Exploring Synthetic Strategies for Nanocrystal/Reticular Framework Hybrids and Their Potential as CO2 Reduction Electrocatalysts

Yannick Thomas Guntern
EPFL, 2021
EPFL thesis

Abstract

The electrochemical CO2 reduction reaction (CO2RR) into valuable chemicals has the potential to realize a carbon-neutral energy cycle. Developing catalysts that can achieve high selectivity towards one of the possible reduction products is one of the biggest challenges in this field. Catalysts possessing one single type of active sites cannot fulfil this need, yet to establish design rules for bifunctional catalysts is not trivial. To have material platforms which allow to study the sensitivity of the catalytic behaviour to structural and compositional features of the catalyst is of the uttermost importance to inform catalyst design. This thesis aims at combining well-defined colloidal nanocrystals (NCs) and porous reticular frameworks as hybrid materials to explore their synergistic interactions as CO2RR catalysts. These classes of materials were chosen because they possess complementary chemical properties which are appealing towards eventually construct an ideal catalyst with high performance. However, one of the challenges is to obtain these hybrids with tunable structural features in an unrestricted compositional range. The overall objective is to design and explore synthetic strategies for the formation of new multifunctional composites consisting of colloidal NCs and metal-organic/covalent organic frameworks (MOFs/COFs). First, a synthetic approach for the formation of NC/MOF hybrid thin films is proposed, which enables their application as a novel catalytic platform for CO2RR. We demonstrate that a combination of colloidal chemistry, atomic-layer deposition and solvothermal synthesis allows to form an intimate contact between Ag NCs and an Al-PMOF matrix. Our tuneable Ag@Al-PMOF hybrid catalysts show promoted CO2RR which is attributed to electronic changes in the Ag NC surface and minor mass-transport effects. Moreover, the hybrids improve the morphological stability of the Ag NCs under CO2RR conditions. We show that the synthetic approach can be further extended to form hybrids with other metallic NCs, thereby representing a new tool for the preparation of composite catalysts for CO2RR. One of the limitations of thin film composites is that synthesis conditions might need to be adapted for different substrates. To prepare hybrid materials in the form of dispensible colloidal solutions is highly appealing and better suited for mechanistic studies. The latter are important because understanding the chemistry driving the formation of such composites is eventually the key for achieving compositional and structural tunability. In the second part, we introduce a new strategy to encapsulate various colloidal NCs in the imine-linked COF LZU1. The synthetic approach allows us to tune the shell thickness and crystallization of the COF in the presence of the NCs. After understanding the nucleation and growth mechanisms of the hybrids, we extend the developed synthesis to obtain multi-layered structures with controlled spatial distribution of various NCs with different compositions. Altogether, we demonstrate that our approach can be applied to prepare hybrids with new functionalities that derive from the encapsulated NCs. Overall, this thesis proposes two different approaches which combine colloidal and reticular chemistry to synthesize tunable material platforms which might aid the design of CO2RR catalysts as well as contributing to other applications which require multifunctional porous materials.

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https://infoscience.epfl.ch/record/288395?ln=en

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Yannick Thomas Guntern
EPFL, 2021
EPFL thesis

Abstract

Official source

https://infoscience.epfl.ch/record/288395?ln=en

About this result

Related concepts (27)

Related concepts

Related publications (121)

Related publications

Related publications (121)

Cu/Metal Oxide Hybrid Nanocrystals as Electrocatalysts for the CO2 Reduction Reaction

