Your search keyword '"Breynaert E"' showing total 140 results

1. Enhanced luminescence in ZnAlEu layered double hydroxides with interlamellar carboxylate and β-diketone ligands

Author

Morais, A.F., Machado, F.O., Teixeira, A.C., Silva, I.G.N., Breynaert, E., and Mustafa, D.

Published

2019

2. Investigation of chabazitic materials as Cs-137 sorbents from cementitious aqueous solutions

Author

Misaelides, P., Sarri, S., Kantiranis, N., Noli, F., Filippidis, A., de Blochouse, B., Maes, A., and Breynaert, E.

Published

2018

3. Multidiagnostic analysis of silicate speciation in clear solutions/sols for zeolite synthesis

Author

Castro, M., Haouas, M., Taulelle, F., Lim, I., Breynaert, E., Brabants, G., Kirschhock, C.E.A., and Schmidt, W.

Published

2014

4. Redox-active phases and radionuclide equilibrium valence state in subsurface environments – New insights from 6th EC FP IP FUNMIG

Author

Bruggeman, C., Maes, N., Christiansen, B.C., Stipp, S.L.S., Breynaert, E., Maes, A., Regenspurg, S., Malström, M.E., Liu, X., Grambow, B., and Schäfer, Th.

Published

2012

5. Column precipitation chromatography: an approach to quantitative analysis of eigencolloids

Author

Breynaert, E. and Maes, A.

Subjects

Aqueous solution reactions -- Research, Chromatography -- Research, Chemistry

Abstract

A new column precipitation chromatography (CPC) technique, capable of quantitatively measuring technetium eigencolloids in aqueous solutions, is presented. The CPC technique is based on the destabilization and precipitation of eigencolloids by polycations in a confined matrix. Tc-(IV) colloids can be quantitatively determined from their precipitation onto the CPC column (separation step) and their subsequent elution upon oxidation to pertechnetate by peroxide (elution step). A clean-bed particle removal model was used to explain the experimental results.

Published

2005

6. Water electrolyte promoted oxidation of functional thiol groups

Author

Lauwers, K., Breynaert, E., Rombouts, I., Delcour, J.A., and Kirschhock, C.E.A.

Published

2016

7. Chemical Communications / Monitoring early zeolite formation via in situ electrochemical impedance spectroscopy

Author

Brabants, G., Lieben, S., Breynaert, E., Reichel, E. K., Taulelle, F., Martens, J. A., Jakoby, Bernhard, and Kirschhock, C. E. A.

Abstract

Hitherto zeolite formation has not been fully understood. Although electrochemical impedance spectroscopy has proven to be a versatile tool for characterizing ionic solutions, it was never used for monitoring zeolite growth. We show here that EIS can quantitatively monitor zeolite formation, especially during crucial early steps where other methods fall short. Version of record

Published

2016

8. Revisiting Silicalite-1 Nucleation in Clear Solution by Electrochemical Impedance Spectroscopy

Author

Brabants, G., primary, Hubin, M., additional, Reichel, E. K., additional, Jakoby, B., additional, Breynaert, E., additional, Taulelle, F., additional, Martens, J. A., additional, and Kirschhock, C. E. A., additional

Published

2017

9. 3D porous nanostructured platinum prepared using atomic layer deposition

Author

Pulinthanathu Sree, Sreeprasanth, primary, Dendooven, J., additional, Geerts, L., additional, Ramachandran, R. K., additional, Javon, E., additional, Ceyssens, F., additional, Breynaert, E., additional, Kirschhock, C. E. A., additional, Puers, R., additional, Altantzis, T., additional, Van Tendeloo, G., additional, Bals, S., additional, Detavernier, C., additional, and Martens, J. A., additional

Published

2017

10. Pathways for abiotic reduction in the FeS/Se(IV) and FeS2/Se(IV) systems

Author

Breynaert, E., Wangermez, W., Dom, D., Scheinost, A. C., Parac-Vogt, T. N., Kirschhock, C. E. A., and Maes, A.

Subjects

EXAFS, nuclear waste, selenium, NMR

Abstract

The geochemical behaviour and bio-availability of selenium have an unexpectedly intricate impact on modern society. While selenium is an essential micronutrient for many living organisms, the window between deficiency and toxicity is very narrow (0.04 ppm ; essential; 0.04 – 0.1 ppm beneficial; 3 ppm toxic). Due to its similarity to sulphur, it is commonly encountered in subsurface deposits such as coal and uranium, phosphate and sulphidic transitionmetal ores. The release of selenium to the environment is closely associated with the economic exploitation of such deposits. Because of its significant contribution to long-term radiation exposure, 79Se is considered as one of the important isotopes in the inventory of the long-lived radioactive waste produced by nuclear industry. In view of redox properties and abundant occurence in reducing soils and sediments, iron sulphides play an important role in the availability of mobile inorganic selenium in the environment. While previous studies have demonstrated the formation of FeSe and Se0 upon reduction of Se(IV) with respectively iron monsulphides and iron disulphides, the mechanistic pathways explaining the different outcome are missing. Combination of published results in a wide range of relevant systems [1-5] with new spectroscopic information (XAS and NMR spectroscopy) obtained for specifically synthesized key intermediates allows to rationalise all previous observations. These results allow to outline the different pathways and demonstrate how the intermediary selenium, sulphur and selenosulphur species determine the final outcome of the reactions. [1] Scheinost et al (2008), ES&T, 42, 1984–1989 [2] Breynaert et al (2008), ES&T, 42, 3595–3601 [3] Scheinost et al (2008), J. Contam. Hydrol., 102, 228-245 [4] Breynaert et al (2010), ES&T, 44, 6649–6655 [5] Kang et al (2011), ES&T, 45, 2704–2710

Published

2014

11. Monitoring early zeolite formation via in situ electrochemical impedance spectroscopy

Author

Brabants, G., primary, Lieben, S., additional, Breynaert, E., additional, Reichel, E. K., additional, Taulelle, F., additional, Martens, J. A., additional, Jakoby, B., additional, and Kirschhock, C. E. A., additional

Published

2016

12. Time and space resolved methods : General discussion

Author

Sun, W., Booth, S., Myerson, A., Hughes, C., Pan, H., Coquerel, G., Brandel, C., Meekes, H., Mazzotti, M., Fabian, L., Black, S., Vekilov, P., Back, K., Toroz, D., Lovelock, J., Sefcik, J., Rasmuson, Åke Christoffer, Breynaert, E., Sear, R., Hammond, R., Ward, M., Threlfall, T., De Yoreo, J., Davey, R., Ristic, R., Lewtas, K., Roberts, K., Hare, A., Gich, M., Cölfen, H., Likhatskiy, M., Ter Horst, J., Sommerdijk, N., Sun, W., Booth, S., Myerson, A., Hughes, C., Pan, H., Coquerel, G., Brandel, C., Meekes, H., Mazzotti, M., Fabian, L., Black, S., Vekilov, P., Back, K., Toroz, D., Lovelock, J., Sefcik, J., Rasmuson, Åke Christoffer, Breynaert, E., Sear, R., Hammond, R., Ward, M., Threlfall, T., De Yoreo, J., Davey, R., Ristic, R., Lewtas, K., Roberts, K., Hare, A., Gich, M., Cölfen, H., Likhatskiy, M., Ter Horst, J., and Sommerdijk, N.

