Your search keyword '"Rothenberg, G."' showing total 130 results

1. Investigating proton shuttling and electrochemical mechanisms of amines in integrated CO2 capture and utilization

Author

Bruggeman, D. F., Rothenberg, G., and Garcia, A. C.

Published

2024

2. A Highly Efficient Electrosynthesis of Formaldehyde Using a TEMPO‐Based Polymer Electrocatalyst.

Author

Broersen, P. J. L., Koning, J. J. N., Rothenberg, G., and Garcia, A. C.

Subjects

OXIDATION of methanol, TURNOVER frequency (Catalysis), METAL catalysts, ORGANIC bases, CHEMICAL industry

Abstract

In the chemical industry, formaldehyde is an important bulk chemical. The traditional synthesis of formaldehyde involves an energy intensive oxidation of methanol over a metal oxide catalyst. The selective electrochemical oxidation of methanol is challenging. Herein, we report a catalytic system with an immobilized TEMPO electrode that selectively oxidizes methanol to formaldehyde with high turnover numbers. Upon the addition of various organic and inorganic bases, the activity of the catalyst could be tuned. The highest Faradaic efficiency that was achieved was 97.5 %, the highest turnover number was 17100. Additionally, we found that the rate determining step changed from the step in which the carbonyl specie is created from the methanol‐TEMPO adduct to the oxidative regeneration of the TEMPO+ species. Finally, we showed that the system could be applied to the oxidation of other aliphatic alcohols. [ABSTRACT FROM AUTHOR]

Published

2024

3. Investigating proton shuttling and electrochemical mechanisms of amines in integrated CO2 capture and utilization.

Author

Bruggeman, D. F., Rothenberg, G., and Garcia, A. C.

Subjects

CARBON sequestration, COPPER, ELECTROLYTIC reduction, LEAD, BOND strengths

Abstract

Carbon capture and utilization (CCU) technologies present a promising solution for converting CO2 emissions into valuable products. Here we show how amines, such as monoethanolamine (MEA) and 2-amino-2-methyl-1-propanol (AMP), influence the electrochemical CO2 reduction process in an integrated CCU system. Using in situ spectroscopic techniques, we identify the key roles of carbamate bond strength, proton shuttling, and amine structure in dictating reaction pathways on copper (Cu) and lead (Pb) electrodes. Our findings demonstrate that on Cu electrodes, surface blockage by ammonium species impedes CO₂ reduction, whereas on Pb electrodes, proton shuttling enhances the production of hydrocarbon products. This study provides additional insights into optimizing CCU systems by tailoring the choice of amines and electrode materials, advancing the selective conversion of CO₂ into valuable chemicals. Integrated carbon capture and utilization (CCU) systems offer a sustainable approach to converting CO₂ emissions into valuable chemicals. Here, the authors report the choice of amine and electrode materials significantly impact the efficiency and selectivity of CO2 reduction in CCU processes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Enhancing CO2 plasma conversion using metal grid catalysts.

Author

Devid, E. J., Ronda-Lloret, M., Zhang, D., Schuler, E., Wang, D., Liang, C.-H., Huang, Q., Rothenberg, G., Shiju, N. R., and Kleyn, A. W.

Subjects

METAL catalysts, PLASMA chemistry, METAL mesh, CHEMICAL reactions, CHEMICAL yield

Abstract

The synergy between catalysis and plasma chemistry often enhances the yield of chemical reactions in plasma-driven reactors. In the case of CO2 splitting into CO and O2, no positive synergistic effect was observed in earlier studies with plasma reactors, except for dielectric barrier discharges, that do not have a high yield and a high efficiency. Here, we demonstrate that introducing metal meshes into radio frequency-driven plasma reactors increases the relative reaction yield by 20%–50%, while supported metal oxide catalysts in the same setups have no effect. We attribute this to the double role of the metal mesh, which acts both as a catalyst for direct CO2 dissociation as well as for oxygen recombination. [ABSTRACT FROM AUTHOR]

Published

2021

5. Christian Insurrections in Turkish Dalmatia 1580-96

Author

Rothenberg, G. E.

Published

1961

6. Glycerol Valorization: Dehydration to Acrolein Over Silica-Supported Niobia Catalysts

Author

Shiju, N. R., Brown, D. R., Wilson, K., and Rothenberg, G.

Published

2010

7. The Role of Vacancies in a Ti2CTx MXene‐Derived Catalyst for Butane Oxidative Dehydrogenation.

Author

Ronda‐Lloret, M., Slot, T. K., van Leest, N. P., de Bruin, B., Sloof, W. G., Batyrev, E., Sepúlveda‐Escribano, A., Ramos‐Fernandez, E. V., Rothenberg, G., and Shiju, N. R.

Subjects

OXIDATIVE dehydrogenation, BUTANE, CATALYSTS, CATALYTIC activity, ELECTRIC conductivity

Abstract

MXenes are a new family of 2D carbides or nitrides that have attracted attention due to their layered structure, tunable surface groups and high electrical conductivity. Here, we report for the first time that the Ti2CTx MXene catalyses the selective oxidative dehydrogenation of n‐butane to butenes and 1,3‐butadiene. This catalyst showed higher intrinsic activity compared to a commercial TiC and TiO2 samples in terms of C4 olefin formation rate. We propose that the stabilisation of structural vacancies and the change in composition (from a carbide to a mixed phase oxide) in the MXene causes its higher catalytic activity. These vacancies can lead to a higher concentration of unpaired electrons in the MXene‐derived material, enhancing its nucleophilic properties and favouring the production of olefins. [ABSTRACT FROM AUTHOR]

Published

2022

8. Pt 0.02Sn 0.003Mg 0.06 on γ-alumina: a stable catalyst for oxidative dehydrogenation of ethane

Author

de Graaf, E.A., Rothenberg, G., Kooyman, P.J., Andreini, A., and Bliek, A.

Published

2005

9. Micropore characteristics of organic matter pools in cemented and non-cemented podzolic horizons.

Author

Catoni, M., D'amico, M. E., Mittelmeijer‐Hazeleger, M. C., Rothenberg, G., and Bonifacio, E.

Subjects

MICROPORES, PODZOL, ORGANOMETALLIC compounds, SOIL mineralogy, MICROPOROSITY, SOIL formation, OXIDATION

Abstract

In Podzols, organic matter ( OM) is stabilized mainly by interaction with minerals, as a direct consequence of pedogenic processes. Metal-organic associations strongly affect OM surface features, particularly microporosity. Cemented ortstein horizons ( CM) may form during podzolization, accompanied by a spatial arrangement of OM on mineral surfaces, which differs from that in non-cemented horizons ( N-CM). To investigate the metal-organic associations and their changes during pedogenesis, we selected both N-CM and CM podzolic horizons, isolated NaClO-resistant OM and compared the specific surface area ( SSA) before and after OM oxidation. The SSA was assessed by using N2, to detect the pores in the range of micropores (< 2 nm) and mesopores (2-50 nm), and CO2, to measure a smaller microporosity (< 0.5 nm), which is not accessible to N2. Only the N-CM samples showed the typical increase in N2-SSA after the removal of labile OM, while a decrease was found in all CM horizons. The CO2-SSA revealed a large number of small micropores characterizing OM, both before and after oxidation. The smallest micropore classes (< 0.5 nm) were, however, more abundant in NaClO-resistant OM, which had therefore a larger number of N2-inaccessible surfaces than the labile pool. The N2-SSA data thus indicated a more homogeneous coverage of mineral surfaces by stabilized OM in CM samples. Because of the abundance of small micropores, OM in these podzolic B horizons had extremely large CO2-SSA values (about 800 m2 g−1), with sharp differences between the NaClO-labile OM (290-380 m2 g−1) and the NaClO-stabilized pool (1380-1860 m2 g−1), thus indicating very reactive illuvial organic materials. [ABSTRACT FROM AUTHOR]

Published

2014

10. Chiral imprinting of palladium with cinchona alkaloids.

Author

Dur&;#x00E1;n Pachón, L., Yosef, I., Markus, T. Z., Naaman, R., Avnir, D., and Rothenberg, G.

