Effect of TiO2 support on immobilization of cobalt porphyrin for electrochemical CO2 reduction

doi:10.1016/j.jmst.2020.09.053

Abstract

Abstract:

Electrochemical reduction of CO₂ is a promising strategy to manage the global carbon balance by transforming CO₂ into chemicals. The efficiency of CO₂ electroreduction is largely dependent on the design of hybrid electrode where both support and catalyst govern the performance of the electrolyzer. In this work, TiO₂ calcined at different temperatures, was used as a support for immobilization of cobalt tetraphenyl porphyrin (CoTPP) and its effect on CO₂ reduction was studied. It is demonstrated that the crystalline phase of TiO₂ and doping of TiO₂ apparently affecting CO₂ electroreduction. It is found that anatase phase exhibits higher activity and selectivity compared to rutile due to the enhanced conductivity which in turn enables faster electron transfer between the support and CoTPP. As for dopants, the carbon doping in anatase TiO₂ is proven to further enhance its conductivity, consequently resulting in the enhanced performance. This study implies that the rational design of supports is important for the performance of the hybrid electrode towards electrochemical CO₂ reduction.

Key words: CO₂ electroreduction, Cobalt porphyrin, Immobilization, TiO₂ support, Carbon doping

Shengshen Gu, Aleksei N. Marianov, Haimei Xu, Yijiao Jiang. Effect of TiO₂ support on immobilization of cobalt porphyrin for electrochemical CO₂ reduction[J]. J. Mater. Sci. Technol., 2021, 80: 20-27.

Figures/Tables 8

Fig. 1. (a) XRD of 200, 400, 600 and 800TiO2 (b) TGA-MS of C-TiO2 (c) TGA-MS of CF-TiO2. TGA-MS conditions: 40 °C to 700 °C with a ramp rate at 10 ℃/min, Ar as carrier gas, sample weight of 20 mg.

Fig. 2. TGA-MS of 200TiO2 (a) and 400TiO2 (b). Conditions: 40 °C to 700 °C with a ramp rate at 10 °C/min, Ar as carrier gas, sample weight of 20 mg.

Fig. 3. (a) XPS survey spectrum and (b) C 1s XPS spectrum of 200TiO2; (c) Ti 2p XPS spectra and (d) O 1s XPS spectra of 200TiO2, C-TiO2 and CF-TiO2.

Fig. 4. CV of (a) CoTPP/200TiO2 under CO2 or N2; (b) CoTPP/TiO2 calcined at different temperatures under CO2. Conditions: 0.5 M KHCO3 as electrolyte and 100 mV/s scan rate.

Fig. 5. (a) Total yield of CO (b) FE of CO (c) current densities over 4 h electrochemical CO2 reduction at -1.30 V with different TiO2 as supports; (d) total yield of CO at different overpotentials over 30 min electrochemical CO2 reduction.

Table 1 Comparison with the related work on CO2 electrochemical reduction.

Entry	Catalyst	V vs NHE	Electrolyte	FEco (%)	TOF	Ref.
1	CoTPP/200TiO₂	-1.095	0.5 M KHCO₃	23.5	0.0336/s	This work
2	40 wt% Ag/TiO2	-1.3	1 M KOH	90	N/A	[42]
3	[Mnbpy(COOH)₂]/ TiO₂	-0.91	CH₃CN (0.1 M Bu₄NPF₆)	N/A	0.0017/s	[30]
4	MnP/ TiO₂	-0.95	CH₃CN/H₂O (0.1 M Bu₄NBF₄)	67	0.016/s	[29]
5	Ru_CP²⁺/TiO₂	-1.03	CH₃CN (0.1 M nBu₄PF₆)	67	0.0165/s	[43]
6	10% Cu/TNT	-2.50	0.5 M NaHCO₃	10	N/A	[44]
7	CoTPP/TNT	-1.10	0.5 M KHCO₃	41.5	0.0144/s	[45]
^a1.11/s	CoTPP/TNT	-1.10	0.5 M KHCO₃	41.5		[45]

Fig. 6. EIS spectra of TiO2 coated FTO glass at open circuit voltage (a) in dark (b) in light. The equivalent circuit model is displayed in the inset of (a).

Fig. 7. Tafel plot of electrochemical CO2 reduction with 200TiO2, C-TiO2 and CF-TiO2 as the supports.

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Effect of TiO₂ support on immobilization of cobalt porphyrin for electrochemical CO₂ reduction

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