Abstract

Cited By :4; Export Date: 30 September 2019QC 20191030

Published

2015

13. Molecular self-assembly and clustering in nucleation processes : General discussion

Author

Price, S., Veesler, S., Pan, H., Lewtas, K., Smets, M., Rimez, B., Myerson, A., Hughes, C., Hare, A., Zhang, F., Meekes, H., Mazzotti, M., Rosbottom, I., Khamar, D., Van Den Ende, J., Fabian, L., Black, S., Taulelle, F., Gich, M., Vekilov, P., Toroz, D., Bertran, C. A., Sefcik, J., Schroeder, S., Booth, S., Rasmuson, Åke Christoffer, Breynaert, E., Simone, E., Hammond, R., Sear, R., De Yoreo, J., Davey, R., Anwar, J., Ristic, R., Camacho Corzo, D. M., Roberts, K., Harris, K., Colfen, H., Turner, T., Price, S., Veesler, S., Pan, H., Lewtas, K., Smets, M., Rimez, B., Myerson, A., Hughes, C., Hare, A., Zhang, F., Meekes, H., Mazzotti, M., Rosbottom, I., Khamar, D., Van Den Ende, J., Fabian, L., Black, S., Taulelle, F., Gich, M., Vekilov, P., Toroz, D., Bertran, C. A., Sefcik, J., Schroeder, S., Booth, S., Rasmuson, Åke Christoffer, Breynaert, E., Simone, E., Hammond, R., Sear, R., De Yoreo, J., Davey, R., Anwar, J., Ristic, R., Camacho Corzo, D. M., Roberts, K., Harris, K., Colfen, H., and Turner, T.

Abstract

Cited By :6; Export Date: 30 September 2019QC 20191028

Published

2015

14. Nucleation in complex multi-component and multi-phase systems : General discussion

Author

Price, S., Rimez, B., Sun, W., Peters, B., Christenson, H., Hughes, C., Sun, C. C., Veesler, S., Pan, H., Brandel, C., Biscans, B., Meekes, H., Rosbottom, I., Roth, W. J., Seton, L., Taulelle, F., Black, S., Threlfall, T., Vekilov, P., Poornachary, S., Diemand, J., Toroz, D., Salvalaglio, M., Tipduangta, P., Sefcik, J., Booth, S., Rasmuson, Åke Christoffer, Janbon, S., Ter Horst, J., Simone, E., Hammond, R., Bertran, C. A., Vetter, T., Sear, R., De Yoreo, J., Harris, K., Ristic, R., Kavanagh, A., Roberts, K., Breynaert, E., Myerson, A., Coquerel, G., Wu, D., Cölfen, H., Cuppen, H., Smets, M., Wu, D. T., Price, S., Rimez, B., Sun, W., Peters, B., Christenson, H., Hughes, C., Sun, C. C., Veesler, S., Pan, H., Brandel, C., Biscans, B., Meekes, H., Rosbottom, I., Roth, W. J., Seton, L., Taulelle, F., Black, S., Threlfall, T., Vekilov, P., Poornachary, S., Diemand, J., Toroz, D., Salvalaglio, M., Tipduangta, P., Sefcik, J., Booth, S., Rasmuson, Åke Christoffer, Janbon, S., Ter Horst, J., Simone, E., Hammond, R., Bertran, C. A., Vetter, T., Sear, R., De Yoreo, J., Harris, K., Ristic, R., Kavanagh, A., Roberts, K., Breynaert, E., Myerson, A., Coquerel, G., Wu, D., Cölfen, H., Cuppen, H., Smets, M., and Wu, D. T.

Abstract

Cited By :1; Export Date: 30 September 2019QC 20191028

Published

2015

15. Interaction of selenite with iron sulphide minerals: a new perspective

Author

Breynaert, E., Dom, D., Scheinost, A. C., Kirschhock, C. E. A., and Maes, A.

Subjects

redox, exafs, selenium, xanes, pyrite

Abstract

XAS-based studies of the interaction of selenite with FeS2 and FeS at circum-neutral pH have shown that selenite is reduced to solid state zero-valent Se and FeSex, respectively [1-4]. While these results were initially unexpected, the occurrence of dissolved, low oxidation state selenium species in presence of insoluble elemental Se, resulting from selenite reduction in pyrite containing clay systems, was astonishing. In addition, several authors encountered an identical Se phase solid phase in presence of pyrite, but none of them has been able to relate this phase to a specific mineral. Correlating selenium redox chemistry with sulphide mineral oxidation pathways allowed to relate these observations to the different oxidation behaviour observed between acid-soluble and acid-insoluble metal sulphides [5]. Acid insoluble metal sulphides such as pyrite, molybdenite or tungstenite exhibit oxidative dissolution only. Upon six consequent one-electron oxidation steps, a thiosulphate anion is liberated (thiosulphate pathway). Acid soluble metal sulphides (troilite, mackinawite, sphalerite, etc.) can exhibit both non-oxidative dissolution, hence liberating sulphide species (H2S, HS-,S2-), and oxidative dissolution in presence of FeIII with the release of sulphide cations (e.g. H2S+), that spontaneously dimerize into disulphide species which can further react to form polysulphide (polysulphide pathway) and finally elemental sulphur. While the end products resulting from Se(IV) reduction by acid-soluble iron sulphur minerals are fairly well known, both the solid and liquid phase products from the interaction of SeO32- with pyrite are poorly characterized. Although the solid phase reaction product in could not yet be assigned to a specific phase, it was clearly identified as a Se0 compound and trigonal (grey) selenium could be excluded as a canditate species.[4] The presence of an unexpectedly high concentration of reduced, dissolved species in presence of pyrite, induced the formulation of a new pyrite-based reduction mechanism. Based on this mechanism, hypothesis was put forward about the identity of the unknown dissolved species. In addition, the new mechanism allows explaining all current experimental observations, more specifically the presence of this currently non-identified dissolved species and the unexpected relation between Se(IV) reduction and pH.[6] [1] Breynaert, E., et al. (2008) ES&T. 42(10): 3595-3601. [2] Scheinost, A.C. and Charlet, L. (2008) ES&T. 42(6): 1984-1989. [3] Scheinost, A.C., et al. (2008) J. Contam. Hydrol. 102(3-4): 228-245. [4] Breynaert, E., et al. (2010) ES&T. 44(17): 6649-6655. [5] Rohwerder, T. and Sand, W.(2007) in Microbial Processing of Metal Sulfides 35-58. [6] Kang, M., et al. (2011) ES&T. 45: 2704-2710.

Published

2012

16. Reduction of Se(IV) with Boom Clay: XAS solid phase speciation

Author

Breynaert, E., Scheinost, A. C., Dom, D., Rossberg, A., Vancluysen, J., Gobechiya, E., Kirschhock, C. E. A., and Maes, A.