Seyedehbehnaz Varandili

The electrochemical CO2 reduction reaction (CO2RR) is envisioned to play a significant role in achieving carbon neutrality while contributing to storing renewable energies. Cu-based materials are among the most promising electrocatalysts. However, 16 different products are obtained from a Cu foil, therefore strategies to make more selective catalysts are needed. This thesis explores Cu/metal oxide interfaces as a mean to direct selectivity towards hydrocarbon products in CO2RR. The aim is to deviate from the scaling relationships which exist on single metal surfaces. Cu/metal oxides hybrid nanocrystals (HNCs) with tunable morphologies and spatial configuration are synthesized via colloidal chemistry. The achieved level of control and tunability is demonstrated to be crucial in understanding the impact of these parameters on the reaction outcome. First, we start by designing a synthesis procedure for Cu/CeO2-x heterodimers (HDs) and then we study their catalytic behavior toward CO2RR. We show that the Cu/CeO2-x interface promotes CO2RR, particularly methane with around 54% selectivity, which is ~5 times higher than those obtained with a physical mixture of isolated Cu and CeO2-x nanocrystals, thus highlighting the important role played by the intimate bonding at the interface. A miscellanea of characterization techniques indicates the higher extent of ceria reduction in the HDs during CO2RR. DFT elucidates the presence of unique catalytic motifs that enable bidentate adsorption of critical intermediates at both Cu and the CeO2-xO-vacancy site, creating an opportunity for reaction engineering beyond scaling relationship limitations. Having assessed the importance of the Cu/ceria interface, we investigate the impact of increasing the Cu/CeO2 interfacial area on the CO2RR outcome. We find that increasing the number of ceria domain around copper inhibits CO2RR. This result highlights that a balance between interfacial area and accessibility to the active catalytic sites must be sought after to exploit synergies arising at the interface between different domains. Finally, we explore Cu/ZnO HNCs as CO2RR pre-catalysts to elucidate the structural and compositional parameters which direct the reaction pathway towards ethanol. Using different sizes of ZnO seeds for the synthesis of Cu/ZnO HNCs, we are able to achieve two different configurations including ZnO decorated Cu core (Cu@ZnO) and Cu decorated ZnO core (ZnO@Cu) HNCs. Upon activation via cathodic voltage, we find that Cu@ZnO HNCs favor methane production while ZnO@Cu exhibits a noticeable selectivity toward ethanol. Operando XAS, XPS, and electron microscopy reveal that both HNCs transform into Cu@CuZn core@shell NCs during the activation step. However, the Zn content in the surface alloy (i.e. degree of alloying) and the presence of surface cationic Zn species are found to be crucial in determining the selectivity of these catalysts, which possibly elucidates some of the contrasting results reported on Cu-Zn across the literature. Overall, this thesis showcases the importance of well-defined and tunable HNCs as platforms to study structure/properties relations and to advance the current knowledge in CO2RR. Furthermore, the library of nanomaterials accessible through the developed synthesis routes might also be utilized in the future to investigate other catalytic reactions and applications where the hybrid interfaces might be relevant.

EPFL2021

Solution behavior of peptide and peptide-hybrid materials

Harald Nuhn

Peptide based and peptide hybrid materials represent two interesting and challenging classes of biomaterials. Both classes consist of and contain, respectively, one or more polypeptide blocks, endowing the resulting polymers with enhanced self-assembly properties, biocompatibility or novel characteristics. Peptide based materials, solely comprised of amino acids, benefit from their advanced self-assembly properties. In the case of peptide hybrid materials, being conjugates of peptides and synthetic polymers, either the polypeptide or the synthetic polymer block can drive the self-assembly process. Furthermore, the latter class benefits from combining the advantages of peptides and synthetic polymers, thus overcoming limitations related to the use of the individual components. The application of these materials is still challenging because it is not possible to predict their final self-assembly behavior based on their design. In order to facilitate a target-oriented design of novel materials for application such as drug delivery, tissue engineering, or self-healing materials, a detailed understanding of the complex interactions within and between these molecules is essential. The work presented in this thesis addresses these fundamental questions. Over the last decades, a plethora of peptide and peptide hybrid materials has been reported. Chapter 1 gives an overview of selected articles describing different synthesis routes for peptide as well as peptide hybrid materials, showing examples of molecules and their self-assembly into superstructures, and highlighting recent applications. Chapter 2 describes the synthesis and characterization of different peptide hybrid diblock oligomers composed of two classes of peptide sequences covalently attached to a poly(ethylene glycol) (PEG) block. The first class of peptide sequences contains the intrinsic propensity to form coiled coils, whereas the second class is composed of "switch" peptides and is able to adopt both amphiphilic α-helical and β-strand conformations. Upon dissolution, the first class yielded superstructures comprised of dimeric and tetrameric coiled coil aggregates, whereas the second class formed fibrillar assemblies. In both cases, the self-assembly properties were driven by the peptide block, and the final superstructure consisted of a peptidic core wrapped by the synthetic polymer block. Chapter 3 presents a detailed study on the aqueous solution self-assembly of two poly(styrene)n-b-poly(L-lysine)m peptide hybrid oligomers. The aim was to clarify whether the observed rod-like micelles, obtained by direct dissolution of the diblock oligomers in aqueous solution, reflect intrinsic self-assembly properties of the hybrid diblock oligomers or whether they present structures that are energetically trapped due to the glassy nature of the polystyrene block. To address this question, the influence of a variety of sample preparation techniques, including the use of organic solvents, dialysis from an organic solvent and several thermal treatments, was investigated. All treatments resulted in solution aggregates that differed in size and shape from samples prepared by direct dissolution in aqueous solution. Thus, it seems likely that direct dissolution of polystyrene-b-poly(L-lysine) diblock oligomers in aqueous solution results in kinetically trapped, rod-like aggregates, which can be transformed into non-spherical micelles by the appropriate treatment. Chapter 4 contains a comprehensive study on peptide-based materials, investigating four different series of short elastin-like peptides (ELPs) based on the GVGVP motif. The objective was to test whether and how defined changes in the primary structure of short ELPs affect the secondary structure and the lower critical solution temperature (LCST) behavior. Therefore, the number of repeats was altered, and within one peptide of constant length, all valines were successively substituted by the more hydrophobic amino acids isoleucine, leucine and phenylalanine, respectively. In parallel, a theoretical approach based on the partition coefficient log P was used to predict the shift of the LCST as function of chain length and composition. For short ELPs, the LCST is strongly affected by changes in the primary structure. This has also been predicted by calculating log P. An increase in the hydrophobicity resulted in a shift of the LCST towards lower temperatures. Furthermore, it was shown for the first time that the sensitivity of short ELPs towards external factors, such as salt concentration, is determined by the intrinsic propensity of the incorporated amino acids to form either α-helices or β-strands. In summary, the obtained results on peptide based and peptide-hybrid materials provides deeper insights into their self-assembly characteristics and highlights the potential of these materials to be used for technical and medical applications.

