Your search keyword '"Thomsen, Maria S."' showing total 7 results

1. Formation of intermetallic PdIn nanoparticles: influence of surfactants on nanoparticle atomic structure

Author

Wang, Baiyu, Mathiesen, Jette K., Kirsch, Andrea, Schlegel, Nicolas, Anker, Andy S., Johansen, Frederik L., Kjær, Emil T.S., Aalling-Frederiksen, Olivia, Nielsen, Tobias M., Thomsen, Maria S., Jakobsen, Rasmus K., Arenz, Matthias, Jensen, Kirsten M.Ø., Wang, Baiyu, Mathiesen, Jette K., Kirsch, Andrea, Schlegel, Nicolas, Anker, Andy S., Johansen, Frederik L., Kjær, Emil T.S., Aalling-Frederiksen, Olivia, Nielsen, Tobias M., Thomsen, Maria S., Jakobsen, Rasmus K., Arenz, Matthias, and Jensen, Kirsten M.Ø.

Abstract

Bimetallic nanoparticles have been extensively studied as electrocatalysts due to their superior catalytic activity and selectivity compared to their monometallic counterparts. The properties of bimetallic materials depend on the ordering of the metals in the structure, and to tailor-make materials for specific applications, it is important to be able to control the atomic structure of the materials during synthesis. Here, we study the formation of bimetallic palladium indium nanoparticles to understand how the synthesis parameters and additives used influence the atomic structure of the obtained product. Specifically, we investigate a colloidal synthesis, where oleylamine was used as the main solvent while the effect of two surfactants, oleic acid (OA) and trioctylphosphine (TOP) was studied. We found that without TOP included in the synthesis, a Pd-rich intermetallic phase with the Pd3In structure initially formed, which transformed into large NPs of the CsCl-structured PdIn phase. When TOP was included, the syntheses yielded both In2O3 and Pd3In. In situ X-ray total scattering with Pair Distribution Function analysis was used to study the formation process of PdIn bimetallic NPs. Our results highlight how seemingly subtle changes to material synthesis methods can have a large influence on the product atomic structure.

Published

2023

2. Formation of intermetallic PdIn nanoparticles:influence of surfactants on nanoparticle atomic structure

Author

Wang, Baiyu, Mathiesen, Jette K., Kirsch, Andrea, Schlegel, Nicolas, Anker, Andy S., Johansen, Frederik L., Kjær, Emil T.S., Aalling-Frederiksen, Olivia, Nielsen, Tobias M., Thomsen, Maria S., Jakobsen, Rasmus K., Arenz, Matthias, Jensen, Kirsten M.Ø., Wang, Baiyu, Mathiesen, Jette K., Kirsch, Andrea, Schlegel, Nicolas, Anker, Andy S., Johansen, Frederik L., Kjær, Emil T.S., Aalling-Frederiksen, Olivia, Nielsen, Tobias M., Thomsen, Maria S., Jakobsen, Rasmus K., Arenz, Matthias, and Jensen, Kirsten M.Ø.

Abstract

Bimetallic nanoparticles have been extensively studied as electrocatalysts due to their superior catalytic activity and selectivity compared to their monometallic counterparts. The properties of bimetallic materials depend on the ordering of the metals in the structure, and to tailor-make materials for specific applications, it is important to be able to control the atomic structure of the materials during synthesis. Here, we study the formation of bimetallic palladium indium nanoparticles to understand how the synthesis parameters and additives used influence the atomic structure of the obtained product. Specifically, we investigate a colloidal synthesis, where oleylamine was used as the main solvent while the effect of two surfactants, oleic acid (OA) and trioctylphosphine (TOP) was studied. We found that without TOP included in the synthesis, a Pd-rich intermetallic phase with the Pd3In structure initially formed, which transformed into large NPs of the CsCl-structured PdIn phase. When TOP was included, the syntheses yielded both In2O3 and Pd3In. In situ X-ray total scattering with Pair Distribution Function analysis was used to study the formation process of PdIn bimetallic NPs. Our results highlight how seemingly subtle changes to material synthesis methods can have a large influence on the product atomic structure.

