Fe-MOF Materials as Precursors for the Catalytic Dehydrogenation of Isobutane

Rodriguez‐Gomez, Alberto; Ould‐Chikh, Samy; Castells‐Gil, Javier; Aguilar‐Tapia, Antonio; Bordet, Pierre; Alrushaid, Mogbel; Martí‐Gastaldo, Carlos; Gascón, Jorge

doi:10.1021/acscatal.1c05303

Cited by 28 publications

(16 citation statements)

References 49 publications

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“…Building on these successes, recent efforts have been extended to designing MOF-based artificial enzymes for CO 2 reduction, monooxygenation with O 2 , and other important reactions. − In particular, a dicopper system has been built on the SBUs of a Ti-MOF to mimic the structures and functions of monooxygenases (Figure ). However, these SBU-based monooxygenase mimics do not allow the incorporation of nitrogen-based ligands which play crucial roles in natural enzymes.…”

Section: Introductionmentioning

confidence: 99%

Self-adaptive Metal–Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases

et al. 2023

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Despite significant efforts, it remains a challenge to design artificial enzymes that can mimic both structures and functions of natural enzymes. Here, we report the post-synthetic construction of binuclear iron catalysts in MOF-253 to mimic natural di-iron monooxygenases. The adjacent bipyridyl (bpy) linkers in MOF-253 can freely rotate to form the [(bpy)FeIII(μ2-OH)]2 active site in a self-adaptive fashion. The composition and structure of the [(bpy)FeIII(μ2-OH)]2 active sites in MOF-253 were characterized by a combination of inductively coupled plasma–mass spectrometry, thermogravimetric analysis, X-ray absorption spectrometry, and Fourier-transform infrared spectroscopy. The MOF-based artificial monooxygenase effectively catalyzed oxidative transformations of organic compounds, including C–H oxidation and alkene epoxidation reactions, using O2 as the only oxidant, which indicates the successful recapitulation of the structure and functions of natural monooxygenases using readily accessible MOFs. The di-iron system exhibited at least 27 times higher catalytic activity than the corresponding mononuclear control. DFT calculations showed that the binuclear system had a 14.2 kcal/mol lower energy barrier than the mononuclear system in the rate-determining C–H activation process, suggesting the importance of cooperativity of the iron centers in the [(bpy)FeIII(μ2-OH)]2 active site in the rate-determining step. The stability and recyclability of the MOF-based artificial monooxygenase were also demonstrated.

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Section: Introductionmentioning

confidence: 99%

Self-adaptive Metal–Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases

et al. 2023

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“…The C 1s spectrum can be deconvoluted into four peaks at 284.8, 285.9, 289.0, and 290.6 eV, corresponding to C–C/CC, C–O, CO, and OC–O, respectively (Figure b). , Among these component peaks, the C–C/CC occupies a considerable proportion, indicating the existence of huge graphitic carbons in Fe 2 O 3 @HA-Fe-BPDC. In the high-resolution O 1s spectrum (Figure c), the four fitted peaks are located at 530.9, 531.9, 533.2, and 533.9 eV, which can be assigned to Fe–O, Fe–OH, C–O, and CO, respectively. , The high relative intensities of Fe–O and Fe–OH components suggest the formation of Fe 2 O 3 as well as the coordination between oxygen-containing functional groups and iron ions. In terms of the Fe 2p spectrum shown in Figure d, two peaks are observed at 712.0 and 725.7 eV, corresponding to Fe 2p 3/2 and Fe 2p 1/2 , respectively .…”

Section: Resultsmentioning

confidence: 95%

Facile Preparation of Interlocked Fe₂O₃/MOF Composite for Boosted Rate and Cycle Performance of Lithium-Ion Batteries