EPFL2008

This thesis deals with the electrocatalytic properties of two-dimensional metal organic coordination networks (2D-MOCNs) self-assembled on electrode surfaces and catalytic activity of 2D-MOCNs is demonstrated for the first time. The low-coordinated metal centers within these supramolecular structures resemble the catalytically active sites of metallo-enzymes. The activity of the metal centers is determined by the type of the metal and the coordination environment; both parameters can be carefully adjusted in 2D-MOCNs. In order to study and correlate electrocatalytic properties with the atomic structure of 2D-MOCNs, a scanning tunnelling microscope operating in ultra-high vacuum (UHV) was combined with an electrochemical (EC) setup. Sample preparation and scanning tunneling microscopy (STM) were conducted under UHV conditions. By STM the composition and structure of the networks were controlled and characterized prior to EC experiments. A transfer system between UHV and EC instrumentation was constructed to keep the sample at all times in a clean and controlled environment. It is demonstrated that the mechanism of the oxygen reduction reaction (ORR) can be influenced by the type of the metal center in the network. The networks formed by benzene-tricarboxylic acid (TMA) with either Fe or Mn atoms are structurally identical, but their electrochemical signal differs significantly. Both networks catalyze the reduction of O2 to H2O, but on different pathways. These results emphasize the key role of the unsaturated metal centers in the electrocatalytic reduction. The electrocatalytic response in the ORR can also altered by the distinct coordination environment; this is shown for Fe atoms nitrogen-coordinated by either tetracyanoquinodimethane (TCNQ), bis-pyridyl-bipyrimidine (PBP) or phythalocyanine (Pc). Depending on the specific coordination environment formed by the different ligands the the final product (H2O2 or H2O) and the mechanism of the ORR is changed. In the last part of this thesis the two metal binding sites of 5,10,15,20-tetra(4-pyridyl)porphyrin (TPyP) are used to selectively incorporate different metal centers in a fixed organic environment and create homo- and hetero-bimetallic networks. The coupling of the two metals centers promoted by the organic environment modifies the electrocatalytic response. The correct combination of two metal centers in the right positioning makes an efficient catalyst. In the ORR the peak and onset potential is varied depending on the metal combination. In the case of the oxygen evolution reaction a non-linearly increased catalytic activity by the cooperative bimetallic effect is obtained. The results presented in this thesis demonstrate the high potential of 2D-MOCNs for heterogeneous catalytic chemical conversions. Engineering of the network structure and the distinct coordination environment of the metal centers offers the possibility to tune their catalytic activity. This opens up a new route for the design of a new class of nanocatalyst materials.

EPFL2015