Photopolymerizations of multicomponent epoxide and acrylate/epoxide hybrid systems for controlled kinetics and enhanced material properties

Eom, Ho Seop

01 May 2011

Cationic photopolymerization of multifunctional epoxides is very useful for efficient cure at room temperature and has been widely used in coatings and adhesives. Despite excellent properties of the final cured polymers, cationic photopolymerizations of epoxides have seen limited application due to slow reactions (relative to acrylates) and brittleness associated with a highly crosslinked, rigid network. To address these issues, two reaction systems were studied in this thesis: photoinitiated cationic copolymerizations of a cycloaliphatic diepoxide with epoxidized elastomers and acrylate/epoxide hybrid photopolymerizations. Oligomer/monomer structures, viscosity, compositions, and photoinitiator system were hypothesized to play important roles in controlling photopolymerizations of the epoxide-based mixtures. A fundamental understanding of the interplay between these variables for the chosen systems will provide comprehensive guidelines for the future development of photopolymerization systems comparable to the epoxide-based mixtures in this research. For diepoxide/oligomer mixtures, the observed overall enhancement in polymerization rate and ultimate conversion of the cycloaliphatic diepoxide was attributed to the activated monomer mechanism associated with hydroxyl terminal groups in the epoxidized oligomers. This enhancement increased with increasing oligomer content. The mixture viscosity influenced the initial reactivity of the diepoxide for oligomer content above 50 wt.%. Real-time consumption of internal epoxides in the oligomers was successfully determined using Raman spectroscopy. Initial reactivity and ultimate conversion of the internal epoxides decreased with increasing the diepoxide content. This trend was more pronounced for the oligomer containing low internal epoxide content. These results indicate that the reactivity of the hydroxyl groups is higher toward cationic active centers of the diepoxide than those of the internal epoxides in the oligomers. These conclusions are consistent with physical property results. The enhanced fracture toughness and impact resistance were attributed to multimodal network chain-length distribution of copolymers containing the oligomer content between 70% and 80%. For acrylate/epoxide hybrid mixtures, diacrylate oligomers significantly suppressed reactivities of cycloaliphatic mono/diepoxides, which was attributed to high mixture viscosity and highly crosslinked acrylate network. In this case, the dual photoinitiator system did not favor the epoxide reaction. Depending on the monovinyl acrylate secondary functionalities, enhanced reactivity and ultimate conversion of the diepoxide were attributed to a combined effect of a reduced viscosity and the radical-promoted cationic polymerization associated with the dual photoinitiator. The retarded and inhibited diepoxide reactivities with ether and urethane secondary groups were attributed to solvation and nucleophilicity/basicity effects, respectively. The influence of the diepoxide on the acrylate reactivity was attributed to dilution and polarity effects. In this case, high concentration of the free-radical photoinitiator is required for the dual photoinitiator system. Physical properties of hybrid polymers also varied with acrylate structures and monomer composition. Dynamic modulation methods were proposed to enhance the diepoxide reactivity and final properties in the presence of urethane acrylates.

Cationic photopolymerization

Epoxidized polybutadiene oligomer

Free-radical photopolymerization

Interpenetraing network structure

Photoinitiated cationic copolymerization

Chemical Engineering

Studium fotochemického síťování methakrylovaného PVAl / Investigation of Methacrylated PVAl Photochemical Crosslinking

Králová, Marcela

January 2008

This diploma thesis deals with a detailed study of photoinitiated radical polymerization of macromers base on PVAl containing lateral GMA moieties. The main goal is the evaluation of the influence of photoinitiator concentration, polymerisable group content and/or other aditives on the polymerisation rate. Other goals include the study of possible influencing the photochemical speed by lowering the glass transition temperature, compatibility with various photoinitiators etc. Attention is also paid to the study of prepared 3D polymeric networks properties

Electrolyte solide innovant à base de liquides ioniques pour micro-accumulateurs au lithium : réalisation par voie humide et caractérisation des propriétés de transport / Gellified electrolyte for microbatteries : elaboration of an ionic liquid-based membrane and characterization of transport properties