Subjects

XAFS, selenium

Abstract

The geochemical fate of selenium is of key importance for today’s society due to its role as a highly toxic essential micronutrient and as a significant component of High Level Radioactive Waste (HLRW) originating from the operation of nuclear reactors. Understanding and prediction of the long-term behavior of Se in natural environments requires identification of the in situ speciation of selenium. This article describes an XAS-based investigation into the solid phase speciation of Se upon interaction of Se(IV) with Boom Clay, a reducing, complex sediment selected as model host rock for clay-based deep geological disposal of HLRW in Belgium and Europe. Using a combination of long-term batch sorption experiments, linear combination XANES analysis and ITFA-based EXAFS analysis allowed for the first time to identify Se0 as the dominant solid phase speciation of Se in Boom Clay systems equilibrated with Se(IV).

Published

2010

17. The geochemical fate of Se(IV) in the Boom Clay system - XAS based solid phase speciation

Author

Breynaert, E., Scheinost, A., Dom, D., Rossberg, A., Vancluysen, J., Gobechiya, E., Kirschhock, C., and Maes, A.

Subjects

redox, selenium, Boom clay

Abstract

For more than 30 years the Boom Clay formation is studied as a reference host formation for methodological research concerning clay-based geological disposal of HLRW in Belgium and Europe. Boom Clay provides good sorption capacity, very low permeability and chemically reducing conditions due to the anoxic conditions and the presence of pyrite and siderite. Performance Assessment calculations have indicated Se79 (t1/2 = 2.95×105 y) to be one of the critical radionuclides for the geological disposal of HLRW [1]. Aqueous selenite [Se(+IV)] and selenate [Se(+VI)] are the dominant species in mildly and strongly oxidizing environments. Under reducing conditions the solubility of Se is theoretically controlled by the formation of sparsely soluble selenium phases such as elemental Se or transition metalselenide salts (e.g. FeSe or FeSe2) [2, 3]. Slow kinetic reactions between the different redox states have been observed [4] and proposed to explain different redox phases observed within a single reducing environment. Se oxyanions, such as SeO4 2- and SeO32-, are generally considered as the most mobile forms of Se [5] and their migration through Boom Clay thus is considered as “worst case scenario”. In order to assess their long-term fate it is imperative to understand the influence of different geochemical phases present in the Boom Clay matrix on selenium speciation and mobility. A multidisciplinary approach combining long-term batch sorption experiments with linear combination XANES and ITFA-based EXAFS analysis on different fractions isolated from Boom Clay batch systems equilibrated with Se(IV), identified Se0 as the dominant in situ solid phase speciation of Se in Boom Clay conditions. [1] SAFIR-2, 2001. Brussels, Belgium. p. 288. [2] Breynaert, E. et al., ES&T. 42 (10): p. 3595. [3] Scheinost, A.C. et al., J. Contam. Hydrol. 102 p. 228. [4] Masscheleyn, P.H. et al., ES&T. 24 (1): p. 91. [5] Elrashidi, M.A. et al., Soil Science 144 (2): p. 141.

Published

2010

18. Catalytic activation of OKO zeolite with intersecting pores of 10- and 12-membered rings using atomic layer deposition of aluminium

Author

Verheyen, E., primary, Pulinthanathu Sree, S., additional, Thomas, K., additional, Dendooven, J., additional, De Prins, M., additional, Vanbutsele, G., additional, Breynaert, E., additional, Gilson, J.-P., additional, Kirschhock, C. E. A., additional, Detavernier, C., additional, and Martens, J. A., additional

Published

2014

19. Eu@COK-16, a host sensitized, hybrid luminescent metal–organic framework

Author

Mustafa, D., primary, Silva, I. G. N., additional, Bajpe, S. R., additional, Martens, J. A., additional, Kirschhock, C. E. A., additional, Breynaert, E., additional, and Brito, H. F., additional

Published

2014

20. Flexibility versus rigidity: what determines the stability of zeolite frameworks? A case study

Author

Verheyen, E., primary, Joos, L., additional, Martineau, C., additional, Dawson, C. J., additional, Weidenthaler, C., additional, Schmidt, W., additional, Yuan, R., additional, Breynaert, E., additional, Van Speybroeck, V., additional, Waroquier, M., additional, Taulelle, F., additional, Treacy, M. M. J., additional, Martens, J. A., additional, and Kirschhock, C. E. A., additional

Published

2014

21. Redox-active phases and radionuclide equilibrium valence state in subsurface environments – New insights from the 6th EC FP IP FUNMIG

Author

Bruggeman, C., Maes, N., Christiansen, Bo C., Stipp, Susan Louise Svane, Breynaert, E., Maes, A., Regenspurg, S., Malström, M.E, Liu, X., Grambow, B., Schäfer, Th., Bruggeman, C., Maes, N., Christiansen, Bo C., Stipp, Susan Louise Svane, Breynaert, E., Maes, A., Regenspurg, S., Malström, M.E, Liu, X., Grambow, B., and Schäfer, Th.

Published

2012

22. XANES−EXAFS Analysis of Se Solid-Phase Reaction Products Formed upon Contacting Se(IV) with FeS2and FeS

Author

Breynaert, E., primary, Bruggeman, C., additional, and Maes, A., additional

Published

2008

23. Flexibility versus rigidity: what determines the stability of zeolite frameworks? A case study.

Author

Verheyen, E., Joos, L., Martineau, C., Dawson, C. J., Weidenthaler, C., Schmidt, W., Yuan, R., Breynaert, E., Van Speybroeck, V., Waroquier, M., Taulelle, F., Treacy, M. M. J., Martens, J. A., and Kirschhock, C. E. A.

Published

2014

24. XANES-EXAFS Analysis of Se Solid-Phase Reaction Products Formed upon Contacting Se(IV) with FeS2 and FeS.

Author

Breynaert, E., Bruggeman, C., and Maes, A.

Subjects

*SPECTRUM analysis, *X-ray spectroscopy, *RADIOACTIVE waste disposal, *WASTE management, *RADIOACTIVE wastes, *NUCLEAR facilities

Abstract

The solid-phase Se speciation after short-term (3 weeks) contact of selenite [Se(IV)] oxyanions with pyrite (FeS2) and troilite (FeS) was investigated using X-ray absorption spectroscopy (XAS; X-ray absorption near-edge spectroscopy-extended X-ray absorption fine structure (XANES-EXAFS)). It was found that the nature of the sulfide mineral dictates the final speciation since respectively Se0 and FeSex were formed, meaning that the reaction mechanism is different and that these phases cannot be regarded as geochemically similar. The experimental results support the previously proposed sorption/reduction mechanism for the reaction of selenite with pyrite (8). In the presence of troilite the reduction proceeds through the intermediate formation of Se0 by reduction of selenite with dissolved sulfide. XAS data recorded for the FeS2 and FeS were compared with different Se reference phases, ranging in oxidation state from -II to +IV, used for validation of the XAS analysis methodology. This methodology can in principle be used to analyze Se phases formed in "in situ" geochemical conditions such as high-level radioactive waste disposal facilities. [ABSTRACT FROM AUTHOR]

Published

2008

25. Flexibility versusrigidity: what determines the stability of zeolite frameworks? A case studyElectronic supplementary information (ESI) available: A detailed description of characterization techniques, X-ray diffraction, high temperature X-ray diffraction, 29Si MAS NMR, nitrogen adsorption and thermogravimetric analysis, and computational details. See DOI: 10.1039/c4mh00127c

Author

Verheyen, E., Joos, L., Martineau, C., Dawson, C. J., Weidenthaler, C., Schmidt, W., Yuan, R., Breynaert, E., Van Speybroeck, V., Waroquier, M., Taulelle, F., Treacy, M. M. J., Martens, J. A., and Kirschhock, C. E. A.

