Graphene Oxide (GO) Supported Palladium (Pd) Nanocomposites for Enhanced Hydrogenation

Rout, Dibya Ranjan; Senapati, Pragyan; Sutar, Harekrushna; Sau, D C; Murmu, Rabiranjan

doi:10.4236/graphene.2019.83003

Cited by 30 publications

(7 citation statements)

References 46 publications

(40 reference statements)

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“…Palladium oxide, PdO, has already been shown to be effective for catalyzing the combustion of organic compounds, , the dimerization of methane, and the methanation of CO 2 . However, to our knowledge, PdO has never explicitly been used for catalytic hydrogenation, despite the widespread use of oxide-supported Pd. − Our results show a clear enhancement of the ethylene hydrogenation activity in the presence of O 2 , even for the pure Pd catalyst. Thus, the results of this work show the potential of using O 2 to modify and activate Pd for catalytic processes involving hydrogenation reactions.…”

Section: Discussionmentioning

confidence: 61%

Activation by O₂ of Ag_xPd_1–x Alloy Catalysts for Ethylene Hydrogenation

Golio,

Gellman

2023

ACS Catal.

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A composition spread alloy film (CSAF) spanning all of Ag x Pd 1−x composition space, x Pd = 0 → 1, was used to study catalytic ethylene hydrogenation with and without the presence of O 2 in the feed gas. High-throughput measurements of the ethylene hydrogenation activity of Ag x Pd 1−x alloys were performed at 100 Pd compositions spanning x Pd = 0 → 1. The extent of ethylene hydrogenation was measured versus x Pd at reaction temperatures spanning T = 300 → 405 K and inlet hydrogen partial pressures spanning P H2 in = 70 → 690 Torr. The inlet ethylene partial pressure was constant at P C2H4 in = 25 Torr, and the O 2 inlet partial pressure was either P O2 in = 0 or 15 Torr. When P O2 in = 0 Torr, only those alloys with x Pd ≥ 0.90 displayed observable ethylene hydrogenation activity. As expected, the most active catalyst was pure Pd, which yielded a maximum conversion of ∼0.4 at T = 405 K and P H2 in = 690 Torr. Adding a constant O 2 partial pressure of P O2 in = 15 Torr to the feed stream dramatically increased the catalytic activity across the CSAF at all experimental conditions and catalyst compositions without inducing catalytic ethylene combustion and without measurable O 2 consumption. The presence of P O2 in = 15 Torr more than doubled the maximum achievable conversion on Pd to ∼0.9 and activated alloys with as little as x Pd = 0.6 for ethylene hydrogenation. Measurement of the reaction order with respect to hydrogen, n H2 , showed that n H2 ≈ 0 when P O2 in = 15 Torr on high x Pd alloys but that n H2 increases to values between 0.5 and 1 as x Pd decreases or when P O2 in = 0 Torr. We attribute this P O2 in -induced change in n H2 to a change in the reaction mechanism resulting from different functional catalyst surfaces: one that is O 2 -activated and Pd-rich and one that is Ag-capped with low activity. Both are extremely sensitive to the bulk alloy composition, x Pd , and the reaction temperature, T. These results show that the activity of AgPd catalysts for ethylene hydrogenation depends strongly on the operational conditions. Furthermore, we demonstrate that the exposure of AgPd catalysts to 15 Torr of O 2 at moderate temperatures leads to enhanced catalyst performance, presumably by stimulating both Pd segregation to the topmost surface and Pd activation for ethylene hydrogenation.

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Section: Discussionmentioning

confidence: 61%

Activation by O₂ of Ag_xPd_1–x Alloy Catalysts for Ethylene Hydrogenation

Golio,

Gellman

2023

ACS Catal.

