Your search keyword '"Probst, Michael"' showing total 16 results

1. Theoretical study of fructose adsorption and conversion to trioses on metal–organic frameworks.

Author

Sittiwong, Jarinya, Maihom, Thana, Wansa, Chomphunuch, Probst, Michael, and Limtrakul, Jumras

Abstract

The conversion of chemically modified biomass into more valuable chemicals has recently gained significant attention from industry. In this study, we investigate the adsorption of fructose and its conversion into two trioses, glyceraldehyde (GLA) and dihydroxyacetone (DHA), on metal–organic frameworks using density functional theory calculations. The reaction mechanism proceeds through two main steps: first, the opening of the fructose ring; second, the retro-aldol fragmentation, which is favored over intramolecular hydrogen shifts. The substitution of a tetravalent metal in the metal–organic framework leads to different adsorption strengths in the order Hf-NU-1000 > Zr-NU-1000 > Ti-NU-1000. The catalytic activities of Hf-NU-1000 and Zr-NU-1000 are found to be similar. Both are more active than Ti-NU1000, corresponding to their relative Lewis acidity. It was found that functionalization of the organic linkers of the Hf-NU-1000 MOF does not improve its catalytic activity. The catalytic activity follows the order Hf-MOF-808 > Hf-NU-1000 > Hf-UIO-66 when based on either the overall activation energy or the turnover frequency (TOF). [ABSTRACT FROM AUTHOR]

Published

2024

2. Understanding the interactions between lithium polysulfides and anchoring materials in advanced lithium–sulfur batteries using density functional theory.

Author

Maihom, Thana, Sittiwong, Jarinya, Probst, Michael, and Limtrakul, Jumras

Abstract

Lithium–sulfur batteries (LSBs) are promising energy storage devices because of their high theoretical capacity and energy density. However, the "shuttle" effect in lithium polysulfides (LiPSs) is an unresolved issue that can hinder their practical commercial application. Research on LSBs has focused on finding appropriate materials that suppress this effect by efficiently anchoring the LiPSs intermediates. Quantum chemical computations are a useful tool for understanding the mechanistic details of chemical interaction involving LiPSs, and they can also offer strategies for the rational design of LiPSs anchoring materials. In this perspective, we highlight computational and theoretical work performed on this topic. This includes elucidating and characterizing the adsorption mechanisms, and the dominant types of interactions, and summarizing the binding energies of LiPSs on anchoring materials. We also give examples and discuss the potential of descriptors and machine learning approaches to predict the adsorption strength and reactivity of materials. We believe that both approaches will become indispensable in modelling future LSBs. [ABSTRACT FROM AUTHOR]

Published

2022

3. Dehydrogenation of ethanol to acetaldehyde with nitrous oxide over the metal–organic framework NU-1000: a density functional theory study.

Author

Paluka, Veerachart, Maihom, Thana, Probst, Michael, and Limtrakul, Jumras

Abstract

The conversion of ethanol to more valuable hydrocarbon compounds receives great attention in chemical industries because it could diminish the dependency on petroleum as raw material. We investigate the catalytic performance of Fe-supported MOF NU-1000 for the dehydrogenation of ethanol to acetaldehyde with nitrous oxide (N2O) by deriving the relevant reaction profiles with density functional theory calculations. In the proposed mechanism, the activation barrier of the rate-determining step is almost four times lower in the presence of N2O than without it. The supported NU-1000 framework plays also important role since it facilitates electron transfers and stabilizes all species along the reaction coordinate. When considering the catalytic activity of tetravalent metal centers (Zr, Hf and Ti) substituted into NU-1000 it is found that their activity decreases in the order Hf ≥ Zr > Ti, based on activation energies and turnover frequencies (TOF). Concerning MOF linkers, we show that the catalytic activity is not further improved by functionalizing NU-1000 with either electron-donating or electron-withdrawing organic groups. [ABSTRACT FROM AUTHOR]

Published

2020

4. Iterative training set refinement enables reactive molecular dynamics via machine learned forces.

Author

Chen, Lei, Sukuba, Ivan, Probst, Michael, and Kaiser, Alexander

Published

2020

5. Computational study of the carbonyl–ene reaction between formaldehyde and propylene encapsulated in coordinatively unsaturated metal–organic frameworks M3(btc)2 (M = Fe, Co, Ni, Cu and Zn).

