Development of Nanoparticle Catalysts for Plasmonic Photoelectrochemical Reduction of Carbon Dioxide

Morin Caamano, Tatiana I. M.

16 January 2023

The threat of the ongoing climate crisis requires the complete reduction of carbon emissions in the next two to three decades. Carbon dioxide electrochemical reduction (CO₂ER) poses a promising pathway to be able to maintain our current energy infrastructures in a carbon neutral fashion, by allowing the production of fuels and chemicals, such as CO, methanol and ethylene, with the use of carbon capture technologies and green energy. Thus far, Cu is the only metal that has demonstrated the ability to form hydrocarbon products. However, Cu is hindered by low selectivity. Improvements have been observed by coupling Cu with noble metals, such as Ag and Au. However, despite significant advancements, the technology has yet to achieve sufficient performance in activity, stability and selectivity for commercial viability. As such, this work pursued to further advance the activity of CO₂ER through the use of plasmonic Cu-based catalysts and the study of novel dinitrile-based electrolytes. It has recently been identified that CO₂ER can benefit from direct plasmonic effects induced by light illumination. In essence, certain light wavelengths can induce collective oscillations of the free electrons in the metallic particles, leading to an enhancement of their electrocatalytic performance. As such, the first project of this work involved the development and testing of plasmonic Cu-Ag bimetallic catalysts for the application of CO₂ER. Cu, Ag, as well as Cu-Ag bimetallic particles with variable morphologies were able to be synthesized through a facile one-pot sodium borohydride chemical reduction method. The synthesized catalyst performance was also compared to commercial catalysts. The synthesized particles were found to be active catalysts for CO₂ER, with improved electro-catalytic activities exhibited by Cu₈₅Ag₁₅, Cu₆₀Ag₄₀ and Cu syntheses in respective order. All nanoparticles demonstrated increases in the catalytic activity ranging between 15-26% under white light illumination, attributed to plasmonic promotion. The best plasmonic promotion of 26% was observed in the CuAg commercial alloy. Meanwhile, the best promotion of the synthesized bimetallic particles was of 18% found in the Cu₆₀Ag₄₀ catalyst. Additionally, improved electrochemical and plasmonic stability was observed with the use of the Cu-Ag bimetallic synthesized structures compared to monometallic Cu. In addition, most studies pertaining CO₂ER involve aqueous electrolytes due to their low cost and low toxicity. However, these systems are hindered by mass transfer limitations due to the low solubility of CO₂ in water. Organic-based electrolytes have been subjects of research as they possess higher CO₂ solubilities to water. As dinitriles pose a novelty in the role of CO₂ER, dinitrile-based electrolytes were studied and tested for the application. It was hypothesized that due to the decreased polarity in dinitrile solvents, CO₂ concentrations in the electrolyte would increase leading to improved catalytic activity. The testing was conducted by evaluating and comparing acetonitrile (ACN), adiponitrile (ADN) and sebaconitrile (SBN) solvent-based electrolytes. Increased CO₂ solubility was observed in the dinitriles with 582 mM and 503 mM of dissolved CO₂ in ADN and SBN respectively, compared to 270 mM in ACN. Results were corroborated through DFT modelling, indicating preference of CO₂ absorbance to nitrile groups on the molecules. However, despite increases in CO₂ concentration, the electrochemical activity decreased from ACN > ADN > SBN. The trend in activity was observed to be inversely proportional to the viscosity of the dinitrile solvents, which affected the ionic conductivity. Based on these developments, the present thesis opens a new perspective for the use of Cu-based nanoparticles for direct plasmonic enhancement with the use of a broad-range wavelength white light. Furthermore, the work also sheds light on the properties and resulting electrocatalytic activities of the use of dinitrile organic electrolytes for CO₂ER. The presented findings provide significant groundwork for further developments in the realm of CO₂ER.

