Polymerní nanočástice generující singletový kyslík / Polymer nanoparticles generating singlet oxygen

Berzédiová, Veronika

January 2019

This theses focuses on preparation and characterisation and comparison of two types of polymer nanoparticles using photophysical methods. The first type was polystyrene nanoparticles prepared by modified nanoprecipitation method from polymeric sulfonated nanofiber membranes with diffrent content of sulfonated groups. The second type was polymer nanoparticles with diferent lenght of hydrophobic polycaprolactone (PCL) and hydrophilic poly(ethyleneglycol) (PEG) blocks. Both types of nanoparticles conteined encapsulated photosensitizer 5,10,15,20-meso-tetraphenylporphyrin with a high quantum singlet oxygen yield. In the prepared nanoparticles with a photosensitizer, the kinetics of singlet oxygen generation was studied using time resolved spectroscopy. The relative efficiency of photooxidation was studied using external akceptor of singlet oxygen. The effect of temperature, size and matrix (type of polymer) of nanoparticles on photooxidation efficiency was also studied. In the next part of this these was studied the influence of time on the size and stability of nanoparticles and also the effect of solution pH and ionic strength on prepared nanoparticles.

Novel Near-Infrared Cyanine Dyes for Fluorescence Imaging in Biological Systems

Fernando, Nilmi T

14 December 2011

Heptamethine cyanine dyes are attractive compounds for imaging purposes in biomedical applications because of their chemical and photophysical properties exhibited in the near-infrared region. A series of meso amino-substituted heptamethine cyanine dyes with indolenine, benz[e]indolenine and benz[c,d]indolenine heterocyclic moieties were synthesized and their spectral properties including fluorescence quntum yield were investigated in ethanol and ethanol/water mixture. Upon substitution with amines, the absorption maxima of the dyes shifted to the lower wavelength region (~600 nm), showed larger Stokes shifts and stronger fluorescence which can be attributed to an excited state intramolecular charge transfer (ICT). High quantum yields were observed for primary amine derivatives and lower quantum yields were observed for secondary amine derivatives. Fluorescence quantum yields are greater for dyes with 3H-indolenine terminal moieties than for dyes with benz[e]indolenine end groups. Benz[c,d]indolenine based heptamethine cyanine dyes exhibited the lowest quantum yield due to aggregation in solution. In general, the benz[e]indolenine hepatemethine cyanines showed high Stokes shifts compared to indolenine dyes. For the meso-chloro dyes, the absorption maxima for the dyes shifted bathochromically in the order of indolenine, benz[e]indolenine and benz[c,d]indolenine.

Benz[e]indolenine

Near-infrared

Heptamethine cyanine dyes

Fluorescence

Indolenine

Photophysical properties

Chemistry

Charge-transfer excitations and phtophysical properties of molecular building blocks

Rubio Pons, Oscar

January 2005

This thesis reports a state-of-the-art theoretical study of photophysical properties of organic charge-transfer aromatic molecules. These molecules are building blocks of molecular functional materials used in modern photonics technology and play essential roles in chemistry and biology in general. A good understanding of these systems is thus important. The theoretical results for permanent dipole moments of some substituted benzenes have been obtained using the coupled cluster singles and doubles (CCSD) method. The performance of density functional theory (DFT) for the geometry and electronic properties has been compared with that of traditional ab initio methods, such as Hartree-Fock, second-order Möller Plesset perturbation theory (MP2), CCSD and CCSD(T). Limitations of the DFT methods for charge transfer molecules have been demonstrated. The multi-configuration self-consistent field (MCSCF) method has been applied to understand properties of the triplet states of benzene derivatives by studying their phosphorescence with the inclusion of contributions from vibronic coupling. It has also been employed to calculate the photophysics of the thioxanthone molecule containing three benzene rings in combination with the CASPT2 method, resolving a long-standing problem concerning the possible stable conformations of the molecule. With knowledge of the building blocks a series of porphyrin derivatives with exceptionally large two-photon absorption cross sections were designed, and proposed for use in bioimaging applications. The static and dynamic properties of a few zinc and platinum organometallic compounds, being possible candidates for optical limiting devices, have also investigated. / QC 20101011

Theoretical chemistry

Photophysical porperties

CCSD

CASSCF

Teoretisk kemi

Theoretical chemistry

Teoretisk kemi

Síntese de Derivados de seleno-aminoácidos e estudos preliminares de sua atividade antioxidante / Synthesis of Selenium Amino Acid Derivatives and Preliminary Study of its Antioxidant Activity