Subjects

ENANTIOSELECTIVE catalysis, MATERIALS science, METAL analysis, STEREOCHEMISTRY, TRANSITION metals, PALLADIUM, HYDROGENATION

Abstract

In the search for new materials and concepts in materials science, metallo-organic hybrids are attractive candidates; they can combine the rich diversity of organic molecules with the advantages of metals. Transition metals such as palladium are widely applied in catalysis, and small organic molecules such as those in the cinchona alkaloid family can control the stereochemistry of a number of organic reactions. Here, we show that reducing a metal salt in the presence of a cinchona alkaloid dopant gives a chirally imprinted metallo-organic hybrid material that is catalytically active and shows moderate enantioselectivity in hydrogenation. Furthermore, using photoelectron emission spectroscopy, we show that the metal retains some chiral character even after extraction of the dopant. This simple and effective methodology opens exciting opportunities for developing a variety of chiral composite materials. [ABSTRACT FROM AUTHOR]

Published

2009

11. Oxidative Dehydrogenation of Alcohols with Metal Oxides on N-Doped Carbon.

Author

SLOT, T. K., EISENBERG, D., VAN NOORDENNE, D., JUNGBACKER, P., and ROTHENBERG, G.

Published

2016

12. ChemInform Abstract: A New Simple Method for the Synthesis of Cyclobutyl Cyanide.

Author

COHEN, S., ROTHENBERG, G., and SASSON, Y.

Published

1998

13. ChemInform Abstract: Extending the Haloform Reaction to Non-Methyl Ketones: Oxidative Cleavage of Cycloalkanones to Dicarboxylic Acids Using Sodium Hypochlorite under Phase-Transfer Catalysis Conditions.

Author

ROTHENBERG, G. and SASSON, Y.

Published

1997

14. Mesoporous Silica with Site-Isolated Amine and Phosphotungstic Acid Groups: A Solid Catalyst with Tunable Antagonistic Functions for One-Pot Tandem Reactions

Author

and Rothenberg G, Brown

Published

2011

15. Parameter Dependency of Electrochemical Reduction of CO 2 in Acetonitrile - A Data Driven Approach.

Author

Deacon-Price C, Mijatović A, Hoefsloot HCJ, Rothenberg G, and Garcia AC

Abstract

The electrochemical CO 2 reduction reaction (CO 2 RR) is a promising technology for the utilization of captured CO 2 . Though systems using aqueous electrolytes is the state-of-the-art, CO 2 RR in aprotic solvents are a promising alternative that can avoid the parallel hydrogen evolution reaction (HER). While system parameters, such as electrolyte composition, electrode material, and applied potential are known to influence the reaction mechanism, there is a lack of intuitive understanding as to how. We show that by using multivariate data analysis on a large dataset collected from the literature, namely random forest modelling, the most important system parameters can be isolated for each possible product. We find that water content, current density, and applied potential are powerful determinants in the reaction pathway, and therefore in the Faradaic efficiency of CO 2 RR products., (© 2024 The Authors. ChemPhysChem published by Wiley-VCH GmbH.)

Published

2024

16. Bio-electrocatalytic Alkene Reduction Using Ene-Reductases with Methyl Viologen as Electron Mediator.

Author

Wei Z, Knaus T, Damian M, Liu Y, Santana CS, Yan N, Rothenberg G, and Mutti FG

Subjects

Electrochemical Techniques, Oxidoreductases metabolism, Oxidoreductases chemistry, Viologens chemistry, Electrons, Alkenes chemistry, Alkenes metabolism, Biocatalysis, Oxidation-Reduction

Abstract

Asymmetric hydrogenation of alkene moieties is important for the synthesis of chiral molecules, but achieving high stereoselectivity remains a challenge. Biocatalysis using ene-reductases (EReds) offers a viable solution. However, the need for NAD(P)H cofactors limits large-scale applications. Here, we explored an electrochemical alternative for recycling flavin-containing EReds using methyl viologen as a mediator. For this, we built a bio-electrocatalytic setup with an H-type glass reactor cell, proton exchange membrane, and carbon cloth electrode. Experimental results confirm the mediator's electrochemical reduction and enzymatic consumption. Optimization showed increased product concentration at longer reaction times with better reproducibility within 4-6 h. We tested two enzymes, Pentaerythritol Tetranitrate Reductase (PETNR) and the Thermostable Old Yellow Enzyme (TOYE), using different alkene substrates. TOYE showed higher productivity for the reduction of 2-cyclohexen-1-one (1.20 mM h -1 ), 2-methyl-2-cyclohexen-1-one (1.40 mM h -1 ) and 2-methyl-2-pentanal (0.40 mM h -1 ), with enantiomeric excesses ranging from 11 % to 99 %. PETNR outperformed TOYE in terms of enantioselectivity for the reduction of 2-methyl-2-pentanal (ee 59 % ± 7 % (S)). Notably, TOYE achieved promising results also in reducing ketoisophorone, a challenging substrate, with similar enantiomeric excess compared to published values using NADH., (© 2024 The Authors. ChemBioChem published by Wiley-VCH GmbH.)

Published

2024

17. Borohydride Hydrolysis Using a Mechanically and Chemically Stable Aluminium-Stainless Steel Porous Monolith Catalyst Made by 3D Printing.

Author

Pope F, Xhaferri X, Giesen D, Geels NJ, Pichler J, and Rothenberg G

Abstract

The challenge of moving to a carbon-free energy economy is highlighted in the context of technology and materials restrictions. Many technologies needed for the so-called energy transition depend on critical metals such as platinum, lithium, iridium and cobalt. Here we focus on solid borohydride salts as hydrogen carriers, studying catalysts for hydrogen release. We combine metal 3D printing technology and a Raney-type leaching process to make structured macroscopic catalyst/reactor monoliths of cobalt, aluminium and stainless steel with well-defined micropores. Remarkably, the blank catalyst samples, which are made only from aluminium and stainless steel (Al-SS), show high activity and, importantly, high stability in borohydride hydrolysis, with no mass loss and no surface poisoning. The batch results are confirmed in a continuous setup running for 96 h. Catalyst performance is attributed to the stable porous structure, the mechanical stability of the stainless steel macrostructure, and the presence of accessible Al(OH)x sites. This research shows a clear contribution to sustainability based on multi-factor comparison: The Al-SS catalyst outperforms the state-of-the-art on mechanical and chemical durability, it is both PGM-free and CRM-free, and its preparation follows a simple, scalable and low-waste procedure., (© 2024 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published

2024

18. Tuning catalytic performance of platinum single atoms by choosing the shape of cerium dioxide supports.

Author

Laan PCM, Mekkering MJ, de Zwart FJ, Troglia A, Bliem R, Zhao K, Geels NJ, de Bruin B, Rothenberg G, Reek JNH, and Yan N