Abstract

All silica COK-14/-COK-14with OKOtopology is the first case of a zeolite which reversibly transforms from a systematically interrupted to a fully connected state and back. Analysis of the opening/closing behavior allowed the study of entropy and framework flexibility as determinants for the stability of zeolite topologies, which, until now, has been experimentally inaccessible. Interconversion of the all-silica COK-14zeolite with fully connected OKOtopology and its -COK-14variant with systematic framework interruption was investigated using high-temperature XRD, thermogravimetric analysis, 29Si MAS NMR, nitrogen adsorption and a range of modelling techniques. Specific framework bonds in the OKOframework can be reversibly hydrolyzed and condensed. Structural silanols of the parent -COK-14, prepared by degermanation of the IM-12 zeolite, were condensed by heating at 923 K, and hydrolyzed again to the initial state by contacting the zeolite with warm water. Molecular modelling revealed an inversion of the relative stabilities for both variants depending on temperature and hydration. Condensation of the structural silanols in -COK-14to COK-14is entropy driven, mainly resulting from the release of water molecules. Framework reopening in the presence of water is spontaneous due to the high rigidity of the fully connected OKOframework. Isomorphous substitution was demonstrated as a viable option for stabilization of the fully connected OKOframework as this renders the closed framework flexible.

Published

2014

26. Identifying routes for transferring spin polarization from parahydrogen to protic solvents.

Author

Vaneeckhaute E, Tyburn JM, Kempf JG, Martens JA, and Breynaert E

Abstract

Repeatable hyperpolarization of high concentrations of mobile protons (>6 M) using parahydrogen in protic methanol/water mixtures is reported here. Different ammonium buffers with increasing mobile proton concentrations were added to an IrCl(COD)(IMes) catalyst in the presence of pyridine. We reach a maximum molar polarization of 1.79 mM at 6 mT. Field-cycling experiments in an 18.8 T detection field distinguished two solvent polarization transfer pathways: chemical exchange with labile protons from ammonia and cross-relaxation with pyridine aromatic protons.

Published

2024

27. Tuneable mesoporous silica material for hydrogen storage application via nano-confined clathrate hydrate construction.

Author

Ciocarlan RG, Farrando-Perez J, Arenas-Esteban D, Houlleberghs M, Daemen LL, Cheng Y, Ramirez-Cuesta AJ, Breynaert E, Martens J, Bals S, Silvestre-Albero J, and Cool P

Abstract

Safe storage and utilisation of hydrogen is an ongoing area of research, showing potential to enable hydrogen becoming an effective fuel, substituting current carbon-based sources. Hydrogen storage is associated with a high energy cost due to its low density and boiling point, which drives a high price. Clathrates (gas hydrates) are water-based (ice-like) structures incorporating small non-polar compounds such as H 2 in cages formed by hydrogen bonded water molecules. Since only water is required to construct the cages, clathrates have been identified as a potential solution for safe storage of hydrogen. In bulk, pure hydrogen clathrate (H 2 O-H 2 ) only forms in harsh conditions, but confined in nanospaces the properties of water are altered and hydrogen storage at mild pressure and temperature could become possible. Here, specifically a hydrophobic mesoporous silica is proposed as a host material, providing a suitable nano-confinement for ice-like clathrate hydrate. The hybrid silica material shows an important decrease of the pressure required for clathrate formation (approx. 20%) compared to the pure H 2 O-H 2 system. In-situ inelastic neutron scattering (INS) and neutron diffraction (ND) provided unique insights into the interaction of hydrogen with the complex surface of the hybrid material and demonstrated the stability of nano-confined hydrogen clathrate hydrate., (© 2024. The Author(s).)

Published

2024

28. Correction: Performance of ferrite nanoparticles in inductive heating swing adsorption (IHSA): how tailoring material properties can circumvent the design limitations of a system.

Author

De Belder M, Morais AF, De Vos N, Basov S, Joris R, Van Bael MJ, Van Meervelt L, Denayer JFM, Martens JA, and Breynaert E

Abstract

Correction for 'Performance of ferrite nanoparticles in inductive heating swing adsorption (IHSA): how tailoring material properties can circumvent the design limitations of a system' by Maxim De Belder et al. , Mater. Horiz. , 2024, 11 , 4144-4149, https://doi.org/10.1039/d4mh00377b.

Published

2024

29. Performance of ferrite nanoparticles in inductive heating swing adsorption (IHSA): how tailoring material properties can circumvent the design limitations of a system.

Author

De Belder M, Morais AF, De Vos N, Van Meervelt L, Denayer JFM, Martens JA, and Breynaert E

Abstract

Inductive heating swing adsorption (IHSA) using hybrid adsorbents incorporating a porous material and ferrite nanoparticles holds promise to be a performant, electrified alternative for conventional gas separation. Successful implementation of hybrid adsorbents in IHSA depends on achieving a maximal specific absorption rate (SAR) in the conditions and at the frequency of the induction setup. This paper outlines and demonstrates successful strategies for optimization of the particle composition, tailoring the coercivity and susceptibility of the ferrite particles to optimal performance in a given alternating magnetic field.

Published

2024

30. Harnessing Nuclear Magnetic Resonance Spectroscopy to Decipher Structure and Dynamics of Clathrate Hydrates in Confinement: A Perspective.

Author

Houlleberghs M, Radhakrishnan S, Chandran CV, Morais AF, Martens JA, and Breynaert E

Abstract

This perspective outlines recent developments in the field of NMR spectroscopy, enabling new opportunities for in situ studies on bulk and confined clathrate hydrates. These hydrates are crystalline ice-like materials, built up from hydrogen-bonded water molecules, forming cages occluding non-polar gaseous guest molecules, including CH 4 , CO 2 and even H 2 and He gas. In nature, they are found in low-temperature and high-pressure conditions. Synthetic confined versions hold immense potential for energy storage and transportation, as well as for carbon capture and storage. Using previous studies, this report highlights static and magic angle spinning NMR hardware and strategies enabling the study of clathrate hydrate formation in situ, in bulk and in nano-confinement. The information obtained from such studies includes phase identification, dynamics, gas exchange processes, mechanistic studies and the molecular-level elucidation of the interactions between water, guest molecules and confining interfaces.

Published

2024

31. Computational Protocol for the Spectral Assignment of NMR Resonances in Covalent Organic Frameworks.

Author

Vanlommel S, Borgmans S, Chandran CV, Radhakrishnan S, Van Der Voort P, Breynaert E, and Van Speybroeck V

Abstract

Solid-state nuclear magnetic resonance spectroscopy is routinely used in the field of covalent organic frameworks to elucidate or confirm the structure of the synthesized samples and to understand dynamic phenomena. Typically this involves the interpretation and simulation of the spectra through the assumption of symmetry elements of the building units, hinging on the correct assignment of each line shape. To avoid misinterpretation resulting from library-based assignment without a theoretical basis incorporating the impact of the framework, this work proposes a first-principles computational protocol for the assignment of experimental spectra, which exploits the symmetry of the underlying building blocks for computational feasibility. In this way, this protocol accommodates the validation of previous experimental assignments and can serve to complement new NMR measurements.

