Proton/Electron Donors Enhancing Electrocatalytic Activity of Supported Conjugated Microporous Polymers for CO₂Reduction

Abstract: Metal phthalocyanines (MePc) hold great promise in electrochemical reduction of CO 2 to value-added chemicals, whereas the catalytic activity of MePc-containing polymers often suffers from a limited molecular modulation strategy. Herein, we synthesize an ultrathin conjugated microporous polymer sheath around carbon nanotubes by an ionothermal copolymerization of CoPc and H 2 Pc via the Scholl reaction. Given the H 2 Pc-mediated regulation in the synthesis, Co II metal is well preserved in the form of single at… Show more

“…41 Guo and coworkers recently reported the phthalocyanines polymerized through solid ion thermal utilizing Scholl reaction (Figure 5A) with carbon nanotubes as the substrates, which could provide both CoN 4 sites and H 2 Pc sites for CO 2 RR. 42 As is shown in Figure 5B, in the phthalocyanine catalysts, CoN 4 could serve as the active sites to interact with CO 2 molecules while H 2 Pc sites could boost CO 2 RR as the donors of protons and electrons. As a result, the performance of phthalocyanines could reach the FE of 97% with a large current density of >200 mA cm -2 .…”

Multicomponent catalyst design for CO₂/N₂/NO_xelectroreduction

“…41 Guo and coworkers recently reported the phthalocyanines polymerized through solid ion thermal utilizing Scholl reaction (Figure 5A) with carbon nanotubes as the substrates, which could provide both CoN 4 sites and H 2 Pc sites for CO 2 RR. 42 As is shown in Figure 5B, in the phthalocyanine catalysts, CoN 4 could serve as the active sites to interact with CO 2 molecules while H 2 Pc sites could boost CO 2 RR as the donors of protons and electrons. As a result, the performance of phthalocyanines could reach the FE of 97% with a large current density of >200 mA cm -2 .…”

Multicomponent catalyst design for CO₂/N₂/NO_xelectroreduction

“…For example, the proton donor H 2 Pc can facilitate the selective CO 2 reduction to CO on a conjugated composite microporous CoPc/H 2 Pc polymer catalyst (Figure 8d ). [ 119 ] The measurement of kinetic isotope effect (KIE) indicated that the rate‐determining step was the proton transfer process, and the addition of the proton donor, H 2 Pc, decreased the KIE value from 4.0 to 1.77, signifying accelerated proton transfer. The proton donor H 2 Pc lowered the energy barrier of the reduction of *CO 2 to the *COOH intermediate and the further reduction of *COOH to *CO.…”

Advances in Biomimetic Photoelectrocatalytic Reduction of Carbon Dioxide

“…Many pioneering efforts have also demonstrated that atomically dispersed active sites anchored onto NC substrates can effectively enhance ORR performances, indicating a preferable application of NC substrates [38][39][40][41][42][43][44], for instance, isolated single-atom Fe anchored on N-doped porous carbon and Cu-Zn clusters on porous NC [45][46][47]. Furthermore, transition metal-nitrogen-carbon (TM-N-C)-based catalysts have attracted widespread interest for CO 2 RR electrocatalysis because their 3d electron orbitals endow metal-N x (x denotes N coordination number) sites with efficient intrinsic CO 2 RR activity [48][49][50]. Therefore, the rational design of bifunctional electrocatalysts containing dual-core active sites for both CO 2 RR and ORR has significant practical applications.…”

Bifunctional Nb-N-C atomic catalyst for aqueous Zn-air battery driving CO2 electrolysis