Piana, Giulia

22 November 2016

Dans le but d’améliorer les performances des micro-accumulateurs au lithium, de nouvelles voies de dépôt, compatibles avec des géométries texturées, sont actuellement explorées. Au cours de ce travail de thèse, un nouvel électrolyte solide déposé par voie « humide » a été développé. Ce matériau, composé d’un liquide ionique et d’un sel de lithium confinés dans une matrice solide, a été synthétisé par polymérisation in-situ d’un oligomère diméthacrylate. Afin de définir leurs caractéristiques de conduction ionique, de nouvelles méthodes, comme le suivi de la photo-polymérisation par impédance in-situ ou encore la réalisation d’un nouveau design de cellules à base de peignes interdigités, ont été développées. De plus, le transfert du lithium a été mesuré par RMN diffusionnelle. Une diminution significative de la vitesse de diffusion des ions Li+ après la photo-polymérisation a ainsi été mise en évidence. La spectroscopie Raman a permis de démontrer que celle-ci est due à la complexation des ions par les chaines de poly(oxyde d’éthylène) de la matrice solide. En outre, grâce aux observations de différentes compositions, un mécanisme de diffusion mixte des ions Li+ par migration dans le liquide et par sauts dans le solide a été identifié. Par conséquent, ces résultats nous ont permis de définir une stratégie pour améliorer la diffusion des ions Li+ : l’ajout d’un copolymère monofonctionnel a permis de diminuer la densité de réticulation de la matrice solide et ainsi d’optimiser la mobilité des chaines polymères. En effet, les performances de cyclage dans des empilements de micro-accumulateurs complets ont été améliorées. A température ambiante, ces résultats se sont révélés très proches de ceux obtenus avec l’électrolyte solide standard LiPON. En conclusion, l’analyse établie a permis de comprendre les liens entre structure et performances électrochimiques, ce qui a permis de dégager les voies d’amélioration les plus prometteuses pour ce type d’électrolytes. / New deposition techniques compatible with making tridimensional geometries are currently being investigated with the aim of improving the performances of lithium microbatteries. This work focuses on the development of a new quasi-solid electrolyte deposited by a “wet process”. An ionic liquid-based membrane containing a lithium salt was prepared by the photo-induced polymerization of a dimethacrylate oligomer. New methods such as a new type of conductivity cell based on planar interdigitated electrodes to measure ionic conductivity as well as in-situ monitoring of photo-polymerization using impedance spectroscopy were used. Transport properties of lithium ion were measured by PGSE-NMR. Interestingly, a significant reduction of lithium ion mobility was observed after UV-curing while the total ionic conductivity only decreased slightly. This phenomenon is due to the formation of lithium ion complexes with ethylene oxide moieties of the solid matrix, evidenced by Raman spectroscopy measurements. Additionally, we have shown that the structures of the complexes depend on the salt concentration and a dual solid/liquid transport mechanism was suggested. Hence, in order to improve lithium ion diffusion, a co-polymer was added in an attempt to decrease the cross-linking density of the solid matrix thus improving its segmental motion. The cyclability of the all solid state micro batteries was indeed improved. Comparable performances with the standard solid electrolyte LiPON were obtained at room temperature. In summary, it was established that electrochemical performances of the solid state microbatteries depend to a certain extent on the structure of the polymer electrolyte. Therefore it is possible to find new ways in designing these types of electrolytes for further improvement.

Electrolytes gélifiés

Liquide ionique

Microbatteries au lithium

Photoréticulation

Spectroscopie d'impédance

Gel polymer electrolyte

Ionic liquid

Lithium microbatteries

Photoinitiated crosslinking

Impedance spectroscopy

New Polyazine-Bridged Ru(II),Rh(III) and Ru(II),Rh(I) Supramolecular Photocatalysts for Water Reduction to Hydrogen Applicable for Solar Energy Conversion and Mechanistic Investigation of the Photocatalytic Cycle