Published

2024

32. Surface modification of mesostructured cellular foam to enhance hydrogen storage in binary THF/H 2 clathrate hydrate.

Author

Kummamuru NB, Ciocarlan RG, Houlleberghs M, Martens J, Breynaert E, Verbruggen SW, Cool P, and Perreault P

Abstract

This study introduces solid-state tuning of a mesostructured cellular foam (MCF) to enhance hydrogen (H 2 ) storage in clathrate hydrates. Grafting of promoter-like molecules ( e.g. , tetrahydrofuran) at the internal surface of the MCF resulted in a substantial improvement in the kinetics of formation of binary H 2 -THF clathrate hydrate. Identification of the confined hydrate as sII clathrate hydrate and enclathration of H 2 in its small cages was performed using XRD and high-pressure 1 H NMR spectroscopy respectively. Experimental findings show that modified MCF materials exhibit a ∼1.3 times higher H 2 storage capacity as compared to non-modified MCF under the same conditions (7 MPa, 265 K, 100% pore volume saturation with a 5.56 mol% THF solution). The enhancement in H 2 storage is attributed to the hydrophobicity originating from grafting organic molecules onto pristine MCF, thereby influencing water interactions and fostering an environment conducive to H 2 enclathration. Gas uptake curves indicate an optimal tuning point for higher H 2 storage, favoring a lower density of carbon per nm 2 . Furthermore, a direct correlation emerges between higher driving forces and increased H 2 storage capacity, culminating at 0.52 wt% (46.77 mmoles of H 2 per mole of H 2 O and 39.78% water-to-hydrate conversions) at 262 K for the modified MCF material with fewer carbons per nm 2 . Notably, the substantial H 2 storage capacity achieved without energy-intensive processes underscores solid-state tuning's potential for H 2 storage in the synthesized hydrates. This study evaluated two distinct kinetic models to describe hydrate growth in MCF. The multistage kinetic model showed better predictive capabilities for experimental data and maintained a low average absolute deviation. This research provides valuable insights into augmenting H 2 storage capabilities and holds promising implications for future advancements., Competing Interests: The authors declare no competing financial interest., (This journal is © The Royal Society of Chemistry.)

Published

2024

33. Noncontact In Situ Multidiagnostic NMR/Dielectric Spectroscopy.

Author

Morais AF, Radhakrishnan S, Arbiv G, Dom D, Duerinckx K, Chandran CV, Martens JA, and Breynaert E

Abstract

Introduction of a dielectric material in a nuclear magnetic resonance (NMR) probe head modifies the frequency response of the probe circuit, a phenomenon revealed by detuning of the probe. For NMR spectroscopy, this detuning is corrected for by tuning and matching the probe head prior to the NMR measurement. The magnitude of the probe detuning, "the dielectric shift", provides direct access to the dielectric properties of the sample, enabling NMR spectrometers to simultaneously perform both dielectric and NMR spectroscopy. By measuring sample dielectric permittivity as a function of frequency, dielectric permittivity spectroscopy can be performed using the new methodology. As a proof of concept, this was evaluated on methanol, ethanol, 1-propanol, 1-pentanol, and 1-octanol using a commercial cross-polarization magic angle spinning (CPMAS) NMR probe head. The results accurately match the literature data collected by standard dielectric spectroscopy techniques. Subsequently, the method was also applied to investigate the solvent-surface interactions of water confined in the micropores of an MFI-type, hydrophilic zeolite with a Si/Al ratio of 11.5. In the micropores, water adsorbs to Bro̷nsted acid sites and defect sites, resulting in a drastically decreased dielectric permittivity of the nanoconfined water. Theoretical background for the new methodology is provided using an effective electric circuit model of a CPMAS probe head with a solenoid coil, describing the detuning resulting from the insertion of dielectric samples in the probe head.

Published

2024

34. Building a Cost-Efficient High-Pressure Cell for Online High-Field NMR and MRI Using Standard Static Probe Heads: An In Situ Demonstration on Clathrate Hydrate Formation.

Author

Houlleberghs M, Helsper S, Dom D, Dubroca T, Trociewitz B, Schurko RW, Radhakrishnan S, and Breynaert E

Abstract

High-pressure nuclear magnetic resonance (NMR) spectroscopy finds remarkable applications in catalysis, protein biochemistry and biophysics, analytical chemistry, material science, energy, and environmental control but requires expensive probe heads and/or sample cells. This contribution describes the design, construction, and testing of a low-cost 5 mm NMR tube suitable for high-pressure NMR measurements of up to 30 MPa. The sample cell comprises a standard, 5 mm single-crystal sapphire tube that has been fitted to a section of a relatively inexpensive polyether ether ketone (PEEK) HPLC column. PEEK HPLC tubing and connectors enable integration with a gas rig or a standard HPLC pump located outside the stray field of the magnet. The cell is compatible with any 5 mm static NMR probe head, exhibits almost zero background in NMR experiments, and is compatible with any liquid, gas, temperature, or pressure range encountered in HPLC experimentation. A specifically designed transport case enables the safe handling of the pressurized tube outside the probe head. The performance of the setup was evaluated using in situ high-field NMR spectroscopy and MRI performed during the formation of bulk and nanoconfined clathrate hydrates occluding methane, ethane, and hydrogen.

Published

2023

35. Eu 3+ doped ZnAl layered double hydroxides as calibrationless, fluorescent sensors for carbonate.

Author

Morais AF, Silva IGN, Ferreira BJ, Teixeira AC, Sree SP, Terraschke H, Garcia FA, Breynaert E, and Mustafa D

Abstract

The photoluminescence properties (PL) of Eu 3+ hosted in the hydroxide layers of layered double hydroxides (LDHs) enables calibrationless quantification of anions in the interlayers. The concept is demonstrated during the nitrate-to-carbonate ion exchange in Zn 2+ /Al 3+ /Eu 3+ LDHs and can be implemented as a remote optical sensor to detect intrusion of anions such as Cl - or CO 3 2- .

