Pd/C‐catalyzed reduction of NaHCO<sub>3</sub> into formate with 2‐pyrrolidone under hydrothermal conditions

Zhu, Yanjie; Yang, Yang; Wang, Xiaoguang; Zhong, Heng; Jin, Fangming

doi:10.1002/ese3.317

Cited by 7 publications

(14 citation statements)

References 49 publications

(83 reference statements)

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“…Subsequently, the formed NO 2 – interacts with NH 4 + , which is hydrolyzed from the amino acid (path (a)), to obtain stable N 2 and H 2 O, while amino acid is converted to alcohols (in the case of l -alanine, it was converted to ethanol). In the meantime, the processes of NaHCO 3 hydrogenation take place over the surface of the catalyst, where *H is adsorbed on the reactive-metal Pd and *HCO 3 – is adsorbed on the support γ-Al 2 O 3 and then following the rule of the SN 2 -like mechanism, NaHCO 3 is reduced to formate. , The total reactions are summarized in eqs –. Subsequently, a thermodynamic assessment of the alanine reaction with NaHCO 3 was performed, as shown in eq .…”

Section: Resultsmentioning

confidence: 99%

“…In the meantime, the processes of NaHCO 3 hydrogenation take place over the surface of the catalyst, where *H is adsorbed on the reactive-metal Pd and *HCO 3 − is adsorbed on the support γ-Al 2 O 3 and then following the rule of the SN 2 -like mechanism, NaHCO 3 is reduced to formate. 9,39 The total reactions are summarized in eqs 3−5. Subsequently, a thermodynamic assessment of the alanine reaction with NaHCO 3 was performed, as shown in eq 6.…”

Section: Nhmentioning

confidence: 99%

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Hydrothermal Reduction of NaHCO₃ into Formate with Protein-Based Biomass over Pd/γ-Al₂O₃ Nanocatalysts

Zhu

Zhong

et al. 2021

ACS Sustainable Chem. Eng.

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CO2/HCO3 – reduction with a renewable reductant has a promising potential for tackling the CO2 problem, but achieving high efficiency is still a challenge. Herein, protein-based biomass as the renewable reductant is found to achieve efficient NaHCO3 reduction under hydrothermal conditions. With the Pd/γ-Al2O3 nanocatalyst, the efficiency of NaHCO3 reduction reached 49.0% with l-alanine (the model compound of protein) as the reductant, which was attributed to the superior hydrogen activation property of Pd and the enhanced adsorption of NaHCO3 on the Pd/γ-Al2O3 surface. Furthermore, the mechanism study revealed that the reductive −NH2 group in protein fulfilled NaHCO3 reduction, which was moderately oxidized to N2 (not NO2 – or NO3 –) as the ultimate product, indicating additional merits of amending the natural nitrogen cycle and eliminating the burden of disposing toxic nitrite/nitrate. The universality of the proposed strategy was also examined with the direct use of protein and protein-based biomass of microalgae as the reductant. With efficient NaHCO3 reduction being achieved, this strategy of NaHCO3 reduction by protein-based biomass could provide a novel and sustainable approach to CO2 conversion and also a potential method of amending the anthropogenic-imbalanced nitrogen cycle.

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Section: Resultsmentioning

confidence: 99%

Section: Nhmentioning

confidence: 99%

Hydrothermal Reduction of NaHCO₃ into Formate with Protein-Based Biomass over Pd/γ-Al₂O₃ Nanocatalysts

Zhu

Zhong

et al. 2021

ACS Sustainable Chem. Eng.

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“…69 By contrast, in the hydrothermal CO 2 reduction, metal catalysts including Cu, Pd/C, Pd 0.5 Cu 0.5 /C and Ni displayed relatively high stability, during which the fluctuation of formic acid yield is less than 5% after 3−5 times recovery for all the tested metals, as shown in Figure 11. More specifically, Cu and Pd/C maintained their activity F I G U R E 1 0 (A) Distribution of carbonaceous species in water solution at different pH 66 ; (B) effect of the starting pH on the formic acid production 25,30,32 ; (C) effect of the initial amount of HCO 3 − on the production of formic acid at 300°C and 2-h condition, 25,65 and the catalytic activity for bimetallic catalyst Pd 0.5 Cu 0.5 /C was still kept after for 5 times reused times at 180°C for even 16 h. 14 Additionally, scanning electron microscope (SEM) and XRD results showed the morphology and crystallinity of reused catalyst had no obvious change after the reaction, while only a slight content of aggregation of metal particles was observed by TEM characterization, further indicating the relative stability of catalyst for hydrothermal CO 2 reduction.…”

Section: Stability Of Catalysts Under Hydrothermal Conditionsmentioning

confidence: 99%

“…(A) Distribution of carbonaceous species in water solution at different pH 66 ; (B) effect of the starting pH on the formic acid production 25,30,32 ; (C) effect of the initial amount of HCO 3 − on the production of formic acid 15,62,65,67 …”

