Stable Engineered Trimetallic Oxide Scaffold as a Catalyst for Enhanced Solvent-Free Conversion of CO<sub>2</sub> into Value-Added Products

Prasad, Divya; Srinivasappa, Puneethkumar M.; Raju, Navya Anna; Samal, Akshaya K.; Jadhav, Arvind H.

doi:10.1021/acs.energyfuels.2c03513

Cited by 12 publications

(33 citation statements)

References 78 publications

(237 reference statements)

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“…As mentioned in Table , Comparing different metal ratios of trimetallic, bimetallic, and monometallic oxide catalysts for CO 2 fixation, the PTOF trimetallic catalyst achieved excellent results under optimized reaction conditions. Earlier reports well emphasized that the catalysts containing mixed metal oxide phases and related systems showed efficient potential for the catalytic activity . Wang et al reported that abundant multimixed metal oxide phases and their surface showed excellent catalytic activity than the bimetallic and monometallic oxide counterparts toward catalytic transformation .…”

Section: Resultsmentioning

confidence: 99%

“…Earlier reports well emphasized that the catalysts containing mixed metal oxide phases and related systems showed efficient potential for the catalytic activity. 29 Wang et al reported that abundant multimixed metal oxide phases and their surface showed excellent catalytic activity than the bimetallic and monometallic oxide counterparts toward catalytic transformation. 56 Remarkably, the mixed metal oxide catalytic systems will attain a more synergistic effect compared to the bimetallic and monometallic oxides under suitable reaction conditions.…”

Section: Catalytic Evaluation Of the Ptof Catalyst Inmentioning

confidence: 99%

“…This rapid combustion methodology benefits the formation of highly porous morphology, good crystalline phases with surface properties, and importantly excellent surface active sites on the materials. 28,29 The exhausted gases cool the as-combusted products and prevent the sintering effect during catalyst synthesis. 30 Herein, we demonstrated effective fixation of CO 2 into oxazolidinone using propylene oxide and aniline as substrates catalyzed by the efficient PTOF.…”

Section: Introductionmentioning

confidence: 99%

“…The molecular mixing of the fuel and oxidizer together upon combustion releases an enormous amount of gases such as CO, CO 2 , NO, H 2 , and N 2 . This rapid combustion methodology benefits the formation of highly porous morphology, good crystalline phases with surface properties, and importantly excellent surface active sites on the materials. , The exhausted gases cool the as-combusted products and prevent the sintering effect during catalyst synthesis …”

Section: Introductionmentioning

confidence: 99%

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Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO₂ into Oxazolidinone: An Experimental and Theoretical Approach

Srinivasappa

Prasad

Chaudhari

et al. 2023

ACS Appl. Mater. Interfaces

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The excess anthropogenic CO 2 depletion via the catalytic approach to produce valuable chemicals is an industrially challenging, demanding, and encouraging strategy for CO 2 fixation. Herein, we demonstrate a selective one-pot strategy for CO 2 fixation into "oxazolidinone" by employing stable porous trimetallic oxide foam (PTOF) as a new catalyst. The PTOF catalyst was synthesized by a solution combustion method using transition metals Cu, Co, and Ni and systematically characterized by X-ray diffraction (XRD), thermogravimetric analysis (TGA), field emission scanning electron microscopy (FE-SEM), high-resolution transmission electron microscopy (HR-TEM), N 2 sorption, temperature-programmed desorption (TPD), and X-ray photoelectron spectroscopy (XPS) analysis. Due to the distinctive synthesis method and unique combination of metal oxides and their percentage, the PTOF catalyst displayed highly interconnected porous channels along with uniformly distributed active sites on its surface. Well ahead, the PTOF catalyst was screened for the fixation of CO 2 into oxazolidinone. The screened and optimized reaction parameters revealed that the PTOF catalyst showed highly efficient and selective activity with 100% conversion of aniline along with 96% selectivity and yield toward the oxazolidinone product at mild and solvent-free reaction conditions. The superiority of the catalytic performance could be due to the presence of surface active sites and acid−base cooperative synergistic properties of the mixed metal oxides. A doubly synergistic plausible reaction mechanism was proposed for the oxazolidinone synthesis experimentally with the support of DFT calculations along with bond lengths, bond angles, and binding energies. In addition, stepwise intermediate formations with the free energy profile were also proposed. Also, the PTOF catalyst displayed good tolerance toward substituted aromatic amines and terminal epoxides for the fixation of CO 2 into oxazolidinones. Very interestingly, the PTOF catalyst could be significantly reused for up to 15 consecutive cycles with stable activity and retention in physicochemical properties.

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Section: Resultsmentioning

confidence: 99%

Section: Catalytic Evaluation Of the Ptof Catalyst Inmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO₂ into Oxazolidinone: An Experimental and Theoretical Approach

Srinivasappa

Prasad

Chaudhari

et al. 2023

ACS Appl. Mater. Interfaces

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“…In Figure 2 (30−32), images are observed of more aggregation of particles with the reduction of surface smoothness. Hence, the CC-MgO surface is observed to exhibit a higher particle aggregation with irregular nanoflake morphology, as shown in Figure 2 (32). From this in-depth discussion, it is observed that precipitating agents significantly played a very decisive role to obtain uniform 3D microsphere morphology of MgO materials.…”

Section: Fe-sem Analysismentioning

confidence: 78%

Base-Tailored Hierarchical MgO Microspheres as Efficient Catalysts for CO₂ Fixation into Oxazolidinone at Atmospheric Pressure

