Hydrogenation reactions catalyzed by colloidal palladium nanoparticles under flow regime

Abstract: A glycerol colloidal solution of palladium nanoparticles stabilized by PVP (PdPVP, mean diameter of 2.2 ± 0.8 × 10 −9 m) was employed under flow conditions for hydrogenation reactions. After optimization, we selected the tube-in-tube flow reactor as the more suitable system for this catalytic process due to its ability to regulate the addition of hydrogen. PdPVP nanoparticles were synthesized and fully characterized ((HR)-TEM, PXRD, EA, and ICP) both in glycerol solution and at solid state. The reduction of di… Show more

“…For the hydrogenation of alkene substrates, full conversion in 24 s was obtained for the indene hydrogenation, selectively reducing the conjugated C]C bond to the aromatic ring (entry 1), leading to a turnover frequency ca. three times higher than other conjugated substrates described in the literature [8]. However, for non-conjugated C]C bonds, such as 1-dodecene, lower conversion was achieved (26 % conversion after recycling 3 times (x12 s) or 36 s of residence time; entry 2) with a low chemoselectivity, mainly obtaining isomerization products (i.e.…”

“…Where V Cont is the volume of the contactor shell side (m 3 ) Q , l the volumetric flow rate of the liquid phase (m 3 ⋅s −1 ), L cont the lengh of the module (0.1 m), r Cont is the radius of the module (0.002 m), n fib the number of fibers (8), r e the external diameter of fibers (3.0⋅10 -4 m).…”

“…Furthermore, supported palladium catalysts have been largely studied and efficiently applied for synthesis of both fine [5] and bulk chemicals [6]. Especially, working under continuous flow conditions represents a sustainable tool in terms of safety, diminution of reaction time, process intensification and scale-up [7,8]. In this frame, polymeric catalytic membranes have proven to be outstanding tools for catalytic reactions in the fine chemical industry, generally working under mild conditions (< 150°C) [9][10][11][12].…”

Remarkable catalytic activity of polymeric membranes containing gel-trapped palladium nanoparticles for hydrogenation reactions

“…For the hydrogenation of alkene substrates, full conversion in 24 s was obtained for the indene hydrogenation, selectively reducing the conjugated C]C bond to the aromatic ring (entry 1), leading to a turnover frequency ca. three times higher than other conjugated substrates described in the literature [8]. However, for non-conjugated C]C bonds, such as 1-dodecene, lower conversion was achieved (26 % conversion after recycling 3 times (x12 s) or 36 s of residence time; entry 2) with a low chemoselectivity, mainly obtaining isomerization products (i.e.…”

“…Where V Cont is the volume of the contactor shell side (m 3 ) Q , l the volumetric flow rate of the liquid phase (m 3 ⋅s −1 ), L cont the lengh of the module (0.1 m), r Cont is the radius of the module (0.002 m), n fib the number of fibers (8), r e the external diameter of fibers (3.0⋅10 -4 m).…”

“…Furthermore, supported palladium catalysts have been largely studied and efficiently applied for synthesis of both fine [5] and bulk chemicals [6]. Especially, working under continuous flow conditions represents a sustainable tool in terms of safety, diminution of reaction time, process intensification and scale-up [7,8]. In this frame, polymeric catalytic membranes have proven to be outstanding tools for catalytic reactions in the fine chemical industry, generally working under mild conditions (< 150°C) [9][10][11][12].…”

Remarkable catalytic activity of polymeric membranes containing gel-trapped palladium nanoparticles for hydrogenation reactions

“…Gómez and co-workers have vast experience in the synthesis and catalytic applications of metal nanoparticles in glycerol, where the solvent plays a key role as liquid support, enabling an efficient immobilization of metal-based NPs and easy recycling of the catalytic phase [ 110 , 111 , 112 , 113 , 114 , 115 ]. Therefore, PdNPs stabilized by cinchona-based alkaloids were prepared for the tandem synthesis of functionalized amines via reductive amination of aldehydes [ 114 ].…”

Palladium and Copper: Advantageous Nanocatalysts for Multi-Step Transformations

“…In 2019, Gómez and co‐workers studied the hydrogenation of nitrobenzene ( 6 ) in flow . In this reaction, three different stabilizers for the Pd catalyst were used, showing different activities (Scheme ).…”

Recent Progress in Continuous‐Flow Hydrogenation