Published

2023

36. Illuminating the Black Box: A Perspective on Zeolite Crystallization in Inorganic Media.

Author

Asselman K, Kirschhock C, and Breynaert E

Abstract

ConspectusSince the discovery of synthetic zeolites in the 1940s and their implementation in major industrial processes involving adsorption, catalytic conversion, and ion exchange, material scientists have targeted the rational design of zeolites: controlling synthesis to crystallize zeolites with predetermined properties. Decades later, the fundamentals of zeolite synthesis remain largely obscured in a black box, rendering rational design elusive. A major prerequisite to rational zeolite design is to fully understand, and control, the elementary processes governing zeolite nucleation, growth, and stability. The molecular-level investigation of these processes has been severely hindered by the complex multiphasic media in which aluminosilicate zeolites are typically synthesized. This Account documents our recent progress in crystallizing zeolites from synthesis media based on hydrated silicate ionic liquids (HSIL), a synthesis approach facilitating the evaluation of the individual impacts of synthesis parameters such as cation type, water content, and alkalinity on zeolite nucleation, growth, and phase selection. HSIL-based synthesis allows straightforward elucidation of the relationship between the characteristics of the synthesis medium and the properties and structure of the crystalline product. This assists in deriving new insights in zeolite crystallization in an inorganic aluminosilicate system, thus improving the conceptual understanding of nucleation and growth in the context of inorganic zeolite synthesis in general. This Account describes in detail what hydrated silicate ionic liquids are, how they form, and how they assist in improving our understanding of zeolite genesis on a molecular level. It describes the development of ternary phase diagrams for inorganic aluminosilicate zeolites via a systematic screening of synthesis compositions. By evaluating obtained crystal structure properties such as framework composition, topology, and extraframework cation distributions, critical questions are dealt with: Which synthesis variables govern the aluminum content of crystallizing zeolites? How does the aluminum content in the framework determine the expression of different topologies? The crucial role of the alkali cation, taking center stage in all aspects of crystallization, phase selection, and, by extension, transformation is also discussed. New criteria and models for phase selection are proposed, assisting in overcoming the need for excessive trial and error in the development of future synthesis protocols.Recent progress in the development of a toolbox enabling liquid-state characterization of these precursor media has been outlined, setting the stage for the routine monitoring of zeolite crystallization in real time. Current endeavors on and future needs for the in situ investigation of zeolite crystallization are highlighted. Finally, experimentally accessible parameters providing opportunities for modeling zeolite nucleation and growth are identified. Overall, this work provides a perspective toward future developments, identifying research areas ripe for investigation and discovery.

Published

2023

37. Prediction of Cu Zeolite NH 3 -SCR Activity from Variable Temperature 1 H NMR Spectroscopy.

Author

Radhakrishnan S, Smet S, Chandran CV, Sree SP, Duerinckx K, Vanbutsele G, Martens JA, and Breynaert E

Abstract

Selective catalytic reduction (SCR) of NO x by ammonia is one of the dominant pollution abatement technologies for near-zero NO x emission diesel engines. A crucial step in the reduction of NO x to N 2 with Cu zeolite NH 3 -SCR catalysts is the generation of a multi-electron donating active site, implying the permanent or transient dimerization of Cu ions. Cu atom mobility has been implicated by computational chemistry as a key factor in this process. This report demonstrates how variable temperature 1 H NMR reveals the Cu induced generation of sharp 1 H resonances associated with a low concentration of sites on the zeolite. The onset temperature of the appearance of these signals was found to strongly correlate with the NH 3 -SCR activity and was observed for a range of catalysts covering multiple frameworks (CHA, AEI, AFX, ERI, ERI-CHA, ERI-OFF, *BEA), with different Si/Al ratios and different Cu contents. The results point towards universal applicability of variable temperature NMR to predict the activity of a Cu-zeolite SCR catalyst. The unique relationship of a spectroscopic feature with catalytic behavior for zeolites with different structures and chemical compositions is exceptional in heterogeneous catalysis.

Published

2023

38. Hydrogen bonding to oxygen in siloxane bonds drives liquid phase adsorption of primary alcohols in high-silica zeolites.

Author

Radhakrishnan S, Lejaegere C, Duerinckx K, Lo WS, Morais AF, Dom D, Chandran CV, Hermans I, Martens JA, and Breynaert E

Abstract

Upon liquid phase adsorption of C 1 -C 5 primary alcohols on high silica MFI zeolites (Si/Al = 11.5-140), the concentration of adsorbed molecules largely exceeds the concentration of traditional adsorption sites: Brønsted acid and defect sites. Combining quantitative in situ 1 H MAS NMR, qualitative multinuclear NMR and IR spectroscopy, hydrogen bonding of the alcohol function to oxygen atoms of the zeolite siloxane bridges (Si-O-Si) was shown to drive the additional adsorption. This mechanism co-exists with chemi- and physi-sorption on Brønsted acid and defect sites and does not exclude cooperative effects from dispersive interactions.

Published

2023

39. Reversible Parahydrogen Induced Hyperpolarization of 15 N in Unmodified Amino Acids Unraveled at High Magnetic Field.

Author

Vaneeckhaute E, Tyburn JM, Kempf JG, Martens JA, and Breynaert E

Abstract

Amino acids (AAs) and ammonia are metabolic markers essential for nitrogen metabolism and cell regulation in both plants and humans. NMR provides interesting opportunities to investigate these metabolic pathways, yet lacks sensitivity, especially in case of 15 N. In this study, spin order embedded in p-H 2 is used to produce on-demand reversible hyperpolarization in 15 N of pristine alanine and ammonia under ambient protic conditions directly in the NMR spectrometer. This is made possible by designing a mixed-ligand Ir-catalyst, selectively ligating the amino group of AA by exploiting ammonia as a strongly competitive co-ligand and preventing deactivation of Ir by bidentate ligation of AA. The stereoisomerism of the catalyst complexes is determined by hydride fingerprinting using 1 H/D scrambling of the associated N-functional groups on the catalyst (i.e., isotopological fingerprinting), and unravelled by 2D-ZQ-NMR. Monitoring the transfer of spin order from p-H 2 to 15 N nuclei of ligated and free alanine and ammonia targets using SABRE-INEPT with variable exchange delays pinpoints the monodentate elucidated catalyst complexes to be most SABRE active. Also RF-spin locking (SABRE-SLIC) enables transfer of hyperpolarization to 15 N. The presented high-field approach can be a valuable alternative to SABRE-SHEATH techniques since the obtained catalytic insights (stereochemistry and kinetics) will remain valid at ultra-low magnetic fields., (© 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2023

40. Engineering of Phenylpyridine- and Bipyridine-Based Covalent Organic Frameworks for Photocatalytic Tandem Aerobic Oxidation/Povarov Cyclization.

Author

Debruyne M, Borgmans S, Radhakrishnan S, Breynaert E, Vrielinck H, Leus K, Laemont A, De Vos J, Rawat KS, Vanlommel S, Rijckaert H, Salemi H, Everaert J, Vanden Bussche F, Poelman D, Morent R, De Geyter N, Van Der Voort P, Van Speybroeck V, and Stevens CV

Abstract

Covalent organic frameworks (COFs) are emerging as a new class of photoactive organic semiconductors, which possess crystalline ordered structures and high surface areas. COFs can be tailor-made toward specific (photocatalytic) applications, and the size and position of their band gaps can be tuned by the choice of building blocks and linkages. However, many types of building blocks are still unexplored as photocatalytic moieties and the scope of reactions photocatalyzed by COFs remains quite limited. In this work, we report the synthesis and application of two bipyridine- or phenylpyridine-based COFs: TpBpyCOF and TpPpyCOF . Due to their good photocatalytic properties, both materials were applied as metal-free photocatalysts for the tandem aerobic oxidation/Povarov cyclization and α-oxidation of N -aryl glycine derivatives, with the bipyridine-based TpBpyCOF exhibiting the highest activity. By expanding the range of reactions that can be photocatalyzed by COFs, this work paves the way toward the more widespread application of COFs as metal-free heterogeneous photocatalysts as a convenient alternative for commonly used homogeneous (metal-based) photocatalysts.

