting its spin density, resulting in the enhanced isosteric heat of adsorption and chemisorption of adsorbents even at high temperatures.…”

“…For this purpose, various porous solid-based adsorbents for CO 2 capture such as metal-organic frameworks (MOFs), aminesilica, zeolites, porous polymers, metal oxides, amine-containing materials, and carbonaceous materials have been developed with suboptimal CO 2 adsorption performance mainly originating from their low N-doped content. Nitrogen functional groups have been found to increase the electron donor properties of carbon by affecting its spin density, resulting in the enhanced isosteric heat of adsorption and chemisorption of adsorbents even at high temperatures. , Therefore, recent efforts have been aimed at the modification of the porous framework of carbon with nitrogen by impregnating chemically synthesized nitrogen-containing precursors such as melamine and urea.…”

Synergistic Effect of Nitrogen Doping and Ultra-Microporosity on the Performance of Biomass and Microalgae-Derived Activated Carbons for CO₂ Capture

“…The chemically modified adsorption materials mainly include biochar, 140 carbon nanotubes, 141 hydrogels, 142 graphene oxide (Fig. 13).…”

Resource utilization of electroplating wastewater: obstacles and solutions

“…Meanwhile, hyperbranched polymers (HBPs) have a unique physical structure and chemical characteristics, such as the nearly three-dimensional spherical molecular shape with a large number of reactive terminal groups, the absence of molecular chain entanglement, many branching points caused high chemical reactivity, and strong chemical resistance . These advantages make HBPs a good material for the applications as coatings, , biomedical materials, − adsorbents, − antimicrobial agents, , and adhesives. , Therefore, using the unique properties of HBPs in the modification of GE adhesives would provide the adhesive with better performance.…”

Novel Gelatin-based Eco-friendly Adhesive with a Hyperbranched Cross-linked Structure