Amino-functionalized ionic liquid biphasic solvents present excellent absorption capacity, regeneration ability, and energy consumption savings, which make them a possible candidate for CO capture. The kinetics and regeneration heat duty of the [TETAH][Lys]-ethanol-water system capturing CO were investigated in this work. The mass transfer and kinetic parameters, including the overall reaction rate constant (k), the reaction rate constant (k), and the enhancement factor (E), were assessed at diverse concentrations and temperatures. At 303.15 K, the k of CO capture into the [TETAH][Lys]-ethanol-water solution was 58,907.30 m kmol s. The Arrhenius equation was introduced to evaluate the relations between k and the reaction temperature, which can be presented as [Formula: see text] The regeneration heat duty of the novel biphasic solvent was 35.5 and 62.39% lower than those of [TETAH][Lys]-water and the benchmark monoethanolamine solution, respectively. An efficient absorption performance and lower energy requirement indicate the great potential for this application.
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