Section: Effects Of Reaction Variablesmentioning

confidence: 99%

CO₂ reduction into formic acid under hydrothermal conditions: A mini review

Liu

Zhong

Wang

et al. 2022

Energy Science & Engineering

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Converting CO2, a major component of greenhouse gas in the atmosphere, into value‐added fine chemicals is beneficial from environmental and economic aspects. Except for various methods for CO2 reduction such as thermal catalysis, photocatalysis, electrocatalysis and biological reduction, hydrothermal reduction of CO2 to organics is becoming a novel and promising strategy. The hydrogen formed in situ from high‐temperature water could avoid the serious issues of hydrogen storage and transportation. This paper summarizes the recent advances on CO2 conversion to formic acid with metal‐ and biomass‐based compounds under hydrothermal conditions mainly focusing on the role of high‐temperature water, autocatalysis mechanism of metal reductants, and interfacial catalysis mechanism of metal/metal oxides. The effects of several experimental variables including temperature, reaction time and pH of the solution on formic acid yield are systematically illustrated as well. Finally, future efforts for fundamental researches and industrial applications of hydrothermal CO2 reduction are discussed.

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“…Many methods such as catalytic hydrogenation, or electrochemical or photochemical reactions have been proposed for the direct conversion of CO 2 . However, photochemical and electrochemical reduction of CO 2 present a low efficiency, thereby limiting their application (Zhu et al, 2019). Although catalytic hydrogenation of CO 2 has arisen as a promising and feasible technique for CO 2 utilisation, it typically requires the addition of gas-phase hydrogen (Zhong et al, 2019a).…”

Section: Introductionmentioning

confidence: 99%

“Reverse combustion” of carbon dioxide in water: The influence of reaction conditions

et al. 2022

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The synthesis of value-added organic products from the hydrothermal conversion of CO2 and H2O has been demonstrated, revealing the impact that reaction conditions have on the product distribution and yield. CO2 has the potential to become a valuable feedstock for the chemicals sector, in part displacing fossil resources and improving the economics of carbon capture. Herein the conversion of CO2 with H2O, in the absence of gas-phase H2, to methanol and other products is shown to occur under sub-critical water conditions in the presence of iron as a reductant and catalyst: this process can be considered as a form of “reverse combustion”. The influence of reaction temperature between 200–350°C and CO2:O2 mole ratio from 9 to 119 (in addition to pure 100% CO2) have been investigated in the presence of Fe powder. The influence of reaction time has also been investigated, employing Fe3O4 as a catalyst. Product analysis is conducted by GC-MS and MS for liquid- and gas-phase products respectively, while SEM and XRD are employed to analyse morphological changes in the catalyst and TPO investigates any coke deposited during reaction. Methanol is the major product formed at all conditions investigated, with a maximum concentration of 8 mmol L−1 after 12 h of reaction, or after 4 h in the presence of oxygen. Acetone and ethanol are also formed, although in smaller quantities than methanol, with larger-chained species also present. An inverse relationship is observed between acetone and ethanol concentrations. Based on the analysis of the reaction data it is hypothesized that ethanol and acetone may be competitively produced in one reaction pathway, while methanol is produced in an independent, parallel, pathway. The observation of acetaldehyde in the gas-phase at all studied conditions suggests that acetone may be produced from the dehydrogenation of ethanol via an acetaldehyde intermediate; catalyzed by zero-valent iron sites. Morphological characterization indicates that the catalysts are stable under the reaction conditions. These studies facilitate the development of improved catalysts and processes for the hydrothermal conversion of CO2, allowing further development of this promising sustainable process.

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Pd/C‐catalyzed reduction of NaHCO₃ into formate with 2‐pyrrolidone under hydrothermal conditions

Cited by 7 publications

References 49 publications

Hydrothermal Reduction of NaHCO₃ into Formate with Protein-Based Biomass over Pd/γ-Al₂O₃ Nanocatalysts

Hydrothermal Reduction of NaHCO₃ into Formate with Protein-Based Biomass over Pd/γ-Al₂O₃ Nanocatalysts

CO₂ reduction into formic acid under hydrothermal conditions: A mini review

“Reverse combustion” of carbon dioxide in water: The influence of reaction conditions

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Pd/C‐catalyzed reduction of NaHCO3 into formate with 2‐pyrrolidone under hydrothermal conditions

Cited by 7 publications

References 49 publications

Hydrothermal Reduction of NaHCO3 into Formate with Protein-Based Biomass over Pd/γ-Al2O3 Nanocatalysts

Hydrothermal Reduction of NaHCO3 into Formate with Protein-Based Biomass over Pd/γ-Al2O3 Nanocatalysts

CO2 reduction into formic acid under hydrothermal conditions: A mini review

“Reverse combustion” of carbon dioxide in water: The influence of reaction conditions

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Product

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Pd/C‐catalyzed reduction of NaHCO₃ into formate with 2‐pyrrolidone under hydrothermal conditions

Hydrothermal Reduction of NaHCO₃ into Formate with Protein-Based Biomass over Pd/γ-Al₂O₃ Nanocatalysts

Hydrothermal Reduction of NaHCO₃ into Formate with Protein-Based Biomass over Pd/γ-Al₂O₃ Nanocatalysts

CO₂ reduction into formic acid under hydrothermal conditions: A mini review