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“…16 On the other hand, the hydrophobic nature of the nanocomposites can alter the wettability of the rock surface toward the water-wet and reduce the capillary forces. 17 Recently, several nanocomposites were evaluated for their potential role in enhancing oil recovery applications, such as Fe 3 O 4 /mineral−soil NCs, 13 polymer nanofibers, 18 polyacrylamide-grafted silica NCs, 19 Fe 3 O 4 @ Chitosan NCs, 20 GO/Pd NCs, 21 TiO 2 /xanthan gum NCs, 23 and nanobentonite. 23 The mentioned studies stated the significant role of the nanomaterials in the interfacial tension (IFT) reduction, wettability alteration, foam stability, and improvement of the oil recovery.…”

Section: Introductionmentioning

confidence: 99%

Performance Evaluation of the Green Surfactant-Treated Nanofluid in Enhanced Oil Recovery: Dill-Hop Extracts and SiO₂/Bentonite Nanocomposites

Manshad,

Mobaraki,

Ali

et al. 2024

Energy Fuels

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This study focuses on developing a surfactant-treated nanofluid (nanosurfactant), a green and sustainable solution, for improving oil recovery from carbonate reservoirs. The natural surfactants used in this study were derived from dill and hop plants, and SiO2/bentonite nanocomposites (NCs) were greenly synthesized from Commelina diffusa leaves. Different enhanced oil recovery (EOR) solutions, including dill and hop surfactants, nanofluids, and nanosurfactants, were prepared at different concentrations and subjected to several experimental tests for performance evaluation and characteristic analyses. The obtained results show that the critical micelle concentrations of the dill and hop surfactants were 4000 and 2000 ppm, respectively, depending on the conductivity and interfacial tension (IFT). A minimum IFT and contact angle of 1.73 mN/m and 38.5–40° were obtained under the effect of dill surfactant with 10,000 ppm NaCL and nanosurfactants at 500 ppm NCs, respectively. In addition, the dill-nanofluid solution prepared from mixing 500 ppm of NCs within 4000 ppm of dill extract enabled extraction of an additional 14.1% original oil in place from the carbonate core plug that has a porosity of 26.47% and permeability of 2.94 mD. These improvements in the EOR parameters confirm the stability and efficiency of the formulated green solution as an active EOR solution that can extract a high amount of crude oil in an ecofriendly sustainable way.

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“…9 Pd@GO has been used in various other studies, such as gas detection, electrocatalysis, hydrogenation, oxidation, and reduction reactions etc . 10–14 Various coupling reactions are also reported, such as Ullmann, Heck, Sonogashira, and Suzuki-Miyaura coupling reactions, etc . 15–18 However, heterogeneous catalysis for C–H functionalization is currently being explored.…”

Section: Introductionmentioning

confidence: 99%

Pd@GO catalyzed stereo- and regio-selective addition of arenes to alkynes and synthesis of coumarins via C–H functionalization

Kyndiah,

Sarkar,

Gajurel

et al. 2023

Org. Biomol. Chem.

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Graphene Oxide (GO) Supported Palladium (Pd) Nanocomposites for Enhanced Hydrogenation

Cited by 30 publications

References 46 publications

Activation by O₂ of Ag_xPd_1–x Alloy Catalysts for Ethylene Hydrogenation

Activation by O₂ of Ag_xPd_1–x Alloy Catalysts for Ethylene Hydrogenation

Performance Evaluation of the Green Surfactant-Treated Nanofluid in Enhanced Oil Recovery: Dill-Hop Extracts and SiO₂/Bentonite Nanocomposites

Pd@GO catalyzed stereo- and regio-selective addition of arenes to alkynes and synthesis of coumarins via C–H functionalization

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Graphene Oxide (GO) Supported Palladium (Pd) Nanocomposites for Enhanced Hydrogenation

Cited by 30 publications

References 46 publications

Activation by O2 of AgxPd1–x Alloy Catalysts for Ethylene Hydrogenation

Activation by O2 of AgxPd1–x Alloy Catalysts for Ethylene Hydrogenation

Performance Evaluation of the Green Surfactant-Treated Nanofluid in Enhanced Oil Recovery: Dill-Hop Extracts and SiO2/Bentonite Nanocomposites

Pd@GO catalyzed stereo- and regio-selective addition of arenes to alkynes and synthesis of coumarins via C–H functionalization

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Product

Resources

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Activation by O₂ of Ag_xPd_1–x Alloy Catalysts for Ethylene Hydrogenation

Activation by O₂ of Ag_xPd_1–x Alloy Catalysts for Ethylene Hydrogenation

Performance Evaluation of the Green Surfactant-Treated Nanofluid in Enhanced Oil Recovery: Dill-Hop Extracts and SiO₂/Bentonite Nanocomposites