Photochemical response of nanoporous carbons. Role as catalysts, photoelectrodes and additives to semiconductors

Gomis-Berenguer, Alicia

21 December 2016

The main objective of this doctoral thesis is explore the origin of the nanoporous carbons photoactivity for studying their applications in different fields of research covering their use as photocatalysts for pollutants degradation as well as photoelectrodes for water photooxidation reaction, either by themselves or as additives coupled to a semiconductor in hybrid electrodes. The first stage of this study mainly consisted in investigating the photoactivity of carbon materials by themselves (in the absence of semiconductors) towards different reactions, aiming at linking their photochemical response with the carbon material nature in terms of porosity, surface chemistry, composition and structure. The exploration of the photoassisted degradation of phenol nanoconfined in the pore voids of several nanoporous carbons showed a positive effect of the tight packing of the molecule in the carbon material porosity. This indicated the role of confinement to boost fast interactions between the photogenerated charge carriers at carbon material surface and the molecule adsorbed inside pores. The irradiation wavelength was found as a key variable upon phenol photooxidation reaction, with the best optimum performance at low and high wavelengths, and a minimum photodegradation yield at ca. 400 nm for all tested carbon materials. Another parameter strongly influencing the photoactivity of the nanoporous carbons was the surface functionalisation. When sulphur was incorporated to a carbon matrix, the light conversion towards the phenol photooxidation became more efficient and it was dependent on the nature of the S-containing groups. Further on, the analysis of photocurrent transients obtained by irradiating several nanoporous carbon electrodes exhibited different responses, with either anodic or cathodic photocurrent, and transient shapes, thus demonstrating the distinct nature of the catalysed reaction occurring onto electrode/electrolyte interface. The second stage deals with hybrid nanoporous carbon/semiconductor (i.e. WO3) electrodes which allowed to explore the role of nanoporous carbon as additive towards water oxidation reaction. The presence of carbon material had a notable effect on the hybrid electrode performance, in terms of conversion efficiency (IPCE), likely due to the improved collection of the photogenerated electrons by carbon matrix. An optimal amount of carbon additive of ca. 20 wt.% was obtained for the best performing hybrid electrode, with a twofold IPCE compared to that obtained for bare WO3 electrode. The effect of carbon matrix on WO3 performance was found dependent on semiconductor crystalline structure.

Photochemisty

Nanoporous carbons

Photoelectrochemistry

Fotoquímica

Materiales de carbono nanoporosos

Fotoelectroquímica

Química Física

Electrochemical Regeneration of Cofactors Using a Novel Cuprous Oxide Derived Cathode

Kadowaki, Jonathan

19 June 2019

No description available.

Materials Science

Chemistry

Mechanical Engineering

NADPH

NADH

cofactor regeneration

photoelectrochemistry

electrochemistry

bioelectrochemistry

materials

Development of hematite and cupric oxide photoelectrodes for water splitting tandem cells

Cots, Ainhoa

13 September 2019

Since the beginning of the Industrial Revolution, the global energy consumption has been continuously increasing, supplied mainly by coal, oil and natural gases. Unfortunately, this consumption is linked to the emission of greenhouse gasses such as CO2 to the atmosphere. For this reason, it is extremely important to look for sustainable and renewable energy sources in order to replace the commonly used fossil fuels. Within the different types of renewable energy sources, solar energy holds by far the largest potential capacity. In this respect, artificial photosynthesis is a promising technology not only to harvest solar energy, but also as a means of storage by producing energy-rich chemical fuels such as H2 from water. The main components of photoelectrochemical water splitting devices are the semiconductor light absorber photoelectrodes and the electrolyte. Chapter 1 reviews the fundamental aspects of photoelectrochemical water splitting and overviews the physics and electrochemistry of semiconductor materials. The second chapter describes the methodologies and techniques employed throughout the thesis. The experimental results are reported from Chapter 3 to 8, focusing on the development and further optimization of two photoelectrodes, concretely hematite and cupric oxide, besides the design and fabrication of tandem cells for standalone water splitting. In the case of hematite photoanodes, the main efforts have focused on its doping to enhance carrier density and mobility as a way of diminishing recombination. The major drawback present in cupric oxide photoelectrodes is their instability against photocorrosion, for this reason, research has focused on protecting them, both by impregnation and adsorption methodologies. Finally, a tandem cell composed by a hematite photoanode and a cupric oxide photocathode was developed. It is worth noting that a polymer electrolyte membrane (PEM) was employed as to facilitate upscaling and diminish the corrosion observed employing the typical acidic or basic liquid electrolytes.

