Your search keyword '"Triana C"' showing total 5 results

1. Molecular and heterogeneous water oxidation catalysts: recent progress and joint perspectives.

Author

Li, J., Triana, C. A., Wan, W., Adiyeri Saseendran, D. P., Zhao, Y., Balaghi, S. E., Heidari, S., and Patzke, G. R.

Subjects

*OXIDATION of water, *CATALYSTS, *ARTIFICIAL photosynthesis, *KNOWLEDGE transfer, *TRANSITION metals, *HETEROGENEOUS catalysts

Abstract

The development of reliable water oxidation catalysts (WOCs) is essential for implementing artificial photosynthesis on a large technological scale. WOC research has evolved into two major branches, namely molecular and heterogeneous catalysts. Manifold design principles and plenty of mechanistic insights have been developed in these individual fields after decades of investigations. Over the past years, a growing need for knowledge transfer between both sides has emerged in order to expedite the development and optimization of next-generation WOCs. In this review, we first provide selected recent highlights in the area of molecular WOCs with different nuclearities, together with current mechanistic insight. WOCs offering molecular integrity under operational conditions are ideal platforms for elucidating reaction mechanisms and well-defined structure–function correlations at the atomic level. Next, recent mechanistic advances and design strategies for heterogeneous WOCs are illustrated for representative examples, together with a discussion of their inherent limitations in mechanistic studies. Finally, illustrative cases of knowledge transfer between molecular and heterogeneous WOCs are discussed to highlight the advantages of combining the best of both catalyst types. For the sake of conciseness, this review focuses primarily on WOCs based on the first-row transition metals, which are attracting increasing attention for both fundamental studies and economic applications. [ABSTRACT FROM AUTHOR]

Published

2021

2. Pathways towards true catalysts: computational modelling and structural transformations of Zn-polyoxotungstates.

Author

Ni, Lubin, Güttinger, Robin, Triana, C. A., Spingler, Bernhard, Baldridge, Kim K., and Patzke, Greta R.

Subjects

ALCOHOL oxidation, CATALYSTS, STRUCTURE-activity relationships, CATALYTIC oxidation, ATOMIC structure, TUNGSTEN

Abstract

Current catalysis undergoes a paradigm shift from molecular and heterogeneous realms towards new dynamic catalyst concepts. This calls for innovative strategies to understand the essential catalytic motifs and true catalysts emerging from oxidative transformation processes. Polyoxometalate (POM) clusters offer an inexhaustible reservoir for new noble metal-free catalysts and excellent model systems whose structure–activity relationships and mechanisms remain to be explored. Here, we first introduce a new {ZnnNa6−n(B-α-SbW9O33)2} (n = 3–6) catalyst family with remarkable tuning options of the Zn-based core structure and high activity in H2O2-assisted catalytic alcohol oxidation as a representative reaction. Next, high level solution-based computational modelling of the intermediates and transition states was carried out for [Zn6Cl6(SbW9O33)2]12− as a representative well-defined case. The results indicate a radical-based oxidation process with the involvement of tungsten and adjacent zinc metal centers. The {ZnnNa6−n(B-α-SbW9O33)2} series indeed efficiently catalyses alcohol oxidation via peroxotungstate intermediates, in agreement with strong spectroscopic support and other experimental evidence for the radical mechanism. Finally, the high performance of [Zn6Cl6(SbW9O33)2]12− was traced back to its transformation into a highly active and robust disordered Zn/W-POM catalyst. The atomic short-range structure of this resting pre-catalyst was elucidated by RMC modelling of the experimental W-L3 and Zn-K edge EXAFS spectra and supported with further analytical methods. We demonstrate that computational identification of the reactive sites combined with the analytical tracking of their dynamic transformations provides essential input to expedite cluster-based molecular catalyst design. [ABSTRACT FROM AUTHOR]

Published

2019

3. Monitoring surface transformations of metal carbodiimide water oxidation catalysts by operando XAS and Raman spectroscopy.

Author

Müller, Rafael J., Lan, Jinggang, Lienau, Karla, Moré, René, Triana, C. A., Iannuzzi, Marcella, and Patzke, Greta R.

