Bi-doped Ceria with Increased Oxygen Vacancy for Enhanced CO2 Photoreduction Performance

Yaxin LIU; Min WANG; Meng SHEN; Qiang WANG; Lingxia ZHANG

doi:10.15541/jim20200142

[1] X CHANG, T WANG, J GONG. CO₂ photo-reduction: insights into CO₂ activation and reaction on surfaces of photocatalysts. Energy & Environmental Science, 9, 2177-2196(2016).

[2] P INDRAKANTI V, D KUBICKI J, H SCHOBERT H. Photoinduced activation of CO₂ on Ti-based heterogeneous catalysts: current state, chemical physics-based insights and outlook. Energy & Environmental Science, 2, 745-750(2009).

[3] Y QI, L SONG, S OUYANG et al. Photoinduced defect engineering: enhanced photothermal catalytic performance of 2D black In₂O_3-x nanosheets with bifunctional oxygen vacancies. Advanced Materials, 32, 1903915(2019).

[4] S LINIC, P CHRISTOPHER, B INGRAM D. Plasmonic-metal nanostructures for efficient conversion of solar to chemical energy. Nature Materials, 10, 911-921(2011).

[5] J LI, F SONG C, J PANG X. Controllable synthesis and photocatalytic performance of BiVO₄ under visible-light irradiation. Journal of Inorganic Materials, 34, 164-172(2019).

[6] Y SUN, H WANG, Q XING et al. The pivotal effects of oxygen vacancy on Bi₂MoO₆: promoted visible light photocatalytic activity and reaction mechanism. Chinese Journal of Catalysis, 40, 647-655(2019).

[7] M WANG, M SHEN, X JIN et al. Oxygen vacancy generation and stabilization in CeO_2-x by Cu introduction with improved CO₂ photocatalytic reduction activity. ACS Catalysis, 9, 4573-4581(2019).

[8] Y LIU, S YU, W ZHENG K et al. NO Photo-oxidation and in-situ DRIFTS studies on N-doped Bi₂O₂CO₃/CdSe quantum dot composite. Journal of Inorganic Materials, 34, 425-432(2019).

[9] D JIANG, W WANG, E GAO et al. Bismuth-induced integration of solar energy conversion with synergistic low-temperature catalysis in Ce_1-xBi_xO_2-δ nanorods. Journal of Physical Chemistry C, 117, 24242-24249(2013).

[10] S SHAMAILA, A K L SAJJAD, F CHEN et al. Study on highly visible light active Bi₂O₃ loaded ordered mesoporous titania. Applied Catalysis B Environmental, 94, 272-280(2010).

[11] H YANG G, K MIAO W, M YUAN Z et al. Bi quantum dots obtained via in situ photodeposition method as a new photocatalytic CO₂ reduction cocatalyst instead of noble metals: borrowing redox conversion between Bi₂O₃ and Bi. Applied Catalysis B Environmental, 237, 302-308(2018).

[12] Y GAO, R LI, S CHEN et al. Morphology-dependent interplay of reduction behaviors, oxygen vacancies and hydroxyl reactivity of CeO₂ nanocrystals. Physical Chemistry Chemical Physics, 17, 31862-31871(2015).

[13] D CHEN, D HE, J LU et al. Investigation of the role of surface lattice oxygen and bulk lattice oxygen migration of cerium-based oxygen carriers: XPS and designed H₂-TPR characterization. Applied Catalysis B Environmental, 218, 249-259(2017).

[14] H WEBER W, C HASS K, R MCBRIDE J. Raman study of CeO₂: second-order scattering, lattice dynamics, and particle-size effects. Physical Review B: Condensed Matter, 48, 178-185(1993).

[15] F LI Y, N SOHEILNIA, M GREINER et al. Pd@H_yWO_3-x nanowires efficiently catalyze the CO₂ heterogeneous reduction reaction with a pronounced light effect. ACS Applied Materials & Interfaces, 11, 5610-5615(2019).

[16] S ZHU, T LI, B CAI W et al. CO₂ Electrochemical reduction as probed through infrared spectroscopy. ACS Energy Letters, 4, 682-689(2019).

[17] D GAMARRA, M FERNANDEZ-GARCIA, C BELVER et al. Operando DRIFTS and XANES study of deactivating effect of CO₂ on a Ce_0.8Cu_0.2O₂. Journal of Physical Chemistry C, 114, 18576-18582(2010).

[18] Y WANG, J ZHAO, T WANG et al. CO₂ photoreduction with H₂O vapor on highly dispersed CeO₂/TiO₂ catalysts: surface species and their reactivity. Journal of Catalysis, 337, 293-302(2016).

[19] J LI, W ZHANG, M RAN et al. Synergistic integration of Bi metal and phosphate defects on hexagonal and monoclinic BiPO₄: enhanced photocatalysis and reaction mechanism. Applied Catalysis B Environmental, 243, 313-321(2019).

[20] X LI, W ZHANG, J LI et al. Transformation pathway and toxic intermediates inhibition of photocatalytic NO removal on designed Bi metal@defective Bi₂O₂SiO₃. Applied Catalysis B: Environmental, 241, 187-195(2019).

[21] S RINGE, C G MORALES-GUIO, L D CHEN et al. Double layer charging driven carbon dioxide adsorption limits the rate of electrochemical carbon dioxide reduction on gold. Nature Communications, 11, 33(2020).

[22] M DUNWELL, Q LU, M HEYES J et al. The central role of bicarbonate in the electrochemical reduction of carbon dioxide on gold. Journal of the American Chemical Society, 139, 3774-3783(2017).

[23] S ZHU, B JIANG, B CAI W et al. Direct observation on reaction intermediates and the role of bicarbonate anions in CO₂ Electrochemical reduction reaction on Cu surfaces. Journal of the American Chemical Society, 139, 15664-15667(2017).

[24] A WUTTIG, Y YOON, J RYU et al. Bicarbonate is not a general acid in Au-catalyzed CO₂ electroreduction. Journal of the American Chemical Society, 139, 17109-17113(2017).

[25] L YE, Y DENG, L WANG et al. Bismuth-based photocatalysts for solar photocatalytic carbon dioxide conversion. ChemSusChem, 12, 3671-3701(2019).

[26] J GRACIANI, K MUDIYANSELAGE, F XU et al. Highly active copper-ceria and copper-ceria-titania catalysts for methanol synthesis from CO₂. Science, 345, 546-550(2014).