Photoelectrochemistry

Hematite

Cupric oxide

Water splitting

Tandem cells

Solar energy

Química Física

Electrodeposition of CdTe on Stainless Steel 304 Substrates

Rutto, Patrick Kipkoech

18 May 2018

No description available.

Condensed Matter Physics

Chemistry

Analytical Chemistry

Electrodeposition of CdTe

photoelectrochemistry

CO₂ Reduction on Cu Oxide Photoelectrodes

Vasconi, Melissa A.

12 July 2012

No description available.

Chemistry

photoelectrochemistry

cupric oxide

cuprous oxide

CO₂ fixation

Mass-transfer correlations for the dual bed colloidal suspension reactor

Jaini, Rajiv

13 January 2014

To meet the growing energy world demands, and in conjunction, lower CO2 production levels, near zero emission energy sources must be pushed to the forefront as alternatives to fossil fuels. Photoelectrochemical (PEC) cells are a potential alternative to fossil fuels and have recently generated much interest because of their potential to electrolyze water into hydrogen fuel from sunlight. But in order to be competitive with fossil fuels, understanding the mass-transfer limitations in PEC systems is critical. This work focuses on the addressing the mass-transfer limitations in a conceptually novel PEC cell reactor, the Dual Bed Colloidal Suspension Reactor (DBCSR). Mass-transfer correlations for the DBCSR are presented. The correlations are based on experimental data obtained using two fabricated diffusion cells. The working correlation representative of both cells is given. An analysis of the orientation of the gas sparger suggests that the transport phenomena in both cells is not the same, and therefore using two correlations to represent similar systems is justified. An energy analysis is presented that shows that gas sparging is a low energy consumption option to mitigate mass-transfer limitations. Future work is suggested for better understanding the mass-transfer behavior in the DBCSR.

Dual bed colloidal suspension reactor

Gas sparging

Mass transfer

Photoelectrochemistry

Renewable energy sources

Solar cells

Electrolytic cells

Conception de biocapteurs à ADN photoélectrochimiques et impédancemétriques à base de polymères électrogénérés / Photoelectrochemical and impedancemetric dna biosensors based on electrogenerated polymers