Author

Maihom, Thana, Probst, Michael, and Limtrakul, Jumras

Abstract

The carbonyl–ene reaction between encapsulated formaldehyde and propylene over the coordinatively unsaturated metal–organic frameworks M3(btc)2 (M = Fe, Co, Ni, Cu and Zn) has been investigated by means of density functional calculations. Zn3(btc)2 adsorbs formaldehyde strongest due to electron delocalization between Zn and the oxygen atom of the reactant molecule. The reaction is proposed to proceed in a single step involving proton transfer and carbon–carbon bond formation. We find the relative catalytic activity to be Zn3(btc)2 ＞ Fe3(btc)2≥ Co3(btc)2 ＞ Ni3(btc)2 ＞ Cu3(btc)2, based on activation energy and turnover frequencies (TOF). The low activation energy for Zn3(btc)2 compared to the others can be explained by the delocalization of electron density between the carbonyl bond and the catalyst active sites, leading to a more stable transition state. The five MOFs are used to propose a descriptor for the relationship between activation energy on one side and electronic properties or adsorption energies on the other side in order to allow a quick screening of other catalytic materials for this reaction. [ABSTRACT FROM AUTHOR]

Published

2019

6. A computational study of the catalytic aerobic epoxidation of propylene over the coordinatively unsaturated metal–organic framework Fe3(btc)2: formation of propylene oxide and competing reactions.

Author

Maihom, Thana, Sawangphruk, Montree, Probst, Michael, and Limtrakul, Jumras

Abstract

The aerobic epoxidation of propylene over the metal–organic framework Fe3(btc)2 (btc = 1,3,5-benzentricarboxylate) as catalyst has been investigated by means of density functional calculations. The mechanisms of the reaction towards propylene oxide, carbonylic products (acetone and propanal) and a pi-allyl radical were investigated to assess the efficiency of Fe3(btc)2 for the selective formation of propylene oxide. Propylene oxide and carbonylic products are formed on Fe3(btc)2 by proceeding via propyleneoxy intermediates in the first step. Subsequently, the intermediates can then either be transformed to propylene oxide by way of ring closure of the intermediate or to the carbonylic compounds of propanal and acetone via 1,2-hydride shift. The results show that the formation of propylene oxide is favored over the formation of carbonylic products mainly due to the activation barriers being 2–3 times smaller. The activation barriers for the formation of the propyleneoxy intermediates on the Fe3(btc)2 catalyst for the first and second reaction cycle are also lower than the barriers obtained for the formation of the pi-allyl radical that acts as the precursor to combustion products. On the basis of these computational results, we therefore expect a high catalytic selectivity of the Fe3(btc)2 catalyst with respect to the formation of propylene oxide. We also compared the catalytic activities of Fe3(btc)2 and Cu3(btc)2. The activation energy of the rate-determining step is almost 2 times lower for Fe3(btc)2 than that for Cu3(btc)2, due to a larger charge transfer from the catalytic site to the O2 molecule in the case of Fe3(btc)2. [ABSTRACT FROM AUTHOR]

Published

2018

7. A proton-hopping charge storage mechanism of ionic one-dimensional coordination polymers for high-performance supercapacitors.