Zhou, Rongwei

09 November 2014

The goal of this research is to test the design constraints of active dpp-bridged RuII,RhIII (dpp = 2,3-bis(2-pyridyl)pyrazine)) supramolecular photocatalysts for water reduction to H2 and provide mechanistic insights into the catalytic cycle. Two member of a new RuII,RhIII motifs with only one Rh-'Cl bond, [(bpy)2Ru(dpp)RhCl(tpy)](PF6)4 ( bpy = 2,2'-bipyridine, tpy = 2,2':6,2"-terpyridine) and [(bpy)2Ru(dpp)RhCl(tpm)](PF6)4, (tpm = tris(1-pyrazolyl)methane), and a cis-RhCl2 model system, [(bpy)2Ru(dpp)RhCl2(bpy)](PF6)3, were prepared. This new motif was to test whether two Rh-'Cl bonds on RhIII are required for the photocatalytic water reduction. 1H NMR spectroscopic analysis of complexes prepared using deuterated ligands was used to characterize these three RuII,RhIII supramolecular complexes. Electrochemical studies suggested that replacing bpy with a tridentate ligand on RhIII shifts the RhIII/II and RhII/I reduction couples positively, which can modulate the orbital energetics of the RhIII LUMO (lowest-unoccupied molecular orbital). This substitute also changes the rate of ligand dissociation following the reduction of RhIII. In tpm and bpy systems, RhII intermediate is more stable than that in the tpy system. All three complexes were good light absorbers in the visible region and weak emitters from their emissive Ru(dπ)-'dpp(π*) 3MLCT (metal-to-ligand charge transfer) excited states at room temperature. The population of a low-lying 3MMCT (metal-to-metal charge transfer) ES (excited state) from the 3MLCT ES contributed to the weak emission, indicating an important intramolecular electron transfer process from dpp' to RhIII upon photoexcitation. The lower-lying 3MMCT excited state in the tpm and tpy systems relative to the bpy system result in a higher rate constant (ket = 2.6 x 10^7 vs 1.7 x 10^7 s-1) for intramolecular electron transfer. Spectrophotochemical analysis suggested that all three complexes were photoinitiated electron collectors capable of collecting two electrons on the RhIII center to generate the RuII,RhI species in the presence of DMA (N,N-dimethylaniline). The observed H2 production from water using [(bpy)2Ru(dpp)RhCl(tpm)](PF6)4 and [(bpy)2Ru(dpp)RhCl(tpy)](PF6)4 established that two halides on RhIII are not necessary in the dpp-bridge RuII,RhIII supramolecular photocatalytic-water-reduction system. This new discovery opens a new approach to the design of different RuII,RhIII motifs for photocatalysis. The active species for water reduction is proposed to be [(bpy)2Ru(dpp)RhICl(TL)]3+ from [(bpy)2Ru(dpp)RhCl(TL)](PF6)4 (TL (terminal ligand) = tpy or tpm) and [(bpy)2Ru(dpp)Rh(bpy)]3+ from [(bpy)2Ru(dpp)RhCl2(bpy)](PF6)3 respectively. Included here is the design and study of a RuII,RhI complex, [(bpy)2Ru(dpp)RhCl(COD)](PF6)3 (COD =1,5-cyclooctadiene) to provide more insights into the photophysical and photochemical properties of polypyridyl RuII,RhI species. Electrochemical and photophysical studies revealed a dpp-based LUMO in this RuII,RhI complex, suggesting dpp reduction upon photoexcitation. Photochemical study found that [(bpy)2Ru(dpp)RhCl(COD)](PF6)3 is an active photocatalyst for water reduction and that additional reduction(s) is (are) required after the generation of the RuII,RhI active species in the RuII,RhIII supramolecular photocatalytic H2 production system. This hypothesis was supported by the electrocatalytic behaviors of the RuII,RhIII supramolecular complexes for proton reduction. Cyclic voltammetry results in the presence of an acid suggested that the protonolysis of the RuII,RhIIH and RuII,RhIH species are electrocatalytic H2-evolution pathways. The mechanism is acid-dependent and influenced by terminal ligand. The studies of electrocatalytic proton reduction on these RuII,RhIII complexes suggested several possible intermediates involved in the photocatalytic water reduction cycle. The insights gained from this research can provide guidance in designing new type of RuII,RhIII and RuII,RhI complexes with better photocatalytic and/or electrocatalytic H2 production performance. / Ph. D.

supramolecular complexes

solar energy

water splitting

hydrogen production

tridentate ligand

rate constant

halide loss

photoinitiated electron collector

excited state quenching

photocatalysis

electrocatalysis

protonation

protonolysis

rhod

Fotodegradação dos herbicidas atrazina e amicarbazona em meio aquoso: destino ambiental e tratamento. / Photodegradation of herbicides atrazine and amicarbazone in aqueous medium: environmental fate and treatment.