Haddache, Fatima

08 December 2015

Cette thèse porte sur la modification d'électrodes par des polymères électrogénérés, capables d'immobiliser une biomolécule et/ou de fournir des propriétés de transduction électrochimique afin d'élaborer des biocapteurs à ADN faisant intervenir différents types d'interactions : ADN/protéine de réparation, hybridation et aptamère/molécule cible.Dans un premier temps, nous avons immobilisé la protéine Formamidopyrimidine ADN Glycosylase (Fpg) de D. radiodurans portant un tag histidine sur un film de poly-(pyrrole-NTA) via l'interaction NTA/Cu2+/Histidine. Dans le but d'étudier, par spectroscopie d'impédance électrochimique et SPR, l'interaction de cette protéine avec un duplex d'ADN sans lésions et un duplex d'ADN portant une lésion -oxo-guanine (8-oxo-G), car la Fpg est une protéine impliquée dans la réparation de l'ADN lorsque celui-ci comporte un site 8 (8-oxo-G).Dans un second temps, nous avons élaboré un biocapteur photoélectrochimique à partir d'un complexe multifonctionnel, (Ru(bpy-pyrrole)2(dppn)]2+) (bpy-pyrrole=4-méthyl-4'-butylpyrrole-2,2'-bipyridine, dppn=benzo[i]dipyrido-[3,2-a:2'.3'-c]phénazine) pouvant être électropolymérisé, intercalé l'ADN et photoactivé. La preuve de concept a été réalisée pour une séquence type d'ADN du VIH. Une limite de détection de 10-15 mol.L-1 et une sensibilité de 0,01 unité par décade avec une gamme de linéarité allant de 10-15 à 10-10 mol.L-1 ont été obtenue. Puis, nous avons conçu un aptacapteur pour la détection de la cocaïne à l'aide d'un aptamère double-fragment, formant une seule entité en présence de cocaïne, pouvant être immobilisée par intercalation sur le ligand dppn du métallopolymère. Ainsi une gamme de linéarité comprise entre 10-6 et 5x10-4 mol L-1 a été obtenue pour une concentration d'aptamère de 10-7 mol L-1, avec une limite de détection de l'ordre de 10-6 mol L-1. / This work focuses on the conception and optimization of impedancemetric and photoelectrochemical DNA biosensors based on the modification of electrodes with electrogenerated polymers. Different types of interactions involving DNA were studied: DNA/DNA repair protein, hybridization and aptamer/target molecule.In the first part, a poly-(pyrrole-NTA)-modified electrode was used to immobilize a protein involved in DNA repair: the Fpg (Formamidopyrimidine DNA Glycosylase) from D. radiodurans. This protein was previously tagged with histidine to be immobilized via a (NTA)Cu-histidine interaction. This protein detects and removes 8-oxo-guanine (8-oxo-G), a DNA damage caused by irradiation in double stranded DNA. We studied the behavior of this Fpg with DNA duplexes with and without 8-oxo-G nucleotide by electrochemical impedance spectroscopy and SPR.In the second part, we report the design of novel photoelectrochemical biosensor based on a multifunctional complex, (Ru(bpy-pyrrole)2(dppn)]2+) (bpy-pyrrole=4-methyl-4'-butylpyrrole-2,2'-bipyridine, dppn= benzo[i]dipyrido-[3,2-a:2'.3'-c]phenazine) exhibiting photo-sensitive, DNA-intercalating and electro-polymerizable properties. This modified electrode achieves photoelectrochemical detection on planar electrode by intercalating HIV-DNA duplexes or aptamer–cocaine complexes. The photocurrent generated through visible irradiation was correlated to the oligonucleotides concentration. Low detection limits of 10-15 mol L-1 and sensitivity of 0.01 unit per decade were measured, demonstrating excellent adequacy of these modified electrodes towards duplex HIV DNA detection. For the cocaine detection, the photelectrochemical aptasensor was based on the immobilization of a 10-7 mol L-1 double-fragment anti-cocaine aptamer and finally exhibited a linear range between 10-6 and 5x10-4 mol L-1 and a detection limit of 10-6 mol L-1.

Biocapteur

Aptacapteur

ADN

Cocaïne

Fpg

Photoélectrochimie

Biosensor

Aptasensor

DNA

Cocaine

Fpg

Photoelectrochemistry

Electrochemical impedance spectroscopy

620

Optimalizace gelového elektrolytu pro tištěný UV senzor na bázi fotoelektrochemického článku / Optimalization of gel electrolyte for printed UV sensor based on photoelectrochemical cell

Vrbková, Kateřina

January 2020

This paper deals with the construction of photoelectrochemical cell, used for detection of ultraviolet radiation as a UV sensor. Photoelectrochemical cell consists of three layers, layer of photoactive semiconductor titanium dioxide, carbon electrodes and poly(vinyl alcohol) polymer electrolyte. The sensor layer enables the detection of UV radiation with the subsequent generation of photocurrent. Material printing techniques, such as screenprinting, pad printing and inkjet printing were used to produce the cell. Gel electrolyte was characterized by optical microscopy and rheometry. Sensor functionality was verified by use of electroanalytical techniques.