Abstract

The local coordination environment of single atom catalysts (SACs) often determines their catalytic performance. To understand these metal-support interactions, we prepared Pt SACs on cerium dioxide (CeO 2 ) cubes, octahedra and rods, with well-structured exposed crystal facets. The CeO 2 crystals were characterized by SEM, TEM, pXRD, and N 2 sorption, confirming the shape-selective synthesis, identical bulk structure, and variations in specific surface area, respectively. EPR, XPS, TEM and XANES measurements showed differences in the oxygen vacancy density following the trend rods > octahedra > cubes. AC-HAADF-STEM, XPS and CO-DRIFTS measurements confirmed the presence of only single Pt 2+ sites, with different surface platinum surface concentrations. We then compared the performance of the three catalysts in ammonia borane hydrolysis. Precise monitoring of reaction kinetics between 30-80 °C gave Arrhenius plots with hundreds of data points. All plots showed a clear inflection point, the temperature of which (rods > octahedra > cubes) correlates to the energy barrier of ammonia borane diffusion to the Pt sites. These activity differences reflect variations in the - facet dependent - degree of stabilization of intermediates by surface oxygen lone pairs and surface-metal binding strength. Our results show how choosing the right macroscopic support shape can give control over single atom catalysed reactions on the microscopic scale., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

19. The impact of statin therapy on the healing of diabetic foot ulcers: a case-control series.

Author

O'Dell B, Rothenberg G, Holmes C, Priesand S, Mizokami-Stout K, Brandt EJ, and Schmidt BM

Abstract

Background: Diabetic foot ulcers (DFU) are a costly complication of diabetes mellitus (DM), with significant implications for the patient and the healthcare professionals that treat them. The primary objective of this study was to evaluate if there were improved healing rates in patients with a DFU that were taking a statin medication compared to those patients with a DFU who were not taking a statin medication. Secondary outcomes assessed were correlations with wound healing or statin use on data obtained from retrospective chart review., Methods: A case-control series was performed to obtain appropriate demographic information, comorbid conditions, laboratory values, and physical examination findings. From the time of presentation with DFU, these patients were followed for 12 weeks to evaluate for healing. Healing was defined as full epithelialization of the DFU with no further drainage. Wound healing and statin use correlation testing was then done for collected variables and each cohort. Chi square and Pearson correlation were then performed to identify any significant correlations. All p-values were two-sided, and findings were considered statistically significant at p < 0.05., Results: Our study identified 109 patients, 75 patients with a DFU on statin medication and 34 patients with a DFU not on statin medication. The statin cohort was more likely to be older, less than 5-year duration of diabetes, have more comorbidities, decreased low-density lipoprotein (LDL) cholesterol, and decreased total cholesterol (p < 0.05). Among those patients taking a statin medication, 48.0% (36/75) healed their DFU within 12 weeks. Among those patients not taking a statin medication, 44.1% (15/34) healed their DFU within 12 weeks. No correlation was noted between wound healing and statin use (p = 0.7). For wound healing, a negative correlation was noted for prior minor amputations (p < 0.05). For statin use, correlations were noted for age, duration of DM, LDL cholesterol level, total cholesterol level, HTN, CAD, and HLD (p < 0.05)., Conclusions: Statin medication use did not influence DFU healing rates between cohorts. There was a correlation noted between wound healing and prior minor amputations and between statin use and age, duration of DM, LDL cholesterol, total cholesterol, HTN, CAD and HLD. Additionally, we observed no correlation between DFU healing rates and use of a statin medication., (© 2024. The Author(s).)

Published

2024

20. Bottom-Up Synthesis of Platinum Dual-Atom Catalysts on Cerium Oxide.

Author

Mekkering MJ, Laan PCM, Troglia A, Bliem R, Kizilkaya AC, Rothenberg G, and Yan N

Abstract

We present here the synthesis and performance of dual-atom catalysts (DACs), analogous to well-known single-atom catalysts (SACs). DACs feature sites containing pairs of metal atoms and can outperform SACs due to their additional binding possibilities. Yet quantifying the improved catalytic activity in terms of proximity effects remains difficult, as it requires both high-resolution kinetic data and an understanding of the reaction pathways. Here, we use an automated bubble counter setup for comparing the catalytic performance of ceria-supported platinum SACs and DACs in ammonia borane hydrolysis. The catalysts were synthesized by wet impregnation and characterized using SEM, HAADF-STEM, XRD, XPS, and CO-DRIFTS. High-precision kinetic studies of ammonia borane hydrolysis in the presence of SACs show two temperature-dependent regions, with a transition point at 43 °C. Conversely, the DACs show only one regime. We show that this is because DACs preorganize both ammonia borane and water at the dual-atom active site. The additional proximal Pt atom improves the reaction rate 3-fold and enables faster reactions at lower temperatures. We suggest that the DACs enable the activation of the water-O-H bond as well as increase the hydrogen spillover effect due to the adjacent Pt site. Interestingly, using ammonia borane hydrolysis as a benchmark reaction gives further insight into hydrogen spillover mechanisms, above what is known from the CO oxidation studies., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

21. Noncovalent Grafting of Molecular Complexes to Solid Supports by Counterion Confinement.

Author

Laan PCM, Bobylev EO, Geels NJ, Rothenberg G, Reek JNH, and Yan N

Abstract

Grafting molecular complexes on solid supports is a facile strategy to synthesize advanced materials. Here, we present a general and simple method for noncovalent grafting on charge-neutral surfaces. Our method is based on the generic principle of counterion confinement in surface micropores. We demonstrate the power of this approach using a set of three platinum complexes: Pt 1 (Pt 1 L 4 (BF 4 ) 2 , L = p -picoline), Pt 2 (Pt 2 L 4 (BF 4 ) 4 , L = 2,6-bis(pyridine-3-ylethynyl)pyridine), and Pt 12 (Pt 12 L 24 (BF 4 ) 24 , L = 4,4'-(5-methoxy-1,3-phenylene)dipyridine). These complexes share the same counterion (BF 4 - ) but differ vastly in their size, charge, and structure. Imaging of the grafted materials by aberration-corrected high-angle annular dark-field scanning transmission electron microscopy (AC-HAADF-STEM) and energy-dispersive X-ray (EDX) showed that our method results in a homogeneous distribution of both complexes and counterions. Nitrogen sorption studies indicated a decrease in the available surface area and micropore volume, providing evidence for counterion confinement in the surface micropores. Following the adsorption of the complexes over time showed that this is a two-step process: fast surface adsorption by van der Waals forces was followed by migration over the surface and surface binding by counterion confinement. Regarding the binding of the complexes to the support, we found that the surface-adsorbate binding constant ( K S ) increases quadratically with the number of anions per complex up to K S = 1.6 × 10 6 M -1 equaling Δ G ° ads = -35 kJ mol -1 for the surface binding of Pt 12 . Overall, our method has two important advantages: first, it is general, as you can anchor different complexes (with different charges, counterions, and/or sizes); second, it promotes the distribution of the complexes on the support surface, creating well-distributed sites that can be used in various applications across several areas of chemistry., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

22. Tailoring Secondary Coordination Sphere Effects in Single-metal-site Catalysts by Surface Immobilization of Supramolecular Cages.