Silva, Marcela Prado

03 December 2015

É grande a preocupação quanto à presença de poluentes persistentes (POP) no ambiente aquático, devido ao potencial destes micropoluentes em afetar organismos aquáticos e a saúde humana. Dentre os POP estão os herbicidas atrazina (ATZ) e amicarbazona (AMZ), empregados no controle de ervas daninhas no cultivo de cana-de-açúcar, responsável por grande parte do consumo de herbicidas no país. O conhecimento do destino desses compostos no meio ambiente é essencial para avaliar seus potenciais impactos, embora não haja na literatura estudos detalhados relacionados a esse tema. No presente trabalho, através da combinação de resultados de experimentos realizados em simulador solar empregando matéria orgânica natural isolada, dados da literatura e simulações matemáticas, foi investigado o destino ambiental fotoquímico da AMZ, considerando as características de corpos d\'águas brasileiros. Analogamente e para fins de comparação, simulou-se o destino ambiental fotoquímico da ATZ com base em informações da literatura. Os resultados das simulações indicaram que a matéria orgânica dissolvida e a profundidade da coluna d\'água são as variáveis que mais influenciam na persistência dos dois herbicidas. O tempo de meiavida pode chegar a aproximadamente 2 meses e 1 ano, para AMZ e ATZ, respectivamente. Assim como é importante o entendimento do destino ambiental dos POP, também é essencial a investigação de processos avançados de oxidação desses poluentes, muitos dos quais são fotoirradiados. Procurando contribuir nesse sentido, neste trabalho estudou-se a fotólise da ATZ sob radiação UV em 254 nm, considerando os efeitos da taxa específica de emissão de fótons e da concentração inicial do herbicida. Procurou-se investigar detalhadamente o papel de espécies reativas de oxigênio (ROS) neste processo, resultados até então não discutidos na literatura. Além disso, os resultados obtidos para ATZ foram comparados aos disponíveis na literatura para AMZ. A degradação dos dois herbicidas diminui com o aumento da concentração inicial dos herbicidas, seguindo decaimento de pseudo primeira-ordem e aumentando com a taxa de emissão de fótons. Os resultados sugerem a formação de produtos persistentes e as ROS foram apontadas como atores importantes durante a degradação fotolítica dos herbicidas. / The presence of Persistent Organic Pollutants (POP) in aquatic environment is a subject of great concern, especially due to their capacity to affect not only aquatic organisms but also the human health. Herbicides as atrazine (ATZ) and amicarbazone (AMZ) are also classified as POP and are widely applied to control weeds on sugarcane cultivations, which are responsible for the increased consumption of herbicides in Brazil. The knowledge regarding the fate of these compounds once released into the environment represents an important issue and is also a type of information usually lacking in the available literature. Through the use of results obtained in experiments performed with a solar simulator, literature data, and mathematical simulations, the photochemical destination of AMZ in the environment was studied considering the characteristics of Brazilian surface water bodies. For purposes of comparison, the environmental destination of ATZ was also simulated. The results indicate that the dissolved organic matter and the depth of the water column are the most influential variables in the environmental persistence of these pesticides. Their half-life may extend up to 2 months to a year, for AMZ and ATZ, respectively. Besides the environmental fate, this investigation also aims to shine a light on the degradation of these contaminants in irradiated advanced oxidation processes. Accordingly, ATZ photolysis through the use of UV radiation (254 nm) was studied, whilst taking into consideration both the herbicide initial concentration and the specific photon emission rate. Another important contribution of this study is the investigation of the role of reactive oxygen species (ROS) in photolytic processes, a subject not usually discussed in the literature. In addition, a crossed-reference analysis between the results obtained for ATZ and those available in the literature for AMZ is presented. The degradation of both herbicides diminishes with the increase in their initial concentration and follows a pseudo first-order decay, increasing with the photon emission rate. Moreover, the results indicate that the formation of persistent degradation products does occur and that ROS play a crucial role in photolytic herbicide degradation.

Amicarbazona

Amicarbazone

Atrazina

Atrazine

Degradação ambiental

Degradação fotoinduzida

Degradação fotoiniciada

Destino ambiental fotoquímico

Espécies reativas de oxigênio

Fotólise UV

Herbicidas

Herbicides

Photochemical fate

Photoinduced degradation

Photoinitiated degradation

Reactive oxygen species

UV photolysis

Fotodegradação dos herbicidas atrazina e amicarbazona em meio aquoso: destino ambiental e tratamento. / Photodegradation of herbicides atrazine and amicarbazone in aqueous medium: environmental fate and treatment.

