CuO coatings on glass fibers: a hybrid material for CO2 adsorption and photocatalytic reduction to solar fuels

“…Avila-Lopez et al used the microwave hydrothermal method to prepare CuO coatings on three different GFs. They immersed GF in an aqueous solution of Cu(CH 3 COO) 2 ·H 2 O and microwave irradiated the solution at 80 °C for 1 h. CuO was deposited on the three different GFs, and the CuO coating showed different forms in the different GFs, namely, strips and spheres [ 80 ]. Sayaka and Aminian et al prepared a TiO 2 porous GF composite by infiltrating GF into a TiO 2 mixture using the traditional dip-coating method, and TiO 2 was dispersed on the GF surface in the form of anatase particles [ 81 , 82 , 83 ].…”

“…Under visible light-emitting-diode light, CO 2 could be converted to solar fuel (CH 3 OH and HCOH) ( Figure 21 G). As the carrier of CuO, the GF improved CO 2 capture and photocatalytic conversion to 11 times that of other materials [ 80 ]. Wei et al loaded novel BiOI/BiOBr/MoS 2 photocatalyst powder on GF to form the BiOI/BiOBr/MoS 2 –GF composite material, which was used for photocatalytic degradation of ammonia nitrogen wastewater.…”

Recent Progress in Modifications, Properties, and Practical Applications of Glass Fiber

“…Avila-Lopez et al used the microwave hydrothermal method to prepare CuO coatings on three different GFs. They immersed GF in an aqueous solution of Cu(CH 3 COO) 2 ·H 2 O and microwave irradiated the solution at 80 °C for 1 h. CuO was deposited on the three different GFs, and the CuO coating showed different forms in the different GFs, namely, strips and spheres [ 80 ]. Sayaka and Aminian et al prepared a TiO 2 porous GF composite by infiltrating GF into a TiO 2 mixture using the traditional dip-coating method, and TiO 2 was dispersed on the GF surface in the form of anatase particles [ 81 , 82 , 83 ].…”

“…Under visible light-emitting-diode light, CO 2 could be converted to solar fuel (CH 3 OH and HCOH) ( Figure 21 G). As the carrier of CuO, the GF improved CO 2 capture and photocatalytic conversion to 11 times that of other materials [ 80 ]. Wei et al loaded novel BiOI/BiOBr/MoS 2 photocatalyst powder on GF to form the BiOI/BiOBr/MoS 2 –GF composite material, which was used for photocatalytic degradation of ammonia nitrogen wastewater.…”

Recent Progress in Modifications, Properties, and Practical Applications of Glass Fiber

“…With a higher PEI/EP ratio of 10:1, PEI had more efficient contact with CO 2 , which has the maximum CO 2 adsorption capacity of 90 mg g −1 at 0.1 MPa and 30 °C. To obtain bifunctional material for capturing and photoconverting CO 2 molecules, A ́vila-Loṕez et al 93 coated copper oxide (CuO) on glass fibers through a facial microwave−hydrothermal method. The presence of CuO on the surfaces of glass fibers immensely favored the fixation of CO 2 , and the best efficiency for CO 2 capture was 3080 mg g −1 .…”

Review on Multidimensional Adsorbents for CO₂ Capture from Ambient Air: Recent Advances and Future Perspectives

“…[1,17,18] Cupric oxide (CuO) has the properties of its abundance, lower toxicity compared to Ni and Co species, low cost, and moderate enthalpy in CO 2 adsorption (ΔH = À 45.5 kJ mol À 1 ) which contributes to decrease of the regeneration temperature (energy) compared to amine and MgO; and supporting of CuO on the porous carrier also enhanced CO 2 adsorption capacity compared to the bare carrier. [1,[19][20][21] CuO x (and Cu 2 + ) species have been also supported on clay minerals, which have abundant resources, low cost, and high thermal stability, using various methods, such as ion exchange, decomposition-precipitation, precursor reduction, and impregnation methods. [22][23][24][25][26] Recently, organic polymers have been used to support metals on clay.…”

Polymer Template Synthesis of CuO_x/Clay Nanocomposites with Controllable CuO_x Formation