Author

Phattharasupakun, Nutthaphon, Wutthiprom, Juthaporn, Kaenket, Surasak, Maihom, Thana, Limtrakul, Jumras, Probst, Michael, Nagarkar, Sanjog S., Horike, Satoshi, and Sawangphruk, Montree

Subjects

POLYMERS, SUPERCAPACITORS, IMIDAZOLES

Abstract

A proton-conducting coordination polymer of anionic one-dimensional (1D) chains of Zn2+ phosphate and protonated imidazole with the formula of [Zn(HPO4)(H2PO4)2](ImH2)2 has been used as a novel supercapacitor material in aqueous electrolytes. This material stores charges via a proton-hopping mechanism. [ABSTRACT FROM AUTHOR]

Published

2017

8. Ethane C–H bond activation on the Fe(iv)–oxo species in a Zn-based cluster of metal–organic frameworks: a density functional theory study.

Author

Impeng, Sarawoot, Siwaipram, Siwarut, Bureekaew, Sareeya, and Probst, Michael

Abstract

We first investigate the feasibility of designing a Fe–oxo complex for the activation of alkane C–H bonds by (a) incorporating an Fe ion into a Zn-based cluster derived from a metal–organic framework (MOF) and (b) creating the Fe–oxo complex via decomposition of N2O over a Fe2+-substituted Zn-based cluster (Fe–Zn3O(pyrazole)6). From the energy profile, it turns out that both steps should be feasible and that the resulting Fe–oxo complex is stable. In the main step, we then investigate the reactivity of this Fe–oxo cluster for the C–H bond cleavage of ethane by calculating the reaction energy profile and analyzing the electronic structure along the relevant steps. Two mechanisms, namely the σ and π pathways on the triplet and quintet potential energy surfaces, were unraveled for this study of catalytic activity. It is shown that the σ pathway on the quintet surface is kinetically and thermodynamically favorable with an energy barrier of 22.5 kcal mol−1. The π pathway on the quintet and triplet surfaces has activation energies of 26.9 kcal mol−1 and 24.9 kcal mol−1, respectively. An alternative unusual pathway called the δ mechanism on the triplet surface is also observed with an energy barrier of 12.6 kcal mol−1. It is, however, thermodynamically at a disadvantage compared to the σ pathway on the quintet surface. Favorable d–d interaction on the Fe center and less steric hindrance from the equatorial ligands at the transition state are the key factors that cause the σ pathway on the quintet surface to have the lowest activation energy. All our calculations are of the cluster type and have been performed at the B3LYP-D3/def2-TZVP level of theory. [ABSTRACT FROM AUTHOR]

Published

2017

9. Experimental evidence for the influence of charge on the adsorption capacity of carbon dioxide on charged fullerenes.

Author

Ralser, Stefan, Kaiser, Alexander, Probst, Michael, Postler, Johannes, Renzler, Michael, Bohme, Diethard K., and Scheier, Paul

Abstract

We show, both experimentally and theoretically, that the adsorption of CO2 is sensitive to charge on a capturing model carbonaceous surface. In the experiment we doped superfluid helium droplets with C60 and CO2 and exposed them to ionising free electrons. Both positively and negatively charged C60(CO2)n+/− cluster ion distributions are observed using a high-resolution mass spectrometer and they show remarkable and reproducible anomalies in intensities that are strongly dependent on the charge. The highest adsorption capacity is seen with C60+. Complementary density functional theory calculations and molecular dynamics simulations provided insight into the nature of the interaction of charged C60 with CO2 as well as trends in the packing of C60+ and C60−. The quadrupole moment of CO2 itself was found to be decisive in determining the charge dependence of the observed adsorption features. Our findings are expected to be applied for the adsorption of CO2 on charged surfaces in general. [ABSTRACT FROM AUTHOR]

Published

2016

10. Structures and reaction mechanisms of glycerol dehydration over H-ZSM-5 zeolite: a density functional theory studyElectronic supplementary information (ESI) available: See DOI: 10.1039/c0cp01720e.