Author

Laan PCM, Bobylev EO, de Zwart FJ, Vleer JA, Troglia A, Bliem R, Rothenberg G, Reek JNH, and Yan N

Abstract

Controlling the coordination sphere of heterogeneous single-metal-site catalysts is a powerful strategy for fine-tuning their catalytic properties but is fairly difficult to achieve. To address this problem, we immobilized supramolecular cages where the primary- and secondary coordination sphere are controlled by ligand design. The kinetics of these catalysts were studied in a model reaction, the hydrolysis of ammonia borane, over a temperature range using fast and precise online measurements generating high-precision Arrhenius plots. The results show how catalytic properties can be enhanced by placing a well-defined reaction pocket around the active site. Our fine-tuning yielded a catalyst with such performance that the reaction kinetics are diffusion-controlled rather than chemically controlled., (© 2023 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2023

23. Creating Conjugated C-C Bonds between Commercial Carbon Electrode and Molecular Catalyst for Oxygen Reduction to Hydrogen Peroxide.

Author

Biemolt J, Meeus EJ, de Zwart FJ, de Graaf J, Laan PCM, de Bruin B, Burdyny T, Rothenberg G, and Yan N

Abstract

Immobilizing molecular catalysts on electrodes is vital for electrochemical applications. However, creating robust electrode-catalyst interactions while maintaining good catalytic performance and rapid electron transfer is challenging. Here, without introducing any foreign elements, we show a bottom-up synthetic approach of constructing the conjugated C-C bond between the commercial Vulcan carbon electrode and an organometallic catalyst. Characterization results from FTIR, XPS, aberration-corrected TEM and EPR confirmed the successful and uniform heterogenization of the complex. The synthesized Vulcan-LN 4 -Co catalyst is highly active and selective in the oxygen reduction reaction in neutral media, showing an 80 % hydrogen peroxide selectivity and a 0.72 V (vs. RHE) onset potential which significantly outperformed the homogenous counterpart. Based on single-crystal XRD and NMR data, we built a model for density functional theory calculations which showed a nearly optimal binding energy for the *OOH intermediate. Our results show that the direct conjugated C-C bonding is an effective approach for heterogenizing molecular catalysts on carbon, opening new opportunities for employing molecular catalysts in electrochemical applications., (© 2023 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published

2023

24. A high-performance electrochemical biosensor using an engineered urate oxidase.

Author

Wei Z, Knaus T, Liu Y, Zhai Z, Gargano AFG, Rothenberg G, Yan N, and Mutti FG

Subjects

Urate Oxidase, Gold, Carbon, Electrodes, Electrochemical Techniques, Enzymes, Immobilized, Metal Nanoparticles, Biosensing Techniques

Abstract

We constructed a high-performance biosensor for detecting uric acid by immobilizing an engineered urate oxidase on gold nanoparticles deposited on a carbon-glass electrode. This biosensor showed a low limit-of-detection (9.16 nM), a high sensitivity (14 μA/μM), a wide range of linearity (50 nM-1 mM), and more than 28 days lifetime.

Published

2023

25. Understanding the Oxidative Properties of Nickel Oxyhydroxide in Alcohol Oxidation Reactions.

Author

Laan PCM, de Zwart FJ, Wilson EM, Troglia A, Lugier OCM, Geels NJ, Bliem R, Reek JNH, de Bruin B, Rothenberg G, and Yan N

Abstract

The NiOOH electrode is commonly used in electrochemical alcohol oxidations. Yet understanding the reaction mechanism is far from trivial. In many cases, the difficulty lies in the decoupling of the overlapping influence of chemical and electrochemical factors that not only govern the reaction pathway but also the crystal structure of the in situ formed oxyhydroxide. Here, we use a different approach to understand this system: we start with synthesizing pure forms of the two oxyhydroxides, β-NiOOH and γ-NiOOH. Then, using the oxidative dehydrogenation of three typical alcohols as the model reactions, we examine the reactivity and selectivity of each oxyhydroxide. While solvent has a clear effect on the reaction rate of β-NiOOH, the observed selectivity was found to be unaffected and remained over 95% for the dehydrogenation of both primary and secondary alcohols to aldehydes and ketones, respectively. Yet, high concentration of OH - in aqueous solvent promoted the preferential conversion of benzyl alcohol to benzoic acid. Thus, the formation of carboxylic compounds in the electrochemical oxidation without alkaline electrolyte is more likely to follow the direct electrochemical oxidation pathway. Overoxidation of NiOOH from the β- to γ-phase will affect the selectivity but not the reactivity with a sustained >95% conversion. The mechanistic examinations comprising kinetic isotope effects, Hammett analysis, and spin trapping studies reveal that benzyl alcohol is oxidatively dehydrogenated to benzaldehyde via two consecutive hydrogen atom transfer steps. This work offers the unique oxidative and catalytic properties of NiOOH in alcohol oxidation reactions, shedding light on the mechanistic understanding of the electrochemical alcohol conversion using NiOOH-based electrodes., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

26. Dry reforming of methane over single-atom Rh/Al 2 O 3 catalysts prepared by exsolution.

Author

Mekkering MJ, Biemolt J, de Graaf J, Lin YA, van Leest NP, Troglia A, Bliem R, de Bruin B, Rothenberg G, and Yan N

Abstract

Single-atom catalysts often show exceptionally high performance per metal loading. However, the isolated atom sites tend to agglomerate during preparation and/or high-temperature reaction. Here we show that in the case of Rh/Al 2 O 3 this deactivation can be prevented by dissolution/exsolution of metal atoms into/from the support. We design and synthesise a series of single-atom catalysts, characterise them and study the impact of exsolution in the dry reforming of methane at 700-900 °C. The catalysts' performance increases with increasing reaction time, as the rhodium atoms migrate from the subsurface to the surface. Although the oxidation state of rhodium changes from Rh(iii) to Rh(ii) or Rh(0) during catalysis, atom migration is the main factor affecting catalyst performance. The implications of these results for preparing real-life catalysts are discussed., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2023

27. High-Rate Alkaline Water Electrolysis at Industrially Relevant Conditions Enabled by Superaerophobic Electrode Assembly.

Author

Li L, Laan PCM, Yan X, Cao X, Mekkering MJ, Zhao K, Ke L, Jiang X, Wu X, Li L, Xue L, Wang Z, Rothenberg G, and Yan N

Abstract

Alkaline water electrolysis (AWE) is among the most developed technologies for green hydrogen generation. Despite the tremendous achievements in boosting the catalytic activity of the electrode, the operating current density of modern water electrolyzers is yet much lower than the emerging approaches such as the proton-exchange membrane water electrolysis (PEMWE). One of the dominant hindering factors is the high overpotentials induced by the gas bubbles. Herein, the bubble dynamics via creating the superaerophobic electrode assembly is optimized. The patterned Co-Ni phosphide/spinel oxide heterostructure shows complete wetting of water droplet with fast spreading time (≈300 ms) whereas complete underwater bubble repelling with 180° contact angle is achieved. Besides, the current collector/electrode interface is also modified by coating with aerophobic hydroxide on Ti current collector. Thus, in the zero-gap water electrolyzer test, a current density of 3.5 A cm -2 is obtained at 2.25 V and 85 °C in 6 m KOH, which is comparable with the state-of-the-art PEMWE using Pt-group metal catalyst. No major performance degradation or materials deterioration is observed after 330 h test. This approach reveals the importance of bubble management in modern AWE, offering a promising solution toward high-rate water electrolysis., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

28. Understanding the Behaviour of Real Metaborates in Solution.

Author

Pope F, Watson NI, Deblais A, and Rothenberg G

Subjects

Borohydrides, Hydrolysis, Potassium, Salts, Hydrogen

Abstract

Alkali metal borohydrides are promising candidates for large-scale hydrogen storage. They react spontaneously with water, generating dihydrogen and metaborate salts. While sodium borohydride is the most studied, potassium has the best chance of commercial application. Here we examine the physical and chemical properties of such self-hydrolysis solutions. We do this by following the hydrogen evolution, the pH changes, and monitoring the reaction intermediates using NMR. Most studies on such systems are done using dilute solutions, but real-life applications require high concentrations. We show that increasing the borohydride concentration radically changes the system's microstructure and rheology. The changes are seen already at concentrations as low as 5 w/w%, and are critical above 10 w/w%. While dilute solutions are Newtonian, concentrated reaction solutions display non-Newtonian behaviour, that we attribute to the formation and (dis)entanglement of metaborate oligomers. The implications of these findings towards using borohydride salts for hydrogen storage are discussed., (© 2022 The Authors. ChemPhysChem published by Wiley-VCH GmbH.)