Published

2023

3. Formation of intermetallic PdIn nanoparticles:influence of surfactants on nanoparticle atomic structure

Author

Wang, Baiyu, Mathiesen, Jette K., Kirsch, Andrea, Schlegel, Nicolas, Anker, Andy S., Johansen, Frederik L., Kjær, Emil T.S., Aalling-Frederiksen, Olivia, Nielsen, Tobias M., Thomsen, Maria S., Jakobsen, Rasmus K., Arenz, Matthias, Jensen, Kirsten M.Ø., Wang, Baiyu, Mathiesen, Jette K., Kirsch, Andrea, Schlegel, Nicolas, Anker, Andy S., Johansen, Frederik L., Kjær, Emil T.S., Aalling-Frederiksen, Olivia, Nielsen, Tobias M., Thomsen, Maria S., Jakobsen, Rasmus K., Arenz, Matthias, and Jensen, Kirsten M.Ø.

Abstract

Bimetallic nanoparticles have been extensively studied as electrocatalysts due to their superior catalytic activity and selectivity compared to their monometallic counterparts. The properties of bimetallic materials depend on the ordering of the metals in the structure, and to tailor-make materials for specific applications, it is important to be able to control the atomic structure of the materials during synthesis. Here, we study the formation of bimetallic palladium indium nanoparticles to understand how the synthesis parameters and additives used influence the atomic structure of the obtained product. Specifically, we investigate a colloidal synthesis, where oleylamine was used as the main solvent while the effect of two surfactants, oleic acid (OA) and trioctylphosphine (TOP) was studied. We found that without TOP included in the synthesis, a Pd-rich intermetallic phase with the Pd3In structure initially formed, which transformed into large NPs of the CsCl-structured PdIn phase. When TOP was included, the syntheses yielded both In2O3 and Pd3In. In situ X-ray total scattering with Pair Distribution Function analysis was used to study the formation process of PdIn bimetallic NPs. Our results highlight how seemingly subtle changes to material synthesis methods can have a large influence on the product atomic structure.

Published

2023

4. Seven Europium(III) Complexes in Solution - the Importance of Reporting Data When Investigating Luminescence Spectra and Electronic Structure

Author

Thomsen, Maria S., Nawrocki, Patrick R., Kofod, Nicolaj, Sorensen, Thomas J., Thomsen, Maria S., Nawrocki, Patrick R., Kofod, Nicolaj, and Sorensen, Thomas J.

Abstract

Despite significant effort, the complexity of europium(III) luminescence in general-and sample composition in particular-has precluded the publication of standard spectra of specific complexes in aqueous solution. Further, low spectral resolution, weighted averages with contributions from several species, as well as poor reproduction hampers the use of literature data, with the note that high quality data from e. g. Bunzli, Latva, Carnall, Parker, Heller, Balzani and Sabatini is from the pre-electronic era. Here, luminescence spectra of Eu.DOTA, Eu.EDTA, Eu.DPA(1), Eu.DPA(2). Eu.DPA(3), Eu.DTPA and the Eu(III) aqua ion was determined in samples with known pH and conductivity. The ligand concentrations were varied in a buffered medium (MES) with a significant salt background. In this manner, full complexation could be ensured, while pH and ionic strength were monitored. The spectra corresponding to the complexes were extracted, and the electronic structure of the ground state F-7(J) manifold was investigated and contrasted to literature data. All spectroscopic data is made available and we suggest this becomes part of the standard procedure when investigating lanthanide(III) complexes.

Published

2022

5. Breaking with the Principles of Coreduction to Form Stoichiometric Intermetallic PdCu Nanoparticles

Author

Mathiesen, Jette K., Bøjesen, Espen D., Pedersen, Jack K., Kjær, Emil T.S., Juelsholt, Mikkel, Cooper, Susan, Quinson, Jonathan, Anker, Andy S., Cutts, Geoff, Keeble, Dean S., Thomsen, Maria S., Rossmeisl, Jan, Jensen, Kirsten M.Ø., Mathiesen, Jette K., Bøjesen, Espen D., Pedersen, Jack K., Kjær, Emil T.S., Juelsholt, Mikkel, Cooper, Susan, Quinson, Jonathan, Anker, Andy S., Cutts, Geoff, Keeble, Dean S., Thomsen, Maria S., Rossmeisl, Jan, and Jensen, Kirsten M.Ø.