Subjects

CARBODIIMIDES, OXIDATION of water, RAMAN spectroscopy

Abstract

Transition metal carbodiimides MNCN (M = Co, Ni, Co0.9Ni0.1, Mn and Cu), were studied by simultaneous operando Raman and X-ray absorption spectroscopy (XAS) with focus on surface oxide detection during electrocatalytic water oxidation. As a proof of concept, easily modifiable screen-printed electrodes were used in this unified operando synchrotron setup for a trade-off between convenience of electrochemical anodization and spectroscopic data acquisition. Monitoring of chemical and structural transformations at the electrode surface during initial anodic electrode polarization shows stability for MNCN with M = Co, Ni, Co0.9Ni0.1 and Mn. While MnNCN is inactive, CoNCN emerges as the most active representative of the series. CuNCN displays pronounced side reactions and the formation of a surface copper oxide layer leading to lower current density attributed to water oxidation, as evident from an irreversible variation of the CuNCN redox behaviour in rotating ring-disc voltammetry. Furthermore, the accompanying structural and vibrational spectroscopy properties of the different MNCN compounds were explored with complementary ex situ analytical methods. [ABSTRACT FROM AUTHOR]

Published

2018

4. Pathways towards true catalysts: computational modelling and structural transformations of Zn-polyoxotungstates.

Author

Ni L, Güttinger R, Triana CA, Spingler B, Baldridge KK, and Patzke GR

Abstract

Current catalysis undergoes a paradigm shift from molecular and heterogeneous realms towards new dynamic catalyst concepts. This calls for innovative strategies to understand the essential catalytic motifs and true catalysts emerging from oxidative transformation processes. Polyoxometalate (POM) clusters offer an inexhaustible reservoir for new noble metal-free catalysts and excellent model systems whose structure-activity relationships and mechanisms remain to be explored. Here, we first introduce a new {Zn n Na 6-n (B-α-SbW 9 O 33 ) 2 } (n = 3-6) catalyst family with remarkable tuning options of the Zn-based core structure and high activity in H 2 O 2 -assisted catalytic alcohol oxidation as a representative reaction. Next, high level solution-based computational modelling of the intermediates and transition states was carried out for [Zn 6 Cl 6 (SbW 9 O 33 ) 2 ] 12- as a representative well-defined case. The results indicate a radical-based oxidation process with the involvement of tungsten and adjacent zinc metal centers. The {Zn n Na 6-n (B-α-SbW 9 O 33 ) 2 } series indeed efficiently catalyses alcohol oxidation via peroxotungstate intermediates, in agreement with strong spectroscopic support and other experimental evidence for the radical mechanism. Finally, the high performance of [Zn 6 Cl 6 (SbW 9 O 33 ) 2 ] 12- was traced back to its transformation into a highly active and robust disordered Zn/W-POM catalyst. The atomic short-range structure of this resting pre-catalyst was elucidated by RMC modelling of the experimental W-L 3 and Zn-K edge EXAFS spectra and supported with further analytical methods. We demonstrate that computational identification of the reactive sites combined with the analytical tracking of their dynamic transformations provides essential input to expedite cluster-based molecular catalyst design.

Published

2019

5. Monitoring surface transformations of metal carbodiimide water oxidation catalysts by operando XAS and Raman spectroscopy.

Author

Müller RJ, Lan J, Lienau K, Moré R, Triana CA, Iannuzzi M, and Patzke GR

Abstract

Transition metal carbodiimides MNCN (M = Co, Ni, Co 0.9 Ni 0.1 , Mn and Cu), were studied by simultaneous operando Raman and X-ray absorption spectroscopy (XAS) with focus on surface oxide detection during electrocatalytic water oxidation. As a proof of concept, easily modifiable screen-printed electrodes were used in this unified operando synchrotron setup for a trade-off between convenience of electrochemical anodization and spectroscopic data acquisition. Monitoring of chemical and structural transformations at the electrode surface during initial anodic electrode polarization shows stability for MNCN with M = Co, Ni, Co 0.9 Ni 0.1 and Mn. While MnNCN is inactive, CoNCN emerges as the most active representative of the series. CuNCN displays pronounced side reactions and the formation of a surface copper oxide layer leading to lower current density attributed to water oxidation, as evident from an irreversible variation of the CuNCN redox behaviour in rotating ring-disc voltammetry. Furthermore, the accompanying structural and vibrational spectroscopy properties of the different MNCN compounds were explored with complementary ex situ analytical methods.

Published

2018