Published

2022

29. A membrane-free flow electrolyzer operating at high current density using earth-abundant catalysts for water splitting.

Author

Yan X, Biemolt J, Zhao K, Zhao Y, Cao X, Yang Y, Wu X, Rothenberg G, and Yan N

Abstract

Electrochemical water splitting is one of the most sustainable approaches for generating hydrogen. Because of the inherent constraints associated with the architecture and materials, the conventional alkaline water electrolyzer and the emerging proton exchange membrane electrolyzer are suffering from low efficiency and high materials/operation costs, respectively. Herein, we design a membrane-free flow electrolyzer, featuring a sandwich-like architecture and a cyclic operation mode, for decoupled overall water splitting. Comprised of two physically-separated compartments with flowing H 2 -rich catholyte and O 2 -rich anolyte, the cell delivers H 2 with a purity >99.1%. Its low internal ohmic resistance, highly active yet affordable bifunctional catalysts and efficient mass transport enable the water splitting at current density of 750 mA cm -2 biased at 2.1 V. The eletrolyzer works equally well both in deionized water and in regular tap water. This work demonstrates the opportunity of combining the advantages of different electrolyzer concepts for water splitting via cell architecture and materials design, opening pathways for sustainable hydrogen generation.

Published

2021

30. Molybdenum Oxide Supported on Ti 3 AlC 2 is an Active Reverse Water-Gas Shift Catalyst.

Author

Ronda-Lloret M, Yang L, Hammerton M, Marakatti VS, Tromp M, Sofer Z, Sepúlveda-Escribano A, Ramos-Fernandez EV, Delgado JJ, Rothenberg G, Ramirez Reina T, and Shiju NR

Abstract

MAX phases are layered ternary carbides or nitrides that are attractive for catalysis applications due to their unusual set of properties. They show high thermal stability like ceramics, but they are also tough, ductile, and good conductors of heat and electricity like metals. Here, we study the potential of the Ti 3 AlC 2 MAX phase as a support for molybdenum oxide for the reverse water-gas shift (RWGS) reaction, comparing this new catalyst to more traditional materials. The catalyst showed higher turnover frequency values than MoO 3 /TiO 2 and MoO 3 /Al 2 O 3 catalysts, due to the outstanding electronic properties of the Ti 3 AlC 2 support. We observed a charge transfer effect from the electronically rich Ti 3 AlC 2 MAX phase to the catalyst surface, which in turn enhances the reducibility of MoO 3 species during reaction. The redox properties of the MoO 3 /Ti 3 AlC 2 catalyst improve its RWGS intrinsic activity compared to TiO 2 - and Al 2 O 3 -based catalysts., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

31. Biodegradable Plastics: Standards, Policies, and Impacts.

Author

Filiciotto L and Rothenberg G

Subjects

Acrylic Resins chemistry, Animals, Biodegradation, Environmental, Climate Change, Ecosystem, Environmental Pollution prevention & control, Food Chain, Humans, Nylons chemistry, Polyethylene chemistry, Biodegradable Plastics chemistry, Biotechnology legislation & jurisprudence, Biotechnology standards, Waste Management methods

Abstract

Plastics are ubiquitous in our society. They are in our phones, clothes, bottles, and cars. Yet having improved our lives considerably, they now threaten our environment and our health. The associated carbon emissions and persistency of plastics challenge the fragile balance of many ecosystems. One solution is using biodegradable plastics. Ideally, such plastics are easily assimilated by microorganisms and disappear from our environment. This can help reduce the problems of climate change, microplastics, and littering. However, biodegradable plastics are still only a tiny portion of the global plastics market and require further efforts in research and commercialization. Here, a critical overview of the state of the art of biodegradable plastics is given. Using a material flow analysis, the challenges of the plastic market are highlighted, and with it the large market potential of biodegradable plastics. The environmental and socio-economic impact of plastics, government policies, standards and certifications, physico-chemical properties, and analytical techniques are covered. The Review concludes with a personal outlook on the future of bioplastics, based on our own experience with their development and commercialization., (© 2020 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published

2021

32. Butane Dry Reforming Catalyzed by Cobalt Oxide Supported on Ti 2 AlC MAX Phase.

Author

Ronda-Lloret M, Marakatti VS, Sloof WG, Delgado JJ, Sepúlveda-Escribano A, Ramos-Fernandez EV, Rothenberg G, and Shiju NR

Abstract

MAX (M n+1 AX n ) phases are layered carbides or nitrides with a high thermal and mechanical bulk stability. Recently, it was shown that their surface structure can be modified to form a thin non-stoichiometric oxide layer, which can catalyze the oxidative dehydrogenation of butane. Here, the use of a Ti 2 AlC MAX phase as a support for cobalt oxide was explored for the dry reforming of butane with CO 2 , comparing this new catalyst to more traditional materials. The catalyst was active and selective to synthesis gas. Although the surface structure changed during the reaction, the activity remained stable. Under the same conditions, a titania-supported cobalt oxide catalyst gave low activity and stability due to the agglomeration of cobalt oxide particles. The Co 3 O 4 /Al 2 O 3 catalyst was active, but the acidic surface led to a faster deactivation. The less acidic surface of the Ti 2 AlC was better at inhibiting coke formation. Thanks to their thermal stability and acid-base properties, MAX phases are promising supports for CO 2 conversion reactions., (© 2020 The Authors. Published by Wiley-VCH GmbH.)

Published

2020

33. CO 2 Hydrogenation at Atmospheric Pressure and Low Temperature Using Plasma-Enhanced Catalysis over Supported Cobalt Oxide Catalysts.

Author

Ronda-Lloret M, Wang Y, Oulego P, Rothenberg G, Tu X, and Shiju NR

Abstract

CO 2 is a promising renewable, cheap, and abundant C1 feedstock for producing valuable chemicals, such as CO and methanol. In conventional reactors, because of thermodynamic constraints, converting CO 2 to methanol requires high temperature and pressure, typically 250 °C and 20 bar. Nonthermal plasma is a better option, as it can convert CO 2 at near-ambient temperature and pressure. Adding a catalyst to such plasma setups can enhance conversion and selectivity. However, we know little about the effects of catalysts in such systems. Here, we study CO 2 hydrogenation in a dielectric barrier discharge plasma-catalysis setup under ambient conditions using MgO, γ-Al 2 O 3 , and a series of Co x O y /MgO catalysts. While all three catalyst types enhanced CO 2 conversion, Co x O y /MgO gave the best results, converting up to 35% of CO 2 and reaching the highest methanol yield (10%). Control experiments showed that the basic MgO support is more active than the acidic γ-Al 2 O 3 , and that MgO-supported cobalt oxide catalysts improve the selectivity toward methanol. The methanol yield can be tuned by changing the metal loading. Overall, our study shows the utility of plasma catalysis for CO 2 conversion under mild conditions, with the potential to reduce the energy footprint of CO 2 -recycling processes., Competing Interests: The authors declare no competing financial interest., (© 2020 American Chemical Society.)