Author

Kongpatpanich, Kanokwan, Nanok, Tanin, Boekfa, Bundet, Probst, Michael, and Limtrakul, Jumras

Abstract

The initial stage of glycerol conversion over H-ZSM-5 zeolite has been investigated using density functional theory (DFT) calculations on an embedded cluster model consisting of 128 tetrahedrally coordinated atoms. It is found that glycerol dehydration to acrolein and acetol proceeds favourably viaa stepwise mechanism. The formation of an alkoxide species upon the first dehydration requires the highest activation energy (42.5 kcal mol−1) and can be considered as the rate determining step of the reaction. The intrinsic activation energies for the first dehydration are virtually the same for both acrolein and acetol formation, respectively, suggesting the competitive removal of the primary and secondary OH groups. A high selectivity to acrolein at moderate temperatures can be attributed to the selective activation of the stronger adsorption mode of glycerol through the secondary OH group and the kinetically favoured subsequent consecutive steps. In addition, the less reactive nature of acrolein relative to acetol precludes it from being converted to other products upon conversion to glycerol. In accordance with typical endothermic reactions, the forward rate constant for glycerol dehydration significantly increases with increasing reaction temperature. [ABSTRACT FROM AUTHOR]

Published

2011

11. Ne2+[II (1/2)u]: radiative decay and electronic predissociation.

Author

Matt-Leubner, Sara, Fedor, Juraj, Parajuli, Rajendra, Stamatovic, Aleksandar, Echt, Olof, Hagelberg, Frank, Głuch, Krzysztof, Probst, Michael, Scheier, Paul, and Märk, Tilmann D.

Published

2005

12. Preparation and nuclear magnetic resonance spectroscopy of [Ag2{µ-CH2(PPh2)2}3][O3SCF3]2, a disilver(I) complex with three bridging CH2(PPh2)2 ligands.

Author

Obendorf, Dagmar, Probst, Michael, Peringer, Paul, Falk, Heinz, and Müller, Norbert

Published

1988

13. Computational study of the carbonyl-ene reaction between formaldehyde and propylene encapsulated in coordinatively unsaturated metal-organic frameworks M 3 (btc) 2 (M = Fe, Co, Ni, Cu and Zn).

Author

Maihom T, Probst M, and Limtrakul J

Abstract

The carbonyl-ene reaction between encapsulated formaldehyde and propylene over the coordinatively unsaturated metal-organic frameworks M3(btc)2 (M = Fe, Co, Ni, Cu and Zn) has been investigated by means of density functional calculations. Zn3(btc)2 adsorbs formaldehyde strongest due to electron delocalization between Zn and the oxygen atom of the reactant molecule. The reaction is proposed to proceed in a single step involving proton transfer and carbon-carbon bond formation. We find the relative catalytic activity to be Zn3(btc)2 > Fe3(btc)2 ≥ Co3(btc)2 > Ni3(btc)2 > Cu3(btc)2, based on activation energy and turnover frequencies (TOF). The low activation energy for Zn3(btc)2 compared to the others can be explained by the delocalization of electron density between the carbonyl bond and the catalyst active sites, leading to a more stable transition state. The five MOFs are used to propose a descriptor for the relationship between activation energy on one side and electronic properties or adsorption energies on the other side in order to allow a quick screening of other catalytic materials for this reaction.

Published

2019

14. A computational study of the catalytic aerobic epoxidation of propylene over the coordinatively unsaturated metal-organic framework Fe 3 (btc) 2 : formation of propylene oxide and competing reactions.