Published

2023

41. Enabling hydrate-based methane storage under mild operating conditions by periodic mesoporous organosilica nanotubes.

Author

Beckwée EJ, Watson G, Houlleberghs M, Arenas Esteban D, Bals S, Van Der Voort P, Breynaert E, Martens J, Baron GV, and Denayer JFM

Abstract

Biomethane is a renewable natural gas substitute produced from biogas. Storage of this sustainable energy vector in confined clathrate hydrates, encapsulated in the pores of a host material, is a highly promising avenue to improve storage capacity and energy efficiency. Herein, a new type of periodic mesoporous organosilica (PMO) nanotubes, referred to as hollow ring PMO (HR-PMO), capable of promoting methane clathrate hydrate formation under mild working conditions (273 K, 3.5 MPa) and at high water loading (5.1 g water/g HR-PMO) is reported. Gravimetric uptake measurements reveal a steep single-stepped isotherm and a noticeably high methane storage capacity (0.55 g methane/g HR-PMO; 0.11 g methane/g water at 3.5 MPa). The large working capacity throughout consecutive pressure-induced clathrate hydrate formation-dissociation cycles demonstrates the material's excellent recyclability (97% preservation of capacity). Supported by ex situ cryo-electron tomography and x-ray diffraction, HR-PMO nanotubes are hypothesized to promote clathrate hydrate nucleation and growth by distribution and confinement of water in the mesopores of their outer wall, along the central channels of the nanotubes and on the external nanotube surface. These findings showcase the potential for application of organosilica materials with hierarchical and interconnected pore systems for pressure-based storage of biomethane in confined clathrate hydrates., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper, (© 2023 The Authors.)

Published

2023

42. Does Water Enable Porosity in Aluminosilicate Zeolites? Porous Frameworks versus Dense Minerals.

Author

Asselman K, Haouas M, Houlleberghs M, Radhakrishnan S, Wangermez W, Kirschhock CEA, and Breynaert E

Abstract

Recently identified zeolite precursors consisting of concentrated, hyposolvated homogeneous alkalisilicate liquids, hydrated silicate ionic liquids (HSIL), minimize correlation of synthesis variables and enable one to isolate and examine the impact of complex parameters such as water content on zeolite crystallization. HSIL are highly concentrated, homogeneous liquids containing water as a reactant rather than bulk solvent. This simplifies elucidation of the role of water during zeolite synthesis. Hydrothermal treatment at 170 °C of Al-doped potassium HSIL with chemical composition 0.5SiO 2 :1KOH: x H 2 O:0.013Al 2 O 3 yields porous merlinoite (MER) zeolite when H 2 O/KOH exceeds 4 and dense, anhydrous megakalsilite when H 2 O/KOH is lower. Solid phase products and precursor liquids were fully characterized using XRD, SEM, NMR, TGA, and ICP analysis. Phase selectivity is discussed in terms of cation hydration as the mechanism, allowing a spatial cation arrangement enabling the formation of pores. Under water deficient conditions, the entropic penalty of cation hydration in the solid is large and cations need to be entirely coordinated by framework oxygens, leading to dense, anhydrous networks. Hence, the water activity in the synthesis medium and the affinity of a cation to either coordinate to water or to aluminosilicate decides whether a porous, hydrated, or a dense, anhydrous framework is formed., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published

2023

43. Absolute Quantification of Residual Solvent in Mesoporous Silica Drug Formulations Using Magic-Angle Spinning NMR Spectroscopy.

Author

Vanderschaeghe H, Houlleberghs M, Verheyden L, Dom D, Chandran CV, Radhakrishnan S, Martens JA, and Breynaert E

Abstract

Porous silica is used as a drug delivery agent to improve the bioavailability of sparsely soluble compounds. In this approach, the active pharmaceutical ingredient (API) is commonly loaded into the porous silica by incipient wetness impregnation using organic solvents. Subsequent solvent elimination is critical as the residual solvent concentration cannot exceed threshold values set by health and safety regulations (e.g., EMA/CHMP/ICH/82260/2006). For dichloromethane and methanol, for example, residual concentrations must be below 600 and 3000 ppm, respectively. Today, EU and USA Pharmacopoeias recommend tedious procedures for residual solvent quantification, requiring extraction of the solvent and subsequent quantification using capillary gas chromatography with static headspace sampling (sHS-GC). This work presents a new method based on the combination of standard addition and absolute quantification using magic-angle spinning nuclear magnetic resonance spectroscopy (MAS qNMR). The methodology was originally developed for absolute quantification of water in zeolites and has now been validated for quantification of residual solvent in drug formations using mesoporous silica loaded with ibuprofen dissolved in DCM and MeOH as test samples. Interestingly, formulations prepared using as-received or predried mesoporous silica contained 5465 versus 484.9 ppm DCM, respectively. This implies that the initial water content of the silica carrier can impact the residual solvent concentration in drug-loaded materials. This observation could provide new options to minimize the occurrence of these undesired solvents in the final formulation.

Published

2022

44. Structural Aspects Affecting Phase Selection in Inorganic Zeolite Synthesis.

Author

Asselman K, Vandenabeele D, Pellens N, Doppelhammer N, Kirschhock CEA, and Breynaert E

Abstract

A guideline for zeolite phase selection in inorganic synthesis media is proposed, based on a systematic exploration of synthesis from inorganic media using liquid Na + , K + , and Cs + aluminosilicate. Although the Si/Al ratio of the zeolites is a continuous function of the synthesis conditions, boundaries between topologies are sharp. The here-derived phase selection criterion relates the obtained zeolite topology to the Si/Al ratio imposed by the synthesis medium. For a given Si/Al ratio, the framework with the highest occupation of topologically available cation sites is favored. The large number of published zeolite syntheses supporting the observation provides strong indication that the concept is applicable in a larger context. The proposed criterion explains how minor variations in the composition of inorganic synthesis media induce the commonly occurring, abrupt changes in topology. It highlights underlying reasons causing the strict demarcation of stability fields of the as-synthesized zeolites experimentally observed in inorganic synthesis., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

45. How Water and Ion Mobility Affect the NMR Fingerprints of the Hydrated JBW Zeolite: A Combined Computational-Experimental Investigation.

Author

Vanlommel S, Hoffman AEJ, Smet S, Radhakrishnan S, Asselman K, Chandran CV, Breynaert E, Kirschhock CEA, Martens JA, and Van Speybroeck V

Abstract

An important aspect within zeolite synthesis is to make fully tunable framework materials with controlled aluminium distribution. A major challenge in characterising these zeolites at operating conditions is the presence of water. In this work, we investigate the effect of hydration on the 27 Al NMR parameters of the ultracrystalline K,Na-compensated aluminosilicate JBW zeolite using experimental and computational techniques. The JBW framework, with Si/Al ratio of 1, is an ideal benchmark system as a stepping stone towards more complicated zeolites. The presence and mobility of water and extraframework species directly affect NMR fingerprints. Excellent agreement between theoretical and experimental spectra is obtained provided dynamic methods are employed with hydrated structural models. This work shows how NMR is instrumental in characterising aluminium distributions in zeolites at operating conditions., (© 2022 The Authors. Chemistry - A European Journal published by Wiley-VCH GmbH.)