Engineering of Earth-Abundant Electrochemical Catalysts

Rodene, Dylan D

01 January 2019

Alternative energy research into hydrogen production via water electrolysis addresses environmental and sustainability concerns associated with fossil fuel use. Renewable-powered electrolyzers are foreseen to produce hydrogen if energy and cost requirements are achieved. Electrocatalysts reduce the energy requirements of operating electrolyzers by lowering the reaction kinetics at the electrodes. Platinum group metals (PGMs) tend to be utilized as electrocatalysts but are not readily available and are expensive. Ni1-xMox alloys, as low-cost and earth-abundant transition metal nanoparticles (NPs), are emerging as promising electrocatalyst candidates to replace expensive PGM catalysts in alkaline media. Pure-phase cubic and hexagonal Ni1-xMox alloy NPs with increasing Mo content (0–11.4%) were synthesized as electrocatalysts for the hydrogen evolution reaction (HER). In general, an increase in HER activity was observed with increasing Mo content. The cubic alloys were found to exhibit significantly higher HER activity in comparison to the hexagonal alloys, attributed to the higher Mo content in the cubic alloys. However, the compositions with similar Mo content still favored the cubic phase for higher activity. To produce a current density of -10 mA/cm2, the cubic and hexagonal alloy NPs require over-potentials ranging from -62 to -177 mV and -162 to -242 mV, respectively. The cubic alloys exhibited over-potentials that rival commercial Pt-based electrocatalysts (-68 to -129 mV at -10 mA/cm2). The cubic Ni0.934Mo0.066 alloy NPs showed the highest alkaline HER activity of the electrocatalysts studied and therefore a patent application was submitted. Bulk Ni–Mo phases have been known as electrocatalysts for the HER for decades, while recently transition metal phosphides (TMPs) have emerged as stable and efficient PGM alternatives. Specifically, Ni2P has demonstrated good HER activity and improved stability for both alkaline and acidic media. However, Ni2P electrocatalysts are a compromise between earth-abundance, performance (lower than Ni–Mo and PGMs) and stability. For the first time Ni–Mo–P electrocatalysts were synthesized with varying atomic ratios of Mo as electrocatalysts for alkaline HER. Specific phases, compositions and morphologies were studied to understand the intrinsic properties of TMPs leading to high HER activity. The Ni1.87Mo0.13P and Ni10.83Mo1.17P5 NPs were shown to be stable for 10 h at –10 mA cm-2 with over-potentials of –96 and –82 mV in alkaline media, respectively. The Ni1.87Mo0.13P and Ni10.83Mo1.17P5 NPs exhibited an improved performance over the synthesized Ni2P sample (–126 mV at –10 mA cm-2), likely a result of the overall phosphorous content and hetero-structured morphologies. A strong correlation between phase dependence and the influence of Mo on HER activity needs to be further investigated. Furthermore, understanding the intrinsic properties of electrocatalysts leading to high water splitting performance and stability can apply electrocatalysts in other research applications, such as photoelectrochemical (PEC) water splitting, water remediation and sustainable chemical processing applications. Contributions to photocatalytic water remediation and electrochemical chlorinated generation to halogenate pyridone-based molecules are reported. Electrochemical techniques were developed and reported herein to aid in understanding electrochemical performance, chemical mechanisms and the stability of electrocatalysts at the electrode-electrolyte interfaces.

Alkaline Water Splitting

Earth-Abundant Electrocatalysts

Electrolysis

Electrochemistry

Hydrogen Production

Photoelectrochemistry

Catalysis and Reaction Engineering

Chemical Engineering

Other Engineering Science and Materials

Preparation and study of ternary metal oxide photocathodes for solar energy conversion

Díez García, María Isabel

17 January 2018

The future energy demand will require a change in the current energy supply. In this regard, the production of hydrogen by photoelectrochemical solar cells is a promising alternative because the fuel is obtained from water and, importantly, its combustion is free of carbon. Many metal oxides, including those having a complex stoichiometry (i.e. ternary oxides) behave as semiconductors and present good stability in aqueous environments, making them attractive candidates for water splitting devices. This thesis focuses on the preparation and study of ternary metal oxide materials as photoelectrodes for water splitting, with emphasis on photocathodes. These materials must meet the requirements for a practical device: low cost, non-toxicity, made of Earth abundant elements, environmentally friendly, etc. The thesis also aims at the study of strategies to improve their photoelectrochemical response. lt comprises the investigation of the kinetics of hydrogen generation reaction and the characteristics of the electrode solution interface by photoelectrochemical impedance spectroscopy. The main points can be summarized as: (i) the effect of an electrochemical oxidative pretreatment in CuFe2Ü4 photocathodes (ii) the investigation of water splitting mechanisms in CaFe2Ü4 photocathodes, (iii) the effect of metal doping in LaFeO3 photocathodes (iv) the study of the photoelectrochemistry of compact and nanoparticulate YFeO3 photocathodes and (v) the effect of a reductive electrochemical treatment in NiTiO3 photoanodes, and comparison with the effect of the treatment in anatase electrodes.

Ternary oxide

Photocathode

Water splitting

Solar energy

Photoelectrochemistry

Óxido ternario

Fotocátodo

Fotodisociación de agua

Energía solar

Fotoelectroquímica

Química Física