3D printed catalytic reactors for aerobic selective oxidation of benzyl alcohol into benzaldehyde in continuous multiphase flow

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“…18–20 In the latter respect, an interesting recent study has focused on the 3D-printing of bi-metallic (namely, Fe and Co) monoliths for the continuous-flow oxidation of benzyl alcohol. 21,22…”

Controlled alcohol oxidation reactions by supported non-noble metal nanoparticles on chitin-derived N-doped carbons

“…18–20 In the latter respect, an interesting recent study has focused on the 3D-printing of bi-metallic (namely, Fe and Co) monoliths for the continuous-flow oxidation of benzyl alcohol. 21,22…”

Controlled alcohol oxidation reactions by supported non-noble metal nanoparticles on chitin-derived N-doped carbons

“…These studies offer insights into the influence of the chemical and physical processes directing the performance of the catalytic reaction, including microchannels and concentration profiles inside the designed geometries. Remarkably, by using Fe and FePd supported on alumina and graphene oxide, respectively, 90% higher TOFs were reached as compared with batch counterparts (Figure 3C) [59].…”

“…(B) Illustrative representation of alkyne reduction using 3D-printed catalytic static mixer [53]. (C) 3D-printed microstructured reactors and modeling of the catalytic performance [59]. Figures adapted, with permission, from [50,53,59].…”

“…(C) 3D-printed microstructured reactors and modeling of the catalytic performance [59]. Figures adapted, with permission, from [50,53,59].…”

3D-printing design for continuous flow catalysis

“…First, to control macroscopic surface morphology, we employ three-dimensional printing (3D-printing). 3D-printing is a technology with significant potential in a wide range of emerging fields including engineering with conductive polymers, desalination, and solar evaporators [ 25 , 26 , 27 , 28 , 29 , 30 ]. Furthermore, 3D printing is an attractive approach as it allows surfaces to be printed with a high accuracy.…”

Inspired by the Nature: A Post-printed Strategy to Efficiently Elaborate Parahydrophobic Surfaces