Electrochemical Promotion of Gold Nanoparticles Supported on Yttria-Stabilized Zirconia

Kim, Jong Min

January 2011

The feasibility of highly dispersed gold nanocatalyst supported on yttria-stabilized zirconia (YSZ) for the model reactions of C2H4 and CO oxidation is demonstrated for the first time. Gold nanoparticles are synthesized on YSZ powder by chemical reduction of the precursor salt in the mixture of ethanol, water and polyvinylpyrrolidone (PVP). Resulting metal loading of the catalysts are 1 wt.% with average particle sizes ranging from 6 to 9 nm. Results of CO and C2H4 oxidation display catalytic activity at 65 0C and 25 0C for CO and C2H4 oxidation, respectively. The catalytic properties of the catalysts are different due to their average particle size. Electrochemical Promotion of Catalysis (EPOC) of C2H4 oxidation is demonstrated. Application of constant potential difference between two electrodes in the bipolar electrochemical cell led to increase in C2H4 conversion. A proposed mechanism explains the bipolar EPOC phenomenon through formation of O2- flux across the electrochemical cell, resulting in the change of Work Function of gold nanoparticles placed in between the electrodes and is electronically isolated.

c2h4 oxidation

electrochemical promotion

epoc

ethylene oxidation

wireless

nemca

nanocatalyst

gold nanoparticle

ysz

yttria stabilized zirconia

Performance and emissions study of diesel and waste biodiesel blends with nanosized CZA2 of high oxygen storage capacity

Pimenidou, Panagiota, Shanmugapriya, N., Shah, N.

29 November 2018

Yes / In this work, the effect of the nanosized CZA2 (cerium-zirconium-aluminium) on the performance and emissions in a two- cylinder indirect injection (IDI) diesel engine, was studied. CZA2 was dispersed in diesel (D100) and waste cooking oil and tallow origin biodiesel-diesel blends (B10, B20, B30) and tested at different engine loads and constant speed. The nanocatalyst (CZA2) increased the brake specific fuel consumption (BSFC) and decreased the brake thermal efficiency (BTE, %) of all tested fuels, at all loads, except B20 at the lowest load. CZA2 reduced nitrogen oxides (NOx) from D100 at low and high engine loads, as well as carbon monoxide (CO) and unburned hydrocarbons (HC) at medium and high tested loads. The dispersion of CZA2 promoted the combustion of the biodiesel blends by almost eliminating HC while reducing NOx and CO emissions at various loads. Thermogravimetric analysis (TGA) coupled with Attenuated Total Reflectance- Fourier Transform Infrared (ATR-FTIR) spectroscopy revealed that the addition of CZA2 in diesel and biodiesel under pyrolysis and oxidation conditions resulted in the presence of saturated species like ketones and final oxidation products such as CO2, supporting their improved combustion and emissions’ reduction in the engine tests.

Redox

Waste biodiesel

Nanocatalyst

Nitrogen oxides (NOx)

Hydrocarbons (HCs)

CZA2 (cerium-zirconium-aluminium)

Nanostructured Hybrids with Engineered Interfaces for Efficient Electro, Photo and Gas Phase Catalytic Reactions