Published

2020

34. An experimental approach for controlling confinement effects at catalyst interfaces.

Author

Slot TK, Riley N, Shiju NR, Medlin JW, and Rothenberg G

Abstract

Catalysts are conventionally designed with a focus on enthalpic effects, manipulating the Arrhenius activation energy. This approach ignores the possibility of designing materials to control the entropic factors that determine the pre-exponential factor. Here we investigate a new method of designing supported Pt catalysts with varying degrees of molecular confinement at the active site. Combining these with fast and precise online measurements, we analyse the kinetics of a model reaction, the platinum-catalysed hydrolysis of ammonia borane. We control the environment around the Pt particles by erecting organophosphonic acid barriers of different heights and at different distances. This is done by first coating the particles with organothiols, then coating the surface with organophosphonic acids, and finally removing the thiols. The result is a set of catalysts with well-defined "empty areas" surrounding the active sites. Generating Arrhenius plots with >300 points each, we then compare the effects of each confinement scenario. We show experimentally that confining the reaction influences mainly the entropy part of the enthalpy/entropy trade-off, leaving the enthalpy unchanged. Furthermore, we find this entropy contribution is only relevant at very small distances (<3 Å for ammonia borane), where the "empty space" is of a similar size to the reactant molecule. This suggests that confinement effects observed over larger distances must be enthalpic in nature., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2020

35. Self-Exfoliated Synthesis of Transition Metal Phosphate Nanolayers for Selective Aerobic Oxidation of Ethyl Lactate to Ethyl Pyruvate.

Author

Zhang W, Oulego P, Sharma SK, Yang XL, Li LJ, Rothenberg G, and Shiju NR

Abstract

Two-dimensional (2D) transition metal nanosheets are promising catalysts because of the enhanced exposure of the active species compared to their 3D counterparts. Here, we report a simple, scalable, and reproducible strategy to prepare 2D phosphate nanosheets by forming a layered structure in situ from phytic acid (PTA) and transition metal precursors. Controlled combustion of the organic groups of PTA results in interlayer carbon, which keeps the layers apart during the formation of phosphate, and the removal of this carbon results in ultrathin nanosheets with controllable layers. Applying this concept to vanadyl phosphate synthesis, we show that the method yields 2D ultrathin nanosheets of the orthorhombic β-form, exposing abundant V 4+ /V 5+ redox sites and oxygen vacancies. We demonstrate the high catalytic activity of this material in the vapor-phase aerobic oxidation of ethyl lactate to ethyl pyruvate. Importantly, these β-VOPO 4 compounds do not get hydrated, thereby reducing the competing hydrolysis reaction by water byproducts. The result has superior selectivity to ethyl pyruvate compared to analogous vanadyl phosphates. The catalysts are highly stable, maintaining a steady-state conversion of ∼90% (with >80% selectivity) for at least 80 h on stream. This "self-exfoliated" synthesis protocol opens opportunities for preparing structurally diverse metal phosphates for catalysis and other applications., Competing Interests: The authors declare no competing financial interest., (Copyright © 2020 American Chemical Society.)

Published

2020

36. Beyond Lithium-Based Batteries.

Author

Biemolt J, Jungbacker P, van Teijlingen T, Yan N, and Rothenberg G

Abstract

We discuss the latest developments in alternative battery systems based on sodium, magnesium, zinc and aluminum. In each case, we categorize the individual metals by the overarching cathode material type, focusing on the energy storage mechanism. Specifically, sodium-ion batteries are the closest in technology and chemistry to today's lithium-ion batteries. This lowers the technology transition barrier in the short term, but their low specific capacity creates a long-term problem. The lower reactivity of magnesium makes pure Mg metal anodes much safer than alkali ones. However, these are still reactive enough to be deactivated over time. Alloying magnesium with different metals can solve this problem. Combining this with different cathodes gives good specific capacities, but with a lower voltage (<1.3 V, compared with 3.8 V for Li-ion batteries). Zinc has the lowest theoretical specific capacity, but zinc metal anodes are so stable that they can be used without alterations. This results in comparable capacities to the other materials and can be immediately used in systems where weight is not a problem. Theoretically, aluminum is the most promising alternative, with its high specific capacity thanks to its three-electron redox reaction. However, the trade-off between stability and specific capacity is a problem. After analyzing each option separately, we compare them all via a political, economic, socio-cultural and technological (PEST) analysis. The review concludes with recommendations for future applications in the mobile and stationary power sectors.

Published

2020

37. A Simple and Efficient Device and Method for Measuring the Kinetics of Gas-Producing Reactions.

Author

Slot TK, Shiju NR, and Rothenberg G

Abstract

We present a new device for quantifying gases or gas mixtures based on the simple principle of bubble counting. With this device, we can follow reaction kinetics down to volume step sizes of 8-12 μL. This enables the accurate determination of both time and size of these gas quanta, giving a very detailed kinetic analysis. We demonstrate this method and device using ammonia borane hydrolysis as a model reaction, obtaining Arrhenius plots with over 300 data points from a single experiment. Our device not only saves time and avoids frustration, but also offers more insight into reaction kinetics and mechanistic studies. Moreover, its simplicity and low cost open opportunities for many lab applications., (© 2019 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2019

38. A Critical Look at Direct Catalytic Hydrogenation of Carbon Dioxide to Olefins.

Author

Ronda-Lloret M, Rothenberg G, and Shiju NR

Abstract

One of the main initiatives for fighting climate change is to use carbon dioxide as a resource instead of waste. In this respect, thermocatalytic carbon dioxide hydrogenation to high-added-value chemicals is a promising process. Among the products of this reaction (alcohols, alkanes, olefins, or aromatics), light olefins are interesting because they are building blocks for making polymers, as well as other important chemicals. Olefins are mainly produced from fossil fuel sources, but the increasing demand of plastics boosts the need to develop more sustainable synthetic routes. This review gives a critical overview of the most recent achievements in direct carbon dioxide hydrogenation to light olefins, which can take place through two competitive routes: the modified Fischer-Tropsch synthesis and methanol-mediated synthesis. Both routes are compared in terms of catalyst development, reaction performance, and reaction mechanisms. Furthermore, practical aspects of the commercialization of this reaction, such as renewable hydrogen production and carbon dioxide capture, compression, and transport, are discussed. It is concluded that, to date, the catalysts used in the carbon dioxide hydrogenation reaction give a wide product distribution, which reduces the specific selectivity to lower olefins. More efforts are needed to reach better control of the C/H surface ratio and interactions within the functionalities of the catalyst, as well as understanding the reaction mechanism and avoiding deactivation. Renewable H 2 production and carbon dioxide capture and transport technologies are being developed, although they are currently still too expensive for industrial application., (© 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

39. Efficient Separation of Ethanol-Methanol and Ethanol-Water Mixtures Using ZIF-8 Supported on a Hierarchical Porous Mixed-Oxide Substrate.