Published

2022

46. Hydrogen-Bonded Water-Aminium Assemblies for Synthesis of Zeotypes with Ordered Heteroatoms.

Author

Park SH, Radhakrishnan S, Choi W, Chandran CV, Kemp KC, Breynaert E, Bell RG, Kirschhock CEA, and Hong SB

Subjects

Hydrogen, Phosphates chemistry, Solvents, Water, Zeolites chemistry

Abstract

Water plays a central role in the crystallization of a variety of organic, inorganic, biological, and hybrid materials. This is also true for zeolites and zeolite-like materials, an important class of industrial catalysts and adsorbents. Water is always present during their hydrothermal synthesis, either with or without organic species as structure-directing agents. Apart from its role as a solvent or a catalyst, structure direction by water in zeolite synthesis has never been clearly elucidated. Here, we report the crystallization of phosphate-based molecular sieves using rationally designed, hydrogen-bonded water-aminium assemblies, resulting in molecular sieves exhibiting the crystallographic ordering of heteroatoms. We demonstrate that a 1:1 assembly of water and diprotonated N , N -dimethyl-1,2-ethanediamine acts as a structure-directing agent in the synthesis of a silicoaluminophosphate material with phillipsite (PHI) topology, using SMARTER crystallography, which combines single-crystal X-ray diffraction and nuclear magnetic resonance spectroscopy, as well as ab initio molecular dynamics simulations. The molecular arrangement of the hydrogen-bonded assembly matches well with the shape and size of subunits in the PHI structure, and their charge distributions result in the strict ordering of framework tetrahedral atoms. This concept of structure direction by water-containing supramolecular assemblies should be applicable to the synthesis of many classes of porous materials.

Published

2022

47. Hydration of Wheat Flour Water-Unextractable Cell Wall Material Enables Structural Analysis of Its Arabinoxylan by High-Resolution Solid-State 13 C MAS NMR Spectroscopy.

Author

De Man WL, Chandran CV, Wouters AGB, Radhakrishnan S, Martens JA, Breynaert E, and Delcour JA

Subjects

Arabinose analysis, Cell Wall chemistry, Magnetic Resonance Spectroscopy, Water chemistry, Xylans chemistry, Xylose, Flour analysis, Triticum chemistry

Abstract

To enable its structural characterization by nuclear magnetic resonance (NMR) spectroscopy, the native structure of cereal water-unextractable arabinoxylan (WU-AX) is typically disrupted by alkali or enzymatic treatments. Here, WU-AX in the wheat flour unextractable cell wall material (UCWM) containing 40.9% ± 1.5 arabinoxylan with an arabinose-to-xylose ratio of 0.62 ± 0.04 was characterized by high-resolution solid-state NMR without disrupting its native structure. Hydration of the UCWM (1.7 mg H 2 O/mg UCWM) in combination with specific optimizations in the NMR methodology enabled analysis by solid-state 13 C NMR with magic angle spinning and 1 H high-power decoupling ( 13 C HPDEC MAS NMR) which provided sufficiently high resolution to allow for carbon atom assignments. Spectral resonances of C -1 from arabinose and xylose residues of WU-AX were here assigned to the solid state. The proportions of un-, mono-, and di-substituted xyloses were 59.2, 19.5, and 21.2%, respectively. 13 C HPDEC MAS NMR showed the presence of solid-state fractions with different mobilities in the UCWM. This study presents the first solid-state NMR spectrum of wheat WU-AX with sufficient resolution to enable assignment without prior WU-AX solubilization.

Published

2022

48. HSIL-Based Synthesis of Ultracrystalline K,Na-JBW, a Zeolite Exhibiting Exceptional Framework Ordering and Flexibility.

Author

Asselman K, Radhakrishnan S, Pellens N, Chandran CV, Houlleberghs M, Xu Y, Martens JA, Sree SP, Kirschhock CEA, and Breynaert E

Abstract

A reproducible synthesis strategy for ultracrystalline K,Na-aluminosilicate JBW zeolite is reported. The synthesis uses a Na-based hydrated silicate ionic liquid (HSIL) as a silicon source and gibbsite as the aluminum source. 27 Al and 23 Na NMR spectra exhibit crystalline second-order quadrupole patterns in the hydrated as well as dehydrated states and distinct resonances for different T-sites demonstrating an exceptional degree of order of the elements of the JBW framework, observed for the first time in a zeolite. Detailed structural analysis via NMR crystallography, combining powder X-ray diffraction and solid-state NMR of all elements ( 27 Al, 29 Si, 23 Na, 39 K, and 1 H), reveals remarkable de- and rehydration behavior of the JBW framework, transforming from its as-made hydrated structure via a modified anhydrous state into a different rehydrated symmetry while showing astonishing flexibility for a semicondensed aluminosilicate. Its crystallinity, exceptional degree of ordering of the T atoms and sodium cations, and the fully documented structure qualify this defect-free K,Na-aluminosilicate JBW zeolite as a suitable model system for developing NMR modeling methods., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

49. Nucleation of Porous Crystals from Ion-Paired Prenucleation Clusters.

Author

Pellens N, Doppelhammer N, Radhakrishnan S, Asselman K, Chandran CV, Vandenabeele D, Jakoby B, Martens JA, Taulelle F, Reichel EK, Breynaert E, and Kirschhock CEA

Abstract

Current nucleation models propose manifold options for the formation of crystalline materials. Exploring and distinguishing between different crystallization pathways on the molecular level however remain a challenge, especially for complex porous materials. These usually consist of large unit cells with an ordered framework and pore components and often nucleate in complex, multiphasic synthesis media, restricting in-depth characterization. This work shows how aluminosilicate speciation during crystallization can be documented in detail in monophasic hydrated silicate ionic liquids (HSILs). The observations reveal that zeolites can form via supramolecular organization of ion-paired prenucleation clusters, consisting of aluminosilicate anions, ion-paired to alkali cations, and imply that zeolite crystallization from HSILs can be described within the spectrum of modern nucleation theory., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

50. Ion-Pairs in Aluminosilicate-Alkali Synthesis Liquids Determine the Aluminum Content and Topology of Crystallizing Zeolites.

Author

Asselman K, Pellens N, Thijs B, Doppelhammer N, Haouas M, Taulelle F, Martens JA, Breynaert E, and Kirschhock CEA

Abstract

Using hydrated silicate ionic liquids, phase selection and framework silicon-to-aluminum ratio during inorganic zeolite synthesis were studied as a function of batch composition. Consisting of homogeneous single phasic liquids, this synthesis concept allows careful control of crystallization parameters and evaluation of yield and sample homogeneity. Ternary phase diagrams were constructed for syntheses at 90 °C for 1 week. The results reveal a cation-dependent continuous relation between batch stoichiometry and framework aluminum content, valid across the phase boundaries of all different zeolites formed in the system. The framework aluminum content directly correlates to the type of alkali cation and gradually changes with batch alkalinity and dilution. This suggests that the observed zeolites form through a solution-mediated mechanism involving the concerted assembly of soluble cation-oligomer ion pairs. Phase selection is a consequence of the stability for a particular framework at the given aluminum content and alkali type., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022