Srinivasappa,

Bawiskar,

Manjunath

et al. 2023

Energy Fuels

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Wide-range implementations are ongoing to utilize recombinant CO 2 for value-added chemical synthesis via various catalytic approaches. Among others, thermal catalysis is a highly compelling and decisive approach to depleting CO 2 in the atmosphere. This study describes a solvent-and cocatalyst-free CO 2 fixation reaction employed by efficient hierarchical magnesium oxide microspheres. A straightforward precipitation process assisted the synthesis of base MgO materials using different precipitating agents. Successfully designed material inherent properties were investigated by TGA, XRD, FE-SEM, N 2 sorption, NH 2 /CO 2 -TPD, TEM/HR-TEM, and XPS analyses. The SC-MgO material that showed essential features was tested as a promising catalyst for the oxazolidinone reaction. Interestingly, the SC-MgO catalyst attained outstanding catalytic activity with 100% conversion of aniline and 97% yield and selectivity of the oxazolidinone product under atmospheric pressure. To comprehend the catalytic activity of the SC-MgO catalyst, various reaction parameters such as the effect of catalyst dosage, time, temperature, and solvents were investigated in detail. Additionally, the SC-MgO catalyst showed excellent catalytic activity toward the desired substituted oxazolidinone derivatives under optimized reaction conditions. The SC-MgO significant catalytic activity was completely reliant on inherent properties such as microsphere morphology, high specific surface area, and Lewis acidic and Lewis basic sites. The tentative oxazolidinone reaction mechanism was evidently proposed with the help of characterization and experimental results. Remarkably, the SC-MgO catalyst showed excellent recyclability with a stable catalytic activity performance along with structural and physicochemical properties for up to 10 consecutive cycles. We successfully demonstrated the highly feasible CO 2 fixation process using recyclable MgO catalyst for the oxazolidinone synthesis.

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Efficient Selective Catalytic Fixation of CO₂ into Epoxide to Form Cyclic Carbonates Using Sodium Aluminate Engineered Gamma Alumina Catalyst

Dhanusha,

Srinivasappa,

Alla

et al. 2024

Applied Organom Chemis

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The anthropogenic carbon dioxide (CO2) fixation and various engineering strategies are gaining very significant attention because of the expansion of the net‐zero carbon environment in the atmosphere. Herein, we designed a sodium aluminate@γ‐alumina (NaAlO2@γ‐Al2O3) catalyst by a simple and facile precipitation and impregnation tactics. A series of different weight percentage NaAlO2@γ‐Al2O3 materials were successfully synthesized and well characterized by using advanced analytical and spectroscopic techniques such as TGA, XRD, FE‐SEM, TEM/HR‐TEM, FT‐IR, Raman, TPD, and XPS analysis. The NaAlO2@γ‐Al2O3 catalyst was employed as a competent catalyst for the CO2 fixation under atmospheric pressure reaction conditions. The catalytic activity results evidently revealed that the cycloaddition reaction successfully achieved 94% styrene oxide conversion and 93% selectivity, along with an 87% yield of the styrene carbonate at 120 °C for 6 h. Furthermore, we comprehensively examined the effect of different reaction parameters such as the effect of sodium aluminate amount, co‐catalyst amount, temperature, and time for CO2 fixation reaction. Additionally, different terminal and internal epoxides were tested under optimized reaction conditions and achieved moderate to excellent yield of the desired cyclic carbonate products. Interestingly, a plausible reaction mechanism was proposed for the styrene carbonate synthesis using NaAlO2@γ‐Al2O3 catalyst surface with the support of characterization and experimental results. Remarkably, the NaAlO2@γ‐Al2O3 catalyst could be easily recoverable and successfully recyclable up to six consecutive cycles without declining its initial catalytic activity along with stable structural and physicochemical properties.

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Stable Engineered Trimetallic Oxide Scaffold as a Catalyst for Enhanced Solvent-Free Conversion of CO₂ into Value-Added Products

Cited by 12 publications

References 78 publications

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO₂ into Oxazolidinone: An Experimental and Theoretical Approach

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO₂ into Oxazolidinone: An Experimental and Theoretical Approach

Base-Tailored Hierarchical MgO Microspheres as Efficient Catalysts for CO₂ Fixation into Oxazolidinone at Atmospheric Pressure

Efficient Selective Catalytic Fixation of CO₂ into Epoxide to Form Cyclic Carbonates Using Sodium Aluminate Engineered Gamma Alumina Catalyst

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Stable Engineered Trimetallic Oxide Scaffold as a Catalyst for Enhanced Solvent-Free Conversion of CO2 into Value-Added Products

Cited by 12 publications

References 78 publications

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO2 into Oxazolidinone: An Experimental and Theoretical Approach

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO2 into Oxazolidinone: An Experimental and Theoretical Approach

Base-Tailored Hierarchical MgO Microspheres as Efficient Catalysts for CO2 Fixation into Oxazolidinone at Atmospheric Pressure

Efficient Selective Catalytic Fixation of CO2 into Epoxide to Form Cyclic Carbonates Using Sodium Aluminate Engineered Gamma Alumina Catalyst

Contact Info

Product

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Stable Engineered Trimetallic Oxide Scaffold as a Catalyst for Enhanced Solvent-Free Conversion of CO₂ into Value-Added Products

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO₂ into Oxazolidinone: An Experimental and Theoretical Approach

Trimetallic Oxide Foam as an Efficient Catalyst for Fixation of CO₂ into Oxazolidinone: An Experimental and Theoretical Approach

Base-Tailored Hierarchical MgO Microspheres as Efficient Catalysts for CO₂ Fixation into Oxazolidinone at Atmospheric Pressure

Efficient Selective Catalytic Fixation of CO₂ into Epoxide to Form Cyclic Carbonates Using Sodium Aluminate Engineered Gamma Alumina Catalyst