Author

Tang Y, Dubbeldam D, Guo X, Rothenberg G, and Tanase S

Abstract

This work reports a new approach for the synthesis of a zeolitic imidazolate framework (ZIF-8) composite. It employs the direct growth of the crystalline ZIF-8 on a mixed-metal oxide support TiO 2 -SiO 2 (TSO), which mimics the porous structure of Populus nigra. Using the natural leaf as a template, the TSO support was prepared using a sol-gel method. The growth of the ZIF-8 layer on the TSO support was carried out by the seeds and second growth method. This method facilitates the homogeneous dispersion of ZIF-8 crystals at the surface of the TSO composite. The ZIF-8@TSO composite adsorbs methanol selectively, mainly due to the hierarchical porous structure of the mixed oxide support. As compared with the as-synthesized ZIF-8, a 50% methanol uptake is achieved in the ZIF-8@TSO composite, with only 25 wt % ZIF-8 loading. IAST simulations show that the ZIF-8@TSO composite has a preferential adsorption toward methanol when using an equimolar methanol-ethanol mixture. An opposite behavior is observed for the as-synthesized ZIF-8. The results show that combining MOFs and mixed-oxide supports with bioinspired structures opens opportunities for synthesizing new materials with unique and enhanced adsorption and separation properties.

Published

2019

40. Air Pollution in Europe.

Author

Koolen CD and Rothenberg G

Abstract

In this short critical perspective, we outline the serious problems caused by air pollution in Europe. Using two types of metrics, level assessment and trend assessment, we quantify the contribution of ammonia, NO x , SO x , non-methane volatile organic compounds, and particulate matter in terms of years of life lost per capita and explain the connection between the various pollutants and their effects on human health and the environment. This is done on the basis of data collected by individual European Union (EU) member states as well as by the EU as a whole. We examine general emission trends as well as sector-specific emissions and discuss the effectiveness of current legislation in reducing health risks and environmental damage. By combining these results with a cost-benefit analysis, we show that a further reduction in NO x emissions is the most urgent and potentially the most beneficial., (© 2018 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2019

41. Coordination polymers from alkaline-earth nodes and pyrazine carboxylate linkers.

Author

Tang Y, Soares AC, Ferbinteanu M, Gao Y, Rothenberg G, and Tanase S

Abstract

A new series of alkaline-earth-metal based coordination polymers were synthesized by using a pyrazine-2,5-dicarboxylic acid (2,5-H2pzdc) ligand under hydrothermal conditions. These compounds show a variety of structural topologies, reflecting the variable coordination geometries of the alkaline-earth ions as well as the key role of the metal precursor salts. Ca, Sr, and Ba give porous three-dimensional compounds, namely [Ca(2,5-pzdc)(H2O)2]·H2O (1), [Sr(2,5-pzdc)(H2O)4]·H2O (3), [Ba(2,5-pzdc)(H2O)4]·2H2O (4) and [Ba(2,5pzdc)(H2O)2] (5), that feature one-dimensional hydrophilic channels which are filled with water molecules. The Sr compound retains its structure when the lattice water molecules are removed, while the other compounds undergo a structural rearrangement. The hydrophilicity of the Sr compound combined with its high stability even in the absence of guest molecules are the key characteristics that determine its good water adsorption and proton conductivity properties.

Published

2018

42. Cooperative Surface-Particle Catalysis: The Role of the "Active Doughnut" in Catalytic Oxidation.

Author

Slot TK, Eisenberg D, and Rothenberg G

Abstract

We consider the factors that govern the activity of bifunctional catalysts comprised of active particles supported on active surfaces. Such catalysts are interesting because the adsorption and diffusion steps, which are often discounted in "conventional" catalytic scenarios, play a key role here. We present an intuitive model, the so-called "active doughnut" concept, defining an active catalytic region around the supported particles. This simple model explains the role of adsorption and diffusion steps in cascade catalytic cycles for active particles supported on active surfaces. The concept has two important practical implications. First, the reaction rate is no longer proportional to the number of active sites, but rather to the number of " communicative" active sites-those available to the reaction intermediates during their respective lifetimes. Second, it generates an important testable prediction concerning the dependence of the total reaction rate on the particle size. With these tools at hand, we examine six experimental examples of catalytic oxidation from the literature, and show that the active doughnut concept gives valuable insight even when detailed mechanistic information is hard to come by.

Published

2018

43. Selective Catalytic Oxidation of Cyclohexene with Molecular Oxygen: Radical Versus Nonradical Pathways.

Author

Denekamp IM, Antens M, Slot TK, and Rothenberg G

Abstract

We study the allylic oxidation of cyclohexene with O 2 under mild conditions in the presence of transition-metal catalysts. The catalysts comprise nanometric metal oxide particles supported on porous N-doped carbons (M/N:C, M=V, Cr, Fe, Co, Ni, Cu, Nb, Mo, W). Most of these metal oxides give only moderate conversions, and the majority of the products are over-oxidation products. Co/N:C and Cu/N:C, however, give 70-80 % conversion and 40-50 % selectivity to the ketone product, cyclohexene-2-one. Control experiments in which we used free-radical scavengers show that the oxidation follows the expected free-radical pathway in almost all cases. Surprisingly, the catalytic cycle in the presence of Cu/N:C does not involve free-radical species in solution. Optimisation of this catalyst gives >85 % conversion with >60 % selectivity to the allylic ketone at 70 °C and 10 bar O 2 . We used SEM, X-ray photoelectron spectroscopy and XRD to show that the active particles have a cupric oxide/cuprous oxide core-shell structure, giving a high turnover frequency of approximately 1500 h -1 . We attribute the high performance of this Cu/N:C catalyst to a facile surface reaction between adsorbed cyclohexenyl hydroperoxide molecules and activated oxygen species.

Published

2018

44. Highly Selective Oxidation of Ethyl Lactate to Ethyl Pyruvate Catalyzed by Mesoporous Vanadia-Titania.

Author

Zhang W, Innocenti G, Oulego P, Gitis V, Wu H, Ensing B, Cavani F, Rothenberg G, and Shiju NR

Abstract

The direct oxidative dehydrogenation of lactates with molecular oxygen is a "greener" alternative for producing pyruvates. Here we report a one-pot synthesis of mesoporous vanadia-titania (VTN), acting as highly efficient and recyclable catalysts for the conversion of ethyl lactate to ethyl pyruvate. These VTN materials feature high surface areas, large pore volumes, and high densities of isolated vanadium species, which can expose the active sites and facilitate the mass transport. In comparison to homogeneous vanadium complexes and VO x /TiO 2 prepared by impregnation, the meso-VTN catalysts showed superior activity, selectivity, and stability in the aerobic oxidation of ethyl lactate to ethyl pyruvate. We also studied the effect of various vanadium precursors, which revealed that the vanadium-induced phase transition of meso-VTN from anatase to rutile depends strongly on the vanadium precursor. NH 4 VO 3 was found to be the optimal vanadium precursor, forming more monomeric vanadium species. V 4+ as the major valence state was incorporated into the lattice of the NH 4 VO 3 -derived VTN material, yielding more V 4+ -O-Ti bonds in the anatase-dominant structure. In situ DRIFT spectroscopy and density functional theory calculations show that V 4+ -O-Ti bonds are responsible for the dissociation of ethyl lactate over VTN catalysts and for further activation of the deprotonation of β-hydrogen. Molecular oxygen can replenish the surface oxygen to regenerate the V 4+ -O-Ti bonds., Competing Interests: The authors declare no competing financial interest.