copper-based nanoparticles

bimetallic catalysts

plasmonic promotion

aprotic organic electrolytes

CO₂ solubility

density functional theory

CO₂ electrochemical reduction

light promotion

Développement d'accumulateurs Li/S / Development of lithium-sulfur batteries

Barchasz, Céline

25 October 2011

Ces travaux ont permis d’approfondir les connaissances du mécanisme de déchargepeu conventionnel de l’accumulateur Li/S et de ses limitations. L’ensemble desrésultats a convergé vers une unique conclusion, à savoir que le système Li/S estprincipalement limité par le phénomène de passivation de l’électrode positive en finde décharge. Les polysulfures de lithium à chaines courtes précipitent à la surface del’électrode positive de soufre. Isolants électroniques, ils sont responsables de la perteprogressive de surface active de l’électrode et de la fin prématurée de la décharge.Ainsi, les performances électrochimiques ont pu être significativement améliorées entravaillant sur la morphologie de l’électrode positive, et sur la composition del’électrolyte. En augmentant la surface spécifique de l’électrode, la quantité depolysulfures de lithium qui peut précipiter en fin de décharge est augmentée, et lapassivation totale de l’électrode est retardée. En augmentant la solubilité despolysulfures de lithium dans l’électrolyte, la précipitation des espèces est retardée etla décharge prolongée. Dans cette optique, les solvants de type PEGDME semblentêtre les plus prometteurs à ce jour. Enfin, un mécanisme possible de réduction dusoufre en électrolyte de type éther a pu être proposé. / This work aimed at better understanding the Li/S cell discharge mechanism and itslimiting parameters. A general conclusion was following from these data: the Li/Ssystem is mainly limited by the passivation process of the sulfur positive electrode,occurring at the end of discharge. Insulating lithium polysulfides precipitate on thepositive electrode surface, thus leading to a gradual loss of the electrode activesurface and to the early end of discharge. As a consequence, the electrochemicalperformances can be significantly improved by working either on the positiveelectrode morphology or on the organic electrolyte composition. Increasing thespecific surface of the positive electrode enables to increase the amount ofpolysulfide compounds that can precipitate on the electrode, thus delaying the fullpassivation of the sulfur electrode and the end of discharge. Working on the organicelectrolyte composition enables to increase the polysulfide solubility and to preventthem from quickly precipitating, thus delaying the end of discharge too. To thispurpose, PEGDME solvents seem to be quite promising. Finally, a possiblemechanism for sulfur reduction in ether-based electrolytes could be proposed.

Accumulateurs électrochimiques

Lithium/Soufre

Li/S

Limitations et mécanisme de décharge,

Electrodes composites

Electrolytes organiques

Batteries

Lithium/Sulfur

Li/S

Composite electrodes

Organic electrolytes

Lithium polysulfide characterization

Liquid Organic Electrolytes: Blends of Low Molecular Weight Methoxyoligooxyethylene (MPEGs)/LiTFSI Salt

Alshahrani, Rasha

15 December 2017

Blends containing methoxyoligooxyethyleneglycol (MPEGs) (MW 350 and 550) and bis(trifluoromethane)sulfonimide lithium (LiTFSI) salt were prepared by solution blending process using tetrahydrofuran (THF) as a solvent. The ionic conductivity of the blends of different compositions were determined at four temperatures i.e. 25°C, 40°C, 60°C and 70°C. A maximum ionic conductivity value of 3.9x10-3 S cm-1 at 25°C was obtained for the blends containing MPEG-350 at an ethylene oxide to lithium salt ratio of 1:10. The ionic conductivity increases with increasing temperature and shows that the ion transport is aided by the segmental motion of the MPEG chains. 7Li NMR spectroscopy was used to study the nature and dynamics of the salt clusters in the blends

Methoxypolyethylene glycol (MPEG)

low molecular weight MPEGs

LiTFSI salt

Triglyme Boron

Ionic conductivity

7Li NMR

Lithum-air battery

Liquid Organic Electrolytes

Organic Chemistry

Polymer Chemistry