Copper-based catalysts are widely explored in electrochemical
CO2 reduction (CO2RR) because of their ability
to
convert CO2 into high-value-added multicarbon products.
However, the poor stability and low selectivity limit the practical
applications of these catalysts. Here, we proposed a simple and efficient
asymmetric low-frequency pulsed strategy (ALPS) to significantly enhance
the stability and the selectivity of the Cu-dimethylpyrazole complex
Cu3(DMPz)3 catalyst in CO2RR. Under
traditional potentiostatic conditions, Cu3(DMPz)3 exhibited poor CO2RR performance with the Faradaic efficiency
(FE) of 34.5% for C2H4 and FE of 5.9% for CH4 as well as the low stability for less than 1 h. We optimized
two distinguished ALPS methods toward CH4 and C2H4, correspondingly. The high selectivities of catalytic
product CH4 (FECH4 = 80.3% and above 76.6% within
24 h) and C2H4 (FEC2H4 = 70.7% and
above 66.8% within 24 h) can be obtained, respectively. The ultralong
stability for 300 h (FECH4 > 60%) and 145 h (FEC2H4 > 50%) was also recorded with the ALPS method. Microscopy
(HRTEM,
SAED, and HAADF) measurements revealed that the ALPS method in situ generated and stabilized extremely dispersive and
active Cu-based clusters (∼2.7 nm) from Cu3(DMPz)3. Meanwhile, ex situ spectroscopies (XPS,
AES, and XANES) and in situ XANES indicated that
this ALPS method modulated the Cu oxidation states, such as Cu(0 and
I) with C2H4 selectivity and Cu(I and II) with
CH4 selectivity. The mechanism under the ALPS methods was
explored by in situ ATR-FTIR, in situ Raman, and DFT computation. The ALPS methods provide a new opportunity
to boost the selectivity and stability of CO2RR.
Zirconium (Zr)-based porphyrinic metal-organic framework (PCN-223-M) were employed as the electrocatalysts to explore the effect of uncoordinated Zr sites on the performance of CO2 reduction reaction (CO2RR). PCN-223-AA with the...
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