Leelavati, A

January 2015

Catalysis using nanostructures has been a topic of substantial interest for fundamental studies and for practical applications in energy and environmental sectors. The growing demand for production of energy and in the cleaning of polluting hazardous vehicles/industrial wastes has led to several studies in catalysis. Despite the substantial growth of heterogeneous catalytic technologies in last decade, they are still far from reaching their full potential in terms of efficiency, selectivity as well as durability. It is often difficult to simultaneously tackle all the mentioned issues with single component catalysts. Most of these challenges are being overcome with heterostructures/supported hybrid catalysts by modifying their interfaces. The properties of heterostructures hybrids arises not only from the individual contributions of the individual components but also from strong synergetic effect arising from the interface. Engineering the interfaces provides pathways to promote the catalytic performance and hence has been explored. In this regard, we have focused on the progress in investigating the active interfaces that affect the performance of metal oxide-metal, semiconductor-metal and coupled semiconductor nanocatalyst hybrids. We explored a wide spectrum of their applications in photo catalytic, electrocatalytic as well as gas-phase reactions and highlighted the importance of the interface for overall performance. The entire study reported in the thesis is organized as follows: Chapter 1 is a general introduction of hybrid nanocatalyst and their role in wide spectra of catalytic reactions in photo/electro catalysis as well as gas-phase reactions. This chapter describes the motivation behind modulating the interface between two or more nanostructures to obtain multifunctional nanocatalysts. Nan catalysts to achieve high throughput with active interfaces are elaborated while indicating the role of morphology, internal induced state, charge transfer, geometric, support, as well as electronic effect for enhanced performance. Motivation behind specific nanocatalyst hybrid, synthesis routes as well as characterization techniques are detailed in the respective chapters. Specific details for different hybrids are described in the following chapters. Chapter 2 describes the synthesis of high dense ultrathin Au wires on ZnO nanorods for electrocatalytic oxidation of ethanol, where the prerequisite step is the formation of amine-modified support. Oleylamine modification not only serves to anchor Au nanowires on ZnO but also passivates surface defects of ZnO, which in turn enhances the photocurrent. In addition to the stability, the support induces electronic effect on Au nanowires, which facilitates redox process at low potential. Most importantly, the support promotes the activity of Au nanowires upon photoirradiation, and thus leading to synergy between electro and photooxidation current. This is of immense importance for photofuel cell technologies. Moreover, the method enabled the first time electrocatalysis on these nanowires that revealed ultrathin nanowires are potentially interesting systems for catalysis applications provided they are stabilized by a suitable support. Chapter 3 deals with the growth of ultrathin Au nanowires on metal oxide (TiO2) coupled with graphene hybrid support in order to overcome the low conductivity of metal oxide. Oleylamine, used for growth of Au nanowires simultaneously functionalizes the support and leads to room temperature GO reduction. With respect to catalytic activity, we also synthesized the binary counterparts (rGO/Au, TiO2/Au ultrathin nanowires) to delineate the contribution of each of the components to the overall electrocatalytic oxidation of ethanol. Comparative analysis of photo and electrocatalytic activity between the different binary and ternary hybrids provides interesting information. Both, electronic effect of TiO2 and electrical conductivity of rGO add their specific beneficial to the nanowires, leading to superior ternary system. Chapter 4 rGO supported ultrathin Au nanowires exhibits high electrocatalytic performance for oxidation of borohydride with a lower onset potential compared to rGO/Au nanoparticles. Electrochemical impedance spectroscopy measurements display abnormal inductive behavior of the synthesized hybrids, indicative of Au surface reactivation. DFT calculations indicate that the origin of the high activity stems from the shift in the position of the Au d-band center. Chapter 5 Different aspect ratio ZnO nanostructures are obtained by varying the solvothermal reaction time. We observed a direct correlation between observed photocatalytic activity, measured photocurrent and length of the ZnO nanorods. Furthermore, photoresponse of the high aspect ratio ZnO nanorods are improved by attaching Au nanoparticles, intimate contact of two components leads to band bending. Thus, the synthesized ZnO/Au heterostructure favors for prominent separation of photogenerated charge carriers. Chapter 6 TiO2 and PbO/TiO2 hybrids are synthesized via non–hydrolytic sol–gel combustion method. Hybrid exhibits higher photocatalytic activity for the degradation of dye than TiO2. The estimated photogenerated species reveals that the origin of enhanced activity stems from the direct oxidization of dye via photogenerated hole rather than radicals. The semiconductors are matched based on their band edge positions, for the formation of energetic radicals to degrade the pollutants. Based on this study, we infer that semiconductors should not neglected (for example Si) based on calculated mismatch of their valence band edges position for photooxidation reaction via radicals. Chapter 7 describes the Pd dopant associated band engineering, a strategy for tuning the optoelectronic properties of ZnO towards enhanced photocatalytic activity. Incorporated Pd heterocation induces internal energy states within the ZnO band gap. The created energy level leads to trends mismatch between photocatalytic activity and measured photocurrent. Formed energy level arrests the photogenerated electrons, which make them not contribute for the photocurrent generation. Hence, the isolated photogenerated hole efficiently oxidizes the pollutants through hydroxyl radicals, and thus leads to enhanced photocatalytic activity. Chapter 8 employed Pd-substituted zinc stannate for CO oxidation as heterogeneous catalyst for the first time. Compared with SnO2 support, zinc stannate based materials exhibits abnormal sudden light-off profiles at selective temperatures. On the basis of DRIFT studies under relevant conditions, we find that the initially formed product gets adsorbed over the catalyst surface. It leads to the accumulation of carbonates as a consequence, both lattice oxygen mobility and further CO interactions are disabled. As soon as Sn redox nature dominates over the accumulated carbonates, this leads to sudden release of lattice oxygen, and thus leads to a sudden full conversion. Therefore, choosing the suitable support material greatly influences the nature of the light-off CO oxidation profile. Chapter 9 Although, reducible oxide supported gold nanostructures exhibits the highest CO oxidation activity; they still suffer from problems such as limited selectivity towards CO in the presence of H2. Both ex-situ and in-situ experiments demonstrate that, Au nanoparticles supported on Zn2SnO4 matrix selectively oxidizes CO. DRIFT experiments revealed that the involvement of OH groups leads to the formation of hydroxycarbonyl under PROX conditions. Chapter 10 This chapter discusses the conclusions for the previous chapters and highlights the possibilities for future scope for the developed nanocatalysts hybrids for energy and environmental applications.