Abstract

Intermetallic nanoparticles (NPs) have shown enhanced catalytic properties as compared to their disordered alloy counterparts. To advance their use in green energy, it is crucial to understand what controls the formation of intermetallic NPs over alloy structures. By carefully selecting the additives used in NP synthesis, it is here shown that monodisperse, intermetallic PdCu NPs can be synthesized in a controllable manner. Introducing the additives iron(III) chloride and ascorbic acid, both morphological and structural control can be achieved. Combined, these additives provide a synergetic effect resulting in precursor reduction and defect-free growth; ultimately leading to monodisperse, single-crystalline, intermetallic PdCu NPs. Using in situ X-ray total scattering, a hitherto unknown transformation pathway is reported that diverges from the commonly reported coreduction disorder–order transformation. A Cu-rich structure initially forms, which upon the incorporation of Pd(0) and atomic ordering forms intermetallic PdCu NPs. These findings underpin that formation of stoichiometric intermetallic NPs is not limited by standard reduction potential matching and coreduction mechanisms, but is instead driven by changes in the local chemistry. Ultimately, using the local chemistry as a handle to tune the NP structure might open new opportunities to expand the library of intermetallic NPs by exploiting synthesis by design.

Published

2022

6. Breaking with the Principles of Coreduction to Form Stoichiometric Intermetallic PdCu Nanoparticles

Author

Mathiesen, Jette K., Bøjesen, Espen D., Pedersen, Jack K., Kjær, Emil T.S., Juelsholt, Mikkel, Cooper, Susan, Quinson, Jonathan, Anker, Andy S., Cutts, Geoff, Keeble, Dean S., Thomsen, Maria S., Rossmeisl, Jan, Jensen, Kirsten M.Ø., Mathiesen, Jette K., Bøjesen, Espen D., Pedersen, Jack K., Kjær, Emil T.S., Juelsholt, Mikkel, Cooper, Susan, Quinson, Jonathan, Anker, Andy S., Cutts, Geoff, Keeble, Dean S., Thomsen, Maria S., Rossmeisl, Jan, and Jensen, Kirsten M.Ø.

Abstract

Intermetallic nanoparticles (NPs) have shown enhanced catalytic properties as compared to their disordered alloy counterparts. To advance their use in green energy, it is crucial to understand what controls the formation of intermetallic NPs over alloy structures. By carefully selecting the additives used in NP synthesis, it is here shown that monodisperse, intermetallic PdCu NPs can be synthesized in a controllable manner. Introducing the additives iron(III) chloride and ascorbic acid, both morphological and structural control can be achieved. Combined, these additives provide a synergetic effect resulting in precursor reduction and defect-free growth; ultimately leading to monodisperse, single-crystalline, intermetallic PdCu NPs. Using in situ X-ray total scattering, a hitherto unknown transformation pathway is reported that diverges from the commonly reported coreduction disorder–order transformation. A Cu-rich structure initially forms, which upon the incorporation of Pd(0) and atomic ordering forms intermetallic PdCu NPs. These findings underpin that formation of stoichiometric intermetallic NPs is not limited by standard reduction potential matching and coreduction mechanisms, but is instead driven by changes in the local chemistry. Ultimately, using the local chemistry as a handle to tune the NP structure might open new opportunities to expand the library of intermetallic NPs by exploiting synthesis by design.

Published

2022

7. Seven Europium(III) Complexes in Solution - the Importance of Reporting Data When Investigating Luminescence Spectra and Electronic Structure

Author

Thomsen, Maria S., Nawrocki, Patrick R., Kofod, Nicolaj, Sorensen, Thomas J., Thomsen, Maria S., Nawrocki, Patrick R., Kofod, Nicolaj, and Sorensen, Thomas J.

Abstract

Despite significant effort, the complexity of europium(III) luminescence in general-and sample composition in particular-has precluded the publication of standard spectra of specific complexes in aqueous solution. Further, low spectral resolution, weighted averages with contributions from several species, as well as poor reproduction hampers the use of literature data, with the note that high quality data from e. g. Bunzli, Latva, Carnall, Parker, Heller, Balzani and Sabatini is from the pre-electronic era. Here, luminescence spectra of Eu.DOTA, Eu.EDTA, Eu.DPA(1), Eu.DPA(2). Eu.DPA(3), Eu.DTPA and the Eu(III) aqua ion was determined in samples with known pH and conductivity. The ligand concentrations were varied in a buffered medium (MES) with a significant salt background. In this manner, full complexation could be ensured, while pH and ionic strength were monitored. The spectra corresponding to the complexes were extracted, and the electronic structure of the ground state F-7(J) manifold was investigated and contrasted to literature data. All spectroscopic data is made available and we suggest this becomes part of the standard procedure when investigating lanthanide(III) complexes.

Published

2022