Catalytic hydrogenation performance of ZIF-8 carbide for electrochemical reduction of carbon dioxide

“…The Faraday efficiency increased from 29.1% to 41.8%, from 15.9% to 27.1%, respectively, for HCOOH and CO at −1.14 V vs. RHE. On the other side, the reaction onset potential decreased from −0.74 V to −0.54 V vs. RHE [272] . The high electrochemical performance of Sn-ZIF-8-800-20% is due to the electroactive sites e.g., pyridinic nitrogen.…”

“…It exhibited the highest selectivity toward the formation of HCOOH. N-doping carbonized ZIF-8 at 800 o C was used to support the earth-rich Sn catalyst (denoted as Sn-ZIF-8-800-20%) [272] . It improved the electron transfer and CO2 adsorption capacity of Sn.…”

“…Hydrogenation of CO2 can be used to synthesize valuable compounds; 1) hydrocarbons, such as methane (CH4, the reaction can be called methanation) [267,271] , olefins, and gasoline, or 2) other compounds, such as formic acid (HCOOH), alcohol (e.g., methanol), and carbon monoxide (CO) [10,[261][262][263][264][265][266][267][268][269][270] . Hydrogenation can be promoted via electrochemical [272] , thermo-catalysis [273] , and photo/thermal [274] methods. ZIFs materials are promising catalysts in terms of efficiency and selectivity among several catalysts.…”

A Review on Removal of Carbon Dioxide (CO2) using Zeolitic Imidazolate Frameworks: Adsorption and Conversion via Catalysis

“…The Faraday efficiency increased from 29.1% to 41.8%, from 15.9% to 27.1%, respectively, for HCOOH and CO at −1.14 V vs. RHE. On the other side, the reaction onset potential decreased from −0.74 V to −0.54 V vs. RHE [272] . The high electrochemical performance of Sn-ZIF-8-800-20% is due to the electroactive sites e.g., pyridinic nitrogen.…”

“…It exhibited the highest selectivity toward the formation of HCOOH. N-doping carbonized ZIF-8 at 800 o C was used to support the earth-rich Sn catalyst (denoted as Sn-ZIF-8-800-20%) [272] . It improved the electron transfer and CO2 adsorption capacity of Sn.…”

“…Hydrogenation of CO2 can be used to synthesize valuable compounds; 1) hydrocarbons, such as methane (CH4, the reaction can be called methanation) [267,271] , olefins, and gasoline, or 2) other compounds, such as formic acid (HCOOH), alcohol (e.g., methanol), and carbon monoxide (CO) [10,[261][262][263][264][265][266][267][268][269][270] . Hydrogenation can be promoted via electrochemical [272] , thermo-catalysis [273] , and photo/thermal [274] methods. ZIFs materials are promising catalysts in terms of efficiency and selectivity among several catalysts.…”

A Review on Removal of Carbon Dioxide (CO2) using Zeolitic Imidazolate Frameworks: Adsorption and Conversion via Catalysis

“…N‐doping carbonized ZIF‐8 at 800°C was used to support the earth‐rich Sn catalyst (denoted as Sn‐ZIF‐8‐800‐20%). [ 275 ] It improved the electron transfer and CO 2 adsorption capacity of Sn. Sn‐ZIF‐8‐800‐20% showed the highest reaction rate and Faraday efficiency of HCOOH and CO's hydrogenation product.…”

“…Hydrogenation of CO 2 can be used to synthesize valuable compounds: (1) hydrocarbons, such as methane (CH 4 , the reaction can be called methanation), [270,274] olefins, and gasoline, or (2) other compounds, such as formic acid (HCOOH), alcohol (e.g., methanol), and carbon monoxide (CO). [10,[264][265][266][267][268][269][270][271][272][273] Hydrogenation can be promoted via electrochemical, [275] thermo-catalysis, [276] and photo/thermal [277] methods. ZIF materials are promising catalysts in terms of efficiency and selectivity among several catalysts.…”

Removal of carbon dioxide using zeolitic imidazolate frameworks: Adsorption and conversion via catalysis

Applications of zeolitic imidazolate frameworks and their derivates in electrochemical reduction of CO2