Marcela Prado Silva

03 December 2015

É grande a preocupação quanto à presença de poluentes persistentes (POP) no ambiente aquático, devido ao potencial destes micropoluentes em afetar organismos aquáticos e a saúde humana. Dentre os POP estão os herbicidas atrazina (ATZ) e amicarbazona (AMZ), empregados no controle de ervas daninhas no cultivo de cana-de-açúcar, responsável por grande parte do consumo de herbicidas no país. O conhecimento do destino desses compostos no meio ambiente é essencial para avaliar seus potenciais impactos, embora não haja na literatura estudos detalhados relacionados a esse tema. No presente trabalho, através da combinação de resultados de experimentos realizados em simulador solar empregando matéria orgânica natural isolada, dados da literatura e simulações matemáticas, foi investigado o destino ambiental fotoquímico da AMZ, considerando as características de corpos d\'águas brasileiros. Analogamente e para fins de comparação, simulou-se o destino ambiental fotoquímico da ATZ com base em informações da literatura. Os resultados das simulações indicaram que a matéria orgânica dissolvida e a profundidade da coluna d\'água são as variáveis que mais influenciam na persistência dos dois herbicidas. O tempo de meiavida pode chegar a aproximadamente 2 meses e 1 ano, para AMZ e ATZ, respectivamente. Assim como é importante o entendimento do destino ambiental dos POP, também é essencial a investigação de processos avançados de oxidação desses poluentes, muitos dos quais são fotoirradiados. Procurando contribuir nesse sentido, neste trabalho estudou-se a fotólise da ATZ sob radiação UV em 254 nm, considerando os efeitos da taxa específica de emissão de fótons e da concentração inicial do herbicida. Procurou-se investigar detalhadamente o papel de espécies reativas de oxigênio (ROS) neste processo, resultados até então não discutidos na literatura. Além disso, os resultados obtidos para ATZ foram comparados aos disponíveis na literatura para AMZ. A degradação dos dois herbicidas diminui com o aumento da concentração inicial dos herbicidas, seguindo decaimento de pseudo primeira-ordem e aumentando com a taxa de emissão de fótons. Os resultados sugerem a formação de produtos persistentes e as ROS foram apontadas como atores importantes durante a degradação fotolítica dos herbicidas. / The presence of Persistent Organic Pollutants (POP) in aquatic environment is a subject of great concern, especially due to their capacity to affect not only aquatic organisms but also the human health. Herbicides as atrazine (ATZ) and amicarbazone (AMZ) are also classified as POP and are widely applied to control weeds on sugarcane cultivations, which are responsible for the increased consumption of herbicides in Brazil. The knowledge regarding the fate of these compounds once released into the environment represents an important issue and is also a type of information usually lacking in the available literature. Through the use of results obtained in experiments performed with a solar simulator, literature data, and mathematical simulations, the photochemical destination of AMZ in the environment was studied considering the characteristics of Brazilian surface water bodies. For purposes of comparison, the environmental destination of ATZ was also simulated. The results indicate that the dissolved organic matter and the depth of the water column are the most influential variables in the environmental persistence of these pesticides. Their half-life may extend up to 2 months to a year, for AMZ and ATZ, respectively. Besides the environmental fate, this investigation also aims to shine a light on the degradation of these contaminants in irradiated advanced oxidation processes. Accordingly, ATZ photolysis through the use of UV radiation (254 nm) was studied, whilst taking into consideration both the herbicide initial concentration and the specific photon emission rate. Another important contribution of this study is the investigation of the role of reactive oxygen species (ROS) in photolytic processes, a subject not usually discussed in the literature. In addition, a crossed-reference analysis between the results obtained for ATZ and those available in the literature for AMZ is presented. The degradation of both herbicides diminishes with the increase in their initial concentration and follows a pseudo first-order decay, increasing with the photon emission rate. Moreover, the results indicate that the formation of persistent degradation products does occur and that ROS play a crucial role in photolytic herbicide degradation.

Amicarbazona

Atrazina

Degradação ambiental

Degradação fotoinduzida

Degradação fotoiniciada

Destino ambiental fotoquímico

Espécies reativas de oxigênio

Fotólise UV

Herbicidas

Amicarbazone

Atrazine

Herbicides

Photochemical fate

Photoinduced degradation

Photoinitiated degradation

Reactive oxygen species

UV photolysis