Su¹,

Hua

Yang³

et al. 2023

Energy Fuels

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Iron oxide (Fe 2 O 3 ) is emerging as a potential anode alternative for lithium-ion batteries (LIBs) due to the merits of high specific capacity, environmental friendliness, and costeffectiveness. However, trapped by unsatisfactory cycling stability and rate capability, further modification is needed for Fe 2 O 3 to achieve practical requirements. In this study, a Fe 2 O 3 -based composite anode (namely Fe 2 O 3 @HA-Fe-BPDC) with interlocked structure was designed and synthesized for pursuing enhanced electrochemical properties. Benefiting from the porous structure, abundant active sites, and good tolerance to volume expansion, the as-prepared electrode exhibits significantly boosted rate capability, excellent specific capacity, and satisfactory reversibility. Typically, the Fe 2 O 3 @HA-Fe-BPDC anode provided an excellent specific capacity of 708 mAh g −1 at 0.1 A g −1 and remained at a high level of 332 mAh g −1 at 1 A g −1 , delivering significantly improved rate performance than Fe 2 O 3 . Additionally, outstanding capacity retention (95.4%) was achieved at 1 A g −1 after 600 charge/discharge cycles. The strategy based on the facile coprecipitation for fabricating Fe 2 O 3 and MOF composite electrodes provides a feasible technique to develop a high-performance anode for LIBs.

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“…H 2 -TPR profiles of the materials showed a similar behavior, a first hydrogen consumption peak from ∼300 to 500 °C corresponding to the reduction of Fe 3 O 4 to FeO and the one at ∼600 °C associated with the reduction of FeO to Fe(0) and the decomposition of the carbon matrix (Figure S38). 27 Based on these results, Fe@C600 and Fe@C600-25 were pretreated at 350 °C under a hydrogen atmosphere for 4 h before the catalytic studies. The iron catalysts were tested in the CO 2 hydrogenation reaction at 350 °C, 50 bar, H 2 /CO 2 = 3, and two different gas hourly space velocities (GHSVs), 7500 and 15,000 mL g −1 h −1 .…”

Section: Resultsmentioning

confidence: 99%

Controlled Manufacture of Heterogeneous Catalysts for the Hydrogenation of CO₂ via Steam Pyrolysis of Different Metal–Organic Frameworks

et al. 2023

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The use of metal−organic frameworks (MOFs) as precursors for the manufacture of heterogeneous catalysts has gained a great deal of attention over the last decade. By subjecting a given MOF to pyrolysis, electrochemical degradation, or other treatments under a controlled atmosphere, (supported) metal (oxide) nanoparticles with very narrow size distributions can be obtained, opening the door to the design of more efficient catalytic solids. Here, we demonstrate the benefits of steam during the controlled decomposition of two different MOF structures (Basolite F300(Fe) and In@ZIF-67(Co)) and the consequences of treatment under this mildly oxidizing atmosphere on the properties of the resulting catalysts for the direct hydrogenation of CO 2 to hydrocarbons and methanol. In-depth characterization demonstrates that steam addition helps to control the phase composition both before and after catalysis; additionally, it results in the formation of smaller nanoparticles, thus leading to more efficient catalysts in comparison with conventional pyrolysis.

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Fe-MOF Materials as Precursors for the Catalytic Dehydrogenation of Isobutane

Cited by 28 publications

References 49 publications

Self-adaptive Metal–Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases

Self-adaptive Metal–Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases

Facile Preparation of Interlocked Fe₂O₃/MOF Composite for Boosted Rate and Cycle Performance of Lithium-Ion Batteries

Controlled Manufacture of Heterogeneous Catalysts for the Hydrogenation of CO₂ via Steam Pyrolysis of Different Metal–Organic Frameworks

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Fe-MOF Materials as Precursors for the Catalytic Dehydrogenation of Isobutane

Cited by 28 publications

References 49 publications

Self-adaptive Metal–Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases

Self-adaptive Metal–Organic Framework Assembles Di-iron Active Sites to Mimic Monooxygenases

Facile Preparation of Interlocked Fe2O3/MOF Composite for Boosted Rate and Cycle Performance of Lithium-Ion Batteries

Controlled Manufacture of Heterogeneous Catalysts for the Hydrogenation of CO2 via Steam Pyrolysis of Different Metal–Organic Frameworks

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Product

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About

Facile Preparation of Interlocked Fe₂O₃/MOF Composite for Boosted Rate and Cycle Performance of Lithium-Ion Batteries

Controlled Manufacture of Heterogeneous Catalysts for the Hydrogenation of CO₂ via Steam Pyrolysis of Different Metal–Organic Frameworks