碱性位和缺陷对MgAL-LDHs催化芴与CO2直接羧基化反应的影响

Effects of basic sites and defects of MgAL-LDHs on direct carboxylation of fluorene with CO2

  • 摘要: 将CO2转化为高附加值的化学品,对于缓解CO2造成的环境污染和减少对化石能源的依赖至关重要。而以CO2为羧基源直接合成羧酸是其资源化利用的重要途径。为了实现CO2在温和条件下的高效转化,实验考察了无水K2CO3、K2CO3/LDHs、K2CO3+ LDHs/LDO等固体碱对CO2直接羧基化合成9-芴甲酸(9-FCA)的影响,结合XPS、XRD、CO2-TPD及FT-IR等探讨了其催化活性存在差异的原因。结果表明,仅使用K2CO3时,9-芴甲酸产率为64.61%。再生过程中K2CO3从γ-K2CO3相转变为低活性的β-K2CO3相,碱性位点减少,碱量降低,导致催化活性下降。负载K2CO3会影响LDHs碱性中心的数量和碱强度,Mg2Al-LDH-C-40%和Mg3Al-LDH-H-40%对应的9-芴甲酸产率分别为66.15%和44.45%。焙烧后Mg2Al-LDO-500尖晶石相(MgAl2O4)增加,羟基(–OH)减少、结晶度降低、中等强度碱性位点和氧空位(Ov)增加,添加量为K2CO3的7%时,9-芴甲酸的产率提升至78.36%。

     

    Abstract: Converting CO2 into high value-added chemicals is essential for mitigating environmental pollution caused by CO2 and reducing dependence on fossil fuels. One significant approach to resource utilization is the direct synthesis of carboxylic acids using CO2 as a carboxyl source. Utilizing fluorene as the raw material along with CO2 for the synthesis of 9-fluorenecarboxylic acid (9-FCA) provides a readily available feedstock while eliminating the need for toxic phosgene or carbon monoxide. Due to the thermodynamic stability and kinetic inertness of CO2, an appropriate catalytic system is crucial for ensuring that the reaction proceeds efficiently. Layered double hydroxides (LDHs) represent an important class of solid bases that facilitate the control of alkalinity by adjusting the composition and ratio of M2+ and M3+ elements within the LDH layers. Their catalytic performance is influenced by both the basic strength and the quantity of the active phase. Layered double oxides (LDOs), which are derived from LDHs after calcination, exhibit developed pore structures and abundant tunable surface basic sites, which are beneficial for the adsorption and activation of CO2. Exploring and understanding the effects of basic sites and defects on the direct carboxylation of fluorene with CO2 catalyzed by MgAL-LDHs is beneficial to the non-dissociation activation of CO2 and has certain reference significance for improving the yield of 9-FCA under mild conditions. To achieve efficient CO2 conversion under mild conditions, this study investigates the effects of solid bases such as anhydrous K2CO3, K2CO3/LDHs and K2CO3 + LDHs/LDO on the direct carboxylation of CO2 to synthesize 9-FCA. The variations in catalytic activity were analyzed using X-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), CO2 temperature-programmed desorption (CO2-TPD), and Fourier-transform infrared spectroscopy (FT-IR). Results indicate that during the recycling of K2CO3, weak alkaline sites gradually transform into medium-strength alkaline sites; however, the alkali content decreases, leading to reduced reaction activity. When the regeneration temperature exceeds 250 °C, the crystal structure transitions from high-activity γ-K2CO3 to low-activity β-K2CO3. After three cycles, the yield of 9-FCA declined from an initial 64.61% to 29.10%. Factors such as the preparation method, crystallinity, number of basic sites, and basic centers in MgAl-LDHs significantly affect catalytic performance, as evidenced by differences in 9-FCA yields. Notably, MgAl-LDHs synthesized via coprecipitation exhibit lower crystallinity but demonstrate superior catalytic effects compared to those produced through hydrothermal methods. Lower crystallinity corresponds to a higher number of medium-strength alkaline active centers, thereby enhancing catalytic reactivity. The cycle stability of the MgAl-LDHs catalyst is commendable, with no phase change observed. The presence of K2CO3 influences the number and strength of alkaline centers in LDHs, yielding 66.15% for Mg2Al-LDH-C-40% and 44.45% for Mg3Al-LDH-H-40%, respectively. The spinel phase (MgAl2O4) in Mg2Al-LDO-500 increases, while hydroxyl groups (−OH) and crystallinity decrease, resulting in an increase in intermediate strength alkaline sites and oxygen vacancies (Ov). Both crystallinity and pore volume of LDO decrease, while the strength and number of medium-strong alkaline sites increase. The presence of more medium-strong alkaline sites enhances the non-dissociative activation of CO2, significantly increasing the yield of 9-FCA. When 7% Mg2Al-LDO-500 is added, the yield of 9-FCA rises to 78.36%.

     

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