Desenvolvimento de catalisadores a base de cobre modificados com monoetanolamina para aplicação na redução de CO2
Abstract
The photo and electrochemical conversion of CO2 into higher-value products, such as fuels and
chemical precursors, emerges as a promising solution to mitigate carbon emissions and meet
the growing global energy demand. However, the viability of these technologies hinges on
developing efficient, stable, and cost-effective catalysts. In this work, modified Cu-based
catalysts were evaluated for their potential application in the photo and electroreduction of CO2.
Aiming to enhance selectivity, reagent availability on the surface, and reduce the reaction
overpotential, the studied catalysts were functionalized with nitrogen groups derived from
monoethanolamine (MEA), which act as CO2 adducts. The syntheses were conducted by
solvothermal reaction and chemical precipitation, both simple techniques involving a single
reaction step to obtain the final material. These materials were characterized by various
analytical techniques and further applied in CO2 reduction processes. The catalysts synthesized
by the solvothermal reaction exhibited compositional variations with copper fractions in
different oxidation states, depending on the concentration of added MEA. These catalysts were
then assessed for their applicability in the photochemical reduction of CO2, achieving methanol
production rates of 1097 µmol g-1h-1, with selectivity greater than 85%. The samples
synthesized by chemical precipitation resulted in forming CuO catalysts with different
morphologies and crystallite sizes depending on the alkaline agent utilized in the synthesis. The
catalyst synthesized with MEA exhibited superior performance in the photoreduction of CO2
compared to catalysts synthesized with other bases (NaOH, KOH, NH4OH), with a methane
production rate of 57.2 µmol g-1 h-1. The enhanced activity was attributed to the
functionalization of the surface with nitrogen groups. In the electroreduction of CO2, the use of
the MEA-functionalized catalyst resulted in current densities of approximately 155 mA cm-2
and stability exceeding 100 hours in long-term tests. The results of this work indicate that
functionalization with MEA increases the efficiency of copper-based catalysts in CO2
reduction, both in photochemical and electrochemical processes.
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