Catalysts with sharp reaction interface for electrochemical CO2 reduction with enhanced selectivity

The invention claimed is: 1. An abrupt interface CO 2 electroreduction catalyst for converting CO 2 into a multi-carbon compound, comprising: a porous gas diffusion layer having a gas-contacting side configured for contacting a CO 2 gas and allowing passage of the CO 2 gas toward an opposed reaction interface side, the porous gas diffusion layer being composed of a hydrophobic material; and a catalytic layer disposed on and covering the reaction interface side of the porous gas diffusion layer and having an electrolyte-contacting side configured for contacting an aqueous electrolyte, the catalytic layer being: hydrophilic allowing penetration of the aqueous electrolyte therethrough to form a gas-liquid interface on an opposed reaction interface side of the catalyst layer; composed of one or more metals selected to convert the CO 2 into the multi-carbon compound at determined electroreduction conditions; and sufficiently thin to prevent diffusion limitations of the CO 2 in the aqueous electrolyte and provide selectivity for the multi-carbon compound, wherein the catalyst layer has a thickness in the range of 10 nm to 100 nm or has a thickness below 50 nm. 2. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the thickness of the catalyst layer is in the range of 10 nm to 100 nm. 3. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the thickness of the catalyst layer is below 50 nm. 4. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the catalyst layer is made of one or more metals comprising Cu, Ag, Au, Pd, Sn, Ni, Cr, and Zn and alloys thereof. 5. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the catalyst layer has Cu as the only metallic component. 6. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the catalyst layer is deposited on the porous gas diffusion layer by a physical vapor deposition technique. 7. The abrupt interface CO 2 electroreduction catalyst of claim 6 , wherein the catalyst layer is deposited on the porous gas diffusion layer by thermal evaporation or sputtering. 8. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the gas diffusion layer is composed of a hydrophobic porous carbon material. 9. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the gas diffusion layer is composed of at least one hydrophobic and current collection material. 10. The abrupt interface CO 2 electroreduction catalyst of claim 9 , wherein the gas diffusion layer has a pore size between 0.1 micrometer and 0.3 micrometer. 11. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the reaction interface side of the porous gas diffusion layer has a roughness between 1 micrometer and 3 micrometers. 12. The abrupt interface CO 2 electroreduction catalyst of claim 11 , wherein the roughness is between 1.8 micrometers and 2.2 micrometers. 13. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the catalytic layer and the gas diffusion layer are sized and configured to provide a thickness-to-roughness ratio between the thickness of the catalytic layer and the roughness of the gas diffusion layer that is between 1/500 and 1/10. 14. The abrupt interface CO 2 electroreduction catalyst of claim 1 , wherein the catalyst layer comprises catalyst nanoparticles having particle sizes in the range of 10 nm to 100 nm. 15. An abrupt interface CO 2 electroreduction catalyst for converting CO 2 into a multi-carbon compound, comprising: a porous gas diffusion layer having a gas-contacting side configured for contacting a CO 2 gas and allowing passage of the CO 2 gas toward an opposed reaction interface side, the porous gas diffusion layer being composed of a hydrophobic material; a catalytic layer disposed on and covering the reaction interface side of the porous gas diffusion layer and having an electrolyte-contacting side configured for contacting an aqueous electrolyte, the catalytic layer being; hydrophilic allowing penetration of the aqueous electrolyte therethrough to form a gas-liquid interface on an opposed reaction interface side of the catalyst layer; composed of one or more metals selected to convert the CO 2 into the multi-carbon compound at determined electroreduction conditions; sufficiently thin to prevent diffusion limitations of the CO 2 in the aqueous electrolyte and provide selectivity for the multi-carbon compound; and wherein the catalyst layer is deposited on the porous gas diffusion layer by a physical vapor deposition technique. 16. The abrupt interface CO 2 electroreduction catalyst of claim 15 , wherein the multi-carbon compound is ethylene and the catalytic layer is configured to provide the selectivity for the ethylene of at least 60%. 17. The abrupt interface CO 2 electroreduction catalyst of claim 15 , wherein the catalyst layer is deposited on the porous gas diffusion layer by thermal evaporation. 18. The abrupt interface CO 2 electroreduction catalyst of claim 15 , wherein the catalyst layer is deposited on the porous gas diffusion layer by sputtering. 19. An abrupt interface CO 2 electroreduction catalyst for converting CO 2 into a multi-carbon compound, comprising: a porous gas diffusion layer having a gas-contacting side configured for contacting a CO 2 gas and allowing passage of the CO 2 gas toward an opposed reaction interface side, the porous gas diffusion layer being composed of a hydrophobic material; a catalytic layer disposed on and covering the reaction interface side of the porous gas diffusion layer and having an electrolyte-contacting side configured for contacting an aqueous electrolyte, the catalytic layer being; hydrophilic allowing penetration of the aqueous electrolyte therethrough to form a gas-liquid interface on an opposed reaction interface side of the catalyst layer; composed of one or more metals selected to convert the CO 2 into the multi-carbon compound at determined electroreduction conditions; sufficiently thin to prevent diffusion limitations of the CO 2 in the aqueous electrolyte and provide selectivity for the multi-carbon compound; and wherein the gas diffusion layer has a pore size between 0.1 micrometer and 0.3 micrometer. 20. An abrupt interface CO 2 electroreduction catalyst for converting CO 2 into a multi-carbon compound, comprising: a porous gas diffusion layer having a gas-contacting side configured for contacting a CO 2 gas and allowing passage of the CO 2 gas toward an opposed reaction interface side, the porous gas diffusion layer being composed of a hydrophobic material; a catalytic layer disposed on and covering the reaction interface side of the porous gas diffusion layer and having an electrolyte-contacting side configured for contacting an aqueous electrolyte, the catalytic layer being: hydrophilic allowing penetration of the aqueous electrolyte therethrough to form a gas-liquid interface on an opposed reaction interface side of the catalyst layer; composed of one or more metals selected to convert the CO 2 into the multi-carbon compound at determined electroreduction conditions; sufficiently thin to prevent diffusion limitations of the CO 2 in the aqueous electrolyte and provide selectivity for the multi-carbon compound; and wherein the reaction interface side of the porous gas diffusion layer has a roughness between 1 micrometer and 3 micrometers.