Author

Maihom T, Sawangphruk M, Probst M, and Limtrakul J

Abstract

The aerobic epoxidation of propylene over the metal-organic framework Fe 3 (btc) 2 (btc = 1,3,5-benzentricarboxylate) as catalyst has been investigated by means of density functional calculations. The mechanisms of the reaction towards propylene oxide, carbonylic products (acetone and propanal) and a pi-allyl radical were investigated to assess the efficiency of Fe 3 (btc) 2 for the selective formation of propylene oxide. Propylene oxide and carbonylic products are formed on Fe 3 (btc) 2 by proceeding via propyleneoxy intermediates in the first step. Subsequently, the intermediates can then either be transformed to propylene oxide by way of ring closure of the intermediate or to the carbonylic compounds of propanal and acetone via 1,2-hydride shift. The results show that the formation of propylene oxide is favored over the formation of carbonylic products mainly due to the activation barriers being 2-3 times smaller. The activation barriers for the formation of the propyleneoxy intermediates on the Fe 3 (btc) 2 catalyst for the first and second reaction cycle are also lower than the barriers obtained for the formation of the pi-allyl radical that acts as the precursor to combustion products. On the basis of these computational results, we therefore expect a high catalytic selectivity of the Fe 3 (btc) 2 catalyst with respect to the formation of propylene oxide. We also compared the catalytic activities of Fe 3 (btc) 2 and Cu 3 (btc) 2 . The activation energy of the rate-determining step is almost 2 times lower for Fe 3 (btc) 2 than that for Cu 3 (btc) 2 , due to a larger charge transfer from the catalytic site to the O 2 molecule in the case of Fe 3 (btc) 2 .

Published

2018

15. Electron attachment to the dipeptide dialanine: influence of methylation on site selective dissociation reactions.

Author

Puschnigg B, Huber SE, Probst M, Tanzer K, Vizcaino V, Ferreira da Silva F, Scheier P, Limão-Vieira P, and Denifl S

Subjects

Dipeptides metabolism, Electrons, Gases chemistry, Methylation, Quantum Theory, Alanine chemistry, Dipeptides chemistry

Abstract

Gas phase dissociative electron attachment (DEA) measurements with methyl-dialanine, C(7)H(14)N(2)O(3), are performed in a crossed electron-molecular beam experiment at high energy resolution (∼120 meV). Anion efficiency yields as a function of the incident electron energy are obtained for the most abundant fragments up to electron energies of ∼15 eV. There is no evidence of molecular anion formation whereas the dehydrogenated closed shell anion (M-H)(-) is one of the most dominant reaction products. Quantum chemical calculations are performed to investigate the electron attachment process and to elucidate site selective bond cleavage in the (M-H)(-) DEA-channel. Previous DEA studies on dialanine have shown that (M-H)(-) formation proceeds through abstraction of a hydrogen atom from the carboxyl and amide groups, contributing to two distinct resonances at 0.81 and 1.17 eV, respectively [D. Gschliesser, V. Vizcaino, M. Probst, P. Scheier and S. Denifl, Chem.-Eur. J., 2012, 18, 4613-4619]. Here we show that by methylation of the carboxyl group, all (calculated) thresholds for H-loss from the different sites in the dialanine molecule are shifted up to a maximum of 1.4 eV. The lowest lying resonance observed experimentally for (M-H)(-) remains operative from the amide group at the electron energy of 2.4 eV due to the methylation. We further study methylation-induced effects on the unimolecular dissociation leading to a variety of negatively charged DEA products.

Published

2013

16. Ne2+[II (1/2)u]: radiative decay and electronic predissociation.

Author

Matt-Leubner S, Fedor J, Parajuli R, Stamatovic A, Echt O, Hagelberg F, Głuch K, Probst M, Scheier P, and Märk TD

Subjects

Dimerization, Free Radicals chemistry, Ions chemistry, Kinetics, Quantum Theory, Electrons, Neon chemistry

Abstract

Metastable fragmentation of neon dimer ions has been investigated by measuring and analyzing high resolution kinetic energy release distributions. Data were obtained by a modified MIKE (mass-analyzed ion kinetic energy) scan technique. Due to the high energy resolution it was possible to distinguish two different reaction mechanisms in the micros time regime which produce Ne+ ions with different kinetic energy distributions. Theoretical studies based on ab initio calculations of potential energy curves allowed the assignment of the reactions to specific electronic transitions in the excited Ne2+ ion. The unusual bimodal kinetic energy release distribution arises from competition between radiative and non radiative decay of the long-lived Ne2+ II(1/2)u state.

Published

2005