Published

2018

45. The Ti 3 AlC 2 MAX Phase as an Efficient Catalyst for Oxidative Dehydrogenation of n-Butane.

Author

Ng WHK, Gnanakumar ES, Batyrev E, Sharma SK, Pujari PK, Greer HF, Zhou W, Sakidja R, Rothenberg G, Barsoum MW, and Shiju NR

Abstract

Dehydrogenation or oxidative dehydrogenation (ODH) of alkanes to produce alkenes directly from natural gas/shale gas is gaining in importance. Ti 3 AlC 2 , a MAX phase, which hitherto had not been used in catalysis, efficiently catalyzes the ODH of n-butane to butenes and butadiene, which are important intermediates for the synthesis of polymers and other compounds. The catalyst, which combines both metallic and ceramic properties, is stable for at least 30 h on stream, even at low O 2 :butane ratios, without suffering from coking. This material has neither lattice oxygens nor noble metals, yet a unique combination of numerous defects and a thin surface Ti 1-y Al y O 2-y/2 layer that is rich in oxygen vacancies makes it an active catalyst. Given the large number of compositions available, MAX phases may find applications in several heterogeneously catalyzed reactions., (© 2017 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2018

46. Facile Synthesis of a Novel Hierarchical ZSM-5 Zeolite: A Stable Acid Catalyst for Dehydrating Glycerol to Acrolein.

Author

Beerthuis R, Huang L, Shiju NR, Rothenberg G, Shen W, and Xu H

Abstract

Catalytic biomass conversion is often hindered by coking. Carbon compounds cover active surface and plug pores, causing catalyst deactivation. Material design at the nanoscale allows tailoring of the catalytic activity and stability. Here, we report a simple synthesis of nanosized ZSM-5 materials by using a silicalite-1 seeding suspension. ZSM-5 crystals were grown from a deionized silica source in the presence of ammonia. By using silicalite-1 seeds, crystalline ZSM-5 is synthesized without any structure-directing agent. This method allows parallel preparation of a range of ZSM-5 samples, eliminating time-consuming ion-exchange steps. Mesoporosity is introduced by formation of intercrystallite voids, owing to nanocrystal agglomeration. The effects of crystal sizes and morphologies are then evaluated in the catalytic dehydration of glycerol to acrolein, with results compared against commercial ZSM-5. The most active nanosized ZSM-5 catalysts were five times more stable compared with commercial ZSM-5, giving quantitative conversion and twice the acrolein yield compared with the commercial catalyst. The influence of the catalyst structure on the chemical diffusion and the resistance to coking are discussed.

Published

2018

47. Plasma-Assisted Synthesis of Monodispersed and Robust Ruthenium Ultrafine Nanocatalysts for Organosilane Oxidation and Oxygen Evolution Reactions.

Author

Gnanakumar ES, Ng W, Coşkuner Filiz B, Rothenberg G, Wang S, Xu H, Pastor-Pérez L, Pastor-Blas MM, Sepúlveda-Escribano A, Yan N, and Shiju NR

Abstract

We report a facile and general approach for preparing ultrafine ruthenium nanocatalysts by using a plasma-assisted synthesis at <100 °C. The resulting Ru nanoparticles are monodispersed (typical size 2 nm) and remain that way upon loading onto carbon and TiO 2 supports. This gives robust catalysts with excellent activities in both organosilane oxidation and the oxygen evolution reaction.

Published

2017

48. Revisiting Hansen Solubility Parameters by Including Thermodynamics.

Author

Louwerse MJ, Maldonado A, Rousseau S, Moreau-Masselon C, Roux B, and Rothenberg G

Abstract

The Hansen solubility parameter approach is revisited by implementing the thermodynamics of dissolution and mixing. Hansen's pragmatic approach has earned its spurs in predicting solvents for polymer solutions, but for molecular solutes improvements are needed. By going into the details of entropy and enthalpy, several corrections are suggested that make the methodology thermodynamically sound without losing its ease of use. The most important corrections include accounting for the solvent molecules' size, the destruction of the solid's crystal structure, and the specificity of hydrogen-bonding interactions, as well as opportunities to predict the solubility at extrapolated temperatures. Testing the original and the improved methods on a large industrial dataset including solvent blends, fit qualities improved from 0.89 to 0.97 and the percentage of correct predictions rose from 54 % to 78 %. Full Matlab scripts are included in the Supporting Information, allowing readers to implement these improvements on their own datasets., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

49. Sustainable Separations of C 4 -Hydrocarbons by Using Microporous Materials.

Author

Gehre M, Guo Z, Rothenberg G, and Tanase S

Subjects

Hydrocarbons chemistry, Organometallic Compounds chemistry, Porosity, Zeolites chemistry, Chemical Fractionation methods, Green Chemistry Technology methods, Hydrocarbons isolation & purification

Abstract

Petrochemical refineries must separate hydrocarbon mixtures on a large scale for the production of fuels and chemicals. Typically, these hydrocarbons are separated by distillation, which is extremely energy intensive. This high energy cost can be mitigated by developing materials that can enable efficient adsorptive separation. In this critical review, the principles of adsorptive separation are outlined, and then the case for C 4 separations by using zeolites and metal-organic frameworks (MOFs) is examined. By analyzing both experimental and theoretical studies, the challenges and opportunities in C 4 separation are outlined, with a focus on the separation mechanisms and structure-selectivity correlations. Zeolites are commonly used as adsorbents and, in some cases, can separate C 4 mixtures well. The pore sizes of eight-membered-ring zeolites, for example, are in the order of the kinetic diameters of C 4 isomers. Although zeolites have the advantage of a rigid and highly stable structure, this is often difficult to functionalize. MOFs are attractive candidates for hydrocarbon separation because their pores can be tailored to optimize the adsorbate-adsorbent interactions. MOF-5 and ZIF-7 show promising results in separating all C 4 isomers, but breakthrough experiments under industrial conditions are needed to confirm these results. Moreover, the flexibility of the MOF structures could hamper their application under industrial conditions. Adsorptive separation is a promising viable alternative and it is likely to play an increasingly important role in tomorrow's refineries., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

50. Boosting the Supercapacitance of Nitrogen-Doped Carbon by Tuning Surface Functionalities.

Author

Biemolt J, Denekamp IM, Slot TK, Rothenberg G, and Eisenberg D

Subjects

Surface Properties, Carbon chemistry, Electric Capacitance, Nitrogen chemistry

Abstract

The specific capacitance of a highly porous, nitrogen-doped carbon is nearly tripled by orthogonal optimization of the microstructure and surface chemistry. First, the carbons' hierarchical pore structure and specific surface area were tweaked by controlling the temperature and sequence of the thermal treatments. The best process (pyrolysis at 900 °C, washing, and subsequent annealing at 1000 °C) yielded a carbon with a specific capacitance of 117 F g -1 -nearly double that of a carbon made by a typical single-step synthesis at 700 °C. Following the structural optimization, the surface chemistry of the carbons was enriched by applying an oxidation routine based on a mixture of nitric and sulfuric acid in a 1:4 ratio at two different treatment temperatures (0 and 20 °C) and different treatment times. The optimal treatment times were 4 h at 0 °C and only 1 h at 20 °C. Overall, the specific capacitance nearly tripled relative to the original carbon, reaching 168 F g -1 . The inherent nitrogen doping of the carbon comes into interplay with the acid-induced surface functionalization, creating a mixture of oxygen- and nitrogen-oxygen functionalities. The evolution of the surface chemistry was carefully followed by X-ray photoelectron spectroscopy and by N 2 sorption porosimetry, revealing stepwise surface functionalization and simultaneous carbon etching. Overall, these processes are responsible for the peak-shaped capacitance trends in the carbons., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017