Semiconductors

Electrocatalysis

Photocatalysis

Nanostructred Hybrids

Gas-phase Catalysis

Metal Oxide-Metal Nanocatalyst Hybrids

Semiconductor-metal Nanocatalyst Hybrids

Semiconductor Nanocatalyst Hybrids

Semiconductor Interfaces

Semiconductor-Metal Interfaces

Zinc Oxide Nanorods

Ultrathin Silver (Au) Nanowire Hybrids

Engineered Interfaces

Ultrathin Au Nanowires

rGO/TiO2

ZnO Nanorods

PbO Quantum Dots

Nanoscience

Synthèse et caractérisation de nanocatalyseurs à base de palladium pour l'oxydation du glucose et la réduction de l'oxygène moléculaire en milieu alcalin / Synthesis and characterization of Pd based nanocatalysts for glucose oxidation and dioxygen reduction in alkaline medium

Diabaté, Donourou

18 December 2012

L'objet de cette étude était le développement de nanocatalyseurs pour une application dans unepile glucose/oxygène en milieu alcalin. Avec la demande de plus en plus croissante d'énergiepropre et moins chère, il paraît judicieux de s'orienter vers des dispositifs moins toxiques de pile àcombustible qui peuvent utiliser le glucose comme combustible. Ce travail de thèse s’est doncattaché à synthétiser et caractériser de nouveaux matériaux catalytiques à base de palladium(Pd/C, PdAg/C et PdNi/C) et à analyser leur activité vis-à-vis des réactions de réduction del'oxygène et de l'électrooxydation du glucose. Les nanocatalyseurs utilisés lors de ces travaux ontété synthétisés par microémulsion «water-in-oil» et sont supportés sur du carbone Vulcan XC-72R.Les caractérisations physiques montrent des nanoparticules assez uniformes et la taille moyennedes particules reste inférieure à 5 nm. La réaction de réduction de l'oxygène commence tôt à lasurface de ces catalyseurs (environ 0,92 V vs. ERH) et le nombre d'électrons échangés est prochede 4. Le couplage voltammétrie / spectroscopie IR a permis de montrer que le glucose s’oxyde àbas potentiel à la surface de ces électrodes. Le produit primaire de cette déshydrogénation est lagluconolactone qui s’hydrolyse en solution en gluconate. Le dioxyde de carbone est aussi unproduit d’oxydation. Sa présence à des potentiels élevés montre que le squelette de la moléculeinitiale du glucose subit une adsorption dissociative notamment sur Pd70Ag30. / This work concerns the development of nanocatalysts for a glucose/oxygen fuel in alkalinemedium. Therefore, carbon supported based palladium nanomaterials (Pd/C, PdAg/C and PdNi/C)were synthesized and characterized. Their electrocatalytic activity towards both the glucoseoxidation and oxygen reduction reaction (ORR) was studied. The electrode materials have beensynthesized by “water-in-oil microemulsion” and the physic-chemical characterizations providedinformation on their shape, morphology. Their average particle size remained less than 5 nm. Theoxygen reduction reaction performed with Rotation Ring Disk Electrode (RRDE) on these catalystsled to a four electrons process i.e. without hydrogen peroxide as intermediate (at ca. 0.85 V vs.RHE). Cycling voltammetry combined with Single Potential Alteration Infrared ReflectanceSpectroscopy (SPAIRS) was helpful to show that the primary product of the glucosedehydrogenation is the d-gluconolactone. The latter oxidation product undergoes hydrolysis togluconate in electrolytic solution. At high potential, the dissociative adsorption of glucose onPd70Ag30 gave carbon dioxide as another oxidation product.

Nanocatalyseurs

Pd/C

PdNi/C

PdAg/C

Glucose

Réduction de l’oxygène

Nanocatalyst

Pd/C

PdNi/C

PdAg/C

Glucose

Oxygen reduction

543