Yuniel Tejeda Mazola

11 August 2017

Há no organismo humano Glutationas peroxidases (GPx), muitas dessas responsáveis por proteger as células contra espécies reativas de oxigênio (ROS, do inglês Reactive Oxygen Species), cuja detecção pode ser realizada por sondas fluorescentes. Tais sondas podem conter em sua estrutura átomos de selênio ou telúrio. Esses calcogênios apresentam várias propriedades, dentre elas a suscetibilidade a processos oxidativos, que podem levar a mecanismos de transferência eletrônica fotoinduzida (PET), promovendo um sistema on/off de fluorescência na molécula. Sendo assim os derivados de selenoaminoácidos e sondas fluorescentes contendo calcogênios podem ser empregados tanto na eliminação de espécies reativas de oxigênio como na sua detecção. O presente trabalho propôs a síntese de derivados de selenoaminoácidos, via reações do tipo Morita-Baylis-Hillman, que poderiam ser empregados como antioxidante. Entretanto, foi também foco da nossa pesquisa explorar a síntese de novos composto organocalcogênios com propriedades fluorescentes e seu estudo fotofísico / Glutathione peroxidases (GPx) are enzymes present in the human body, and many of them are responsible for protecting cells against reactive oxygen species (ROS), which can be detected by fluorescent probes. Selenium or tellurium atoms can be present in these probes and are susceptible to oxidative processes, which can lead to photoinduced electron transfer mechanism (PET). These mechanisms can promote an on/off fluorescence system, thus, selenium amino acids derivatives and fluorescent probes containing chalcogens can be used both in the elimination of reactive oxygen species and their detection. Herein, we proposed the synthesis of selenium amino acids derivatives, vía Morita-Baylis-Hillman reaction, and the products were pointed out as potential antioxidants. In addition, it was also the focus of our research exploring the synthesis of new organochalcogen compounds with fluorescent properties and their photophysical study.

Estudo fotofísico

Morita-Baylis-Hillman

Organocalcogênios

Sondas fluorescentes

Fluorescent probes

Morita-Baylis-Hillman

Organochalcogen

Photophysical study

A Computational Investigation of the Photophysical, Electronic and Bonding Properties of Exciplex-Forming Van der Waals Systems

Sinha, Pankaj

12 1900

Calculations were performed on transition-metal complexes to (1) extrapolate the structure and bonding of the ground and phosphorescent states (2) determine the luminescence energies and (3) assist in difficult assignment of luminescent transitions. In the [Pt(SCN)4]2- complex, calculations determined that the major excited-state distortion is derived from a b2g bending mode rather than from the a1g symmetric stretching mode previously reported in the literature. Tuning of excimer formation was explained in the [Au(SCN)2]22- by interactions with the counterion. Weak bonding interactions and luminescent transitions were explained by calculation of Hg dimers, excimers and exciplexes formed with noble gases.

Photophysical

Van der Waals

luminescence

Van der Waals forces.

Transition metal complexes.

Phosphorescence.

Luminescence.

DENSITY FUNCTIONAL THEORY STUDIES OF PHOTOINDUCED ELECTRON EXCITATION AND TRANSFER OF ORGANIC DYES FOR PHOTODYNAMIC THERAPY, SOLAR CELLS, AND FLUORESCENCE SENSOR APPLICATIONS

Weerasinghe, Krishanthi Chandima

01 August 2016

The main aim of work presented here is to understand photophysical processes of organic dyes and to design better organic molecules/systems which can be applied in many applications such as solar cells, photodynamic therapy, and fluorescence sensors. Developments of novel multichromophore organic materials for the above mentioned applications were made using computational tools. A brief description of the history of computational chemistry was given based on the photochemistry of organic dyes in the introductory chapters and also the importance of basis sets and functionals was discussed in order to produce accurate computational results. Density functional theory (DFT) and time-dependent DFT (TDDFT) calculations were performed to understand the photophysical processes in the porphyrin-perylene bisimide (HTPP-PDI) dyad that exhibited long-lived triplet states. The DFT results show that breaking the rigidity of PDI in HTPP-PDI was responsible for the generation of long-lived triplet states. Furthermore, six porphyrin derivatives were designed by introducing a 4,4’-dicarboxybutadienyl functional group to the porphyrin moiety and studied to investigate the substituent effects on the non-coplanarity, molecular orbitals, and excitation wavelength of the porphyrin donor. Five of the six proposed porphyrin derivatives are promising donors in the HTPP-PDI dyad to replace HTPP for its potential use in photodynamic therapy. Six donor- accepter(s) systems were designed for their potential application in solar cells. Four D-A1-A2 architectural triads, MTPA-TRC-AEAQ, MTPA-TRC-HTPP, MTPA-TRC-PDI, and MTPA-TRC-PBI were designed. The cascade electronic energy levels were obtained and experimentally observed, which lead to sequential electron transfers from 1MTPA* to TRC and then to AEAQ (HTPP/PDI/PBI) module as well as a hole transfer from 1AEAQ*(1HTPP*/1PDI*/1PBI*) to MTPA module. Therefore, all the D-A1-A2 systems we have designed are ambipolar. Interestingly, the lifetime of charge separated states of the newly designed MTPA*+-TRC-AEAQ*- was elongated to 650 ns, an eightfold of that of the donor-acceptor MTPA-TRC parent molecule (80 ns). However, different charge separated state lifetimes were obtained for MTPA*+-TRC-PDI*-(22ns) and MTPA*+-TRC-PBI*-(75ns). The photophysical results suggested that the charge separated state may decay to the triplet state when the charge separated state exhibits a higher energy level than the triplet state. Further, the photovoltaic tests indicated potential applications of MTPA-TRC-AEAQ in solar cells. DFT and TDDFT calculations were performed together with experimental studies to explore the nature of fluorescence enhancement in the anthracene-based sensor after the addition of Zn2+. A 23-fold fluorescence emission was quenched via non-radiative decay pathway in the absence of Zn2+. However, when the Zn2+ chelated to the sensor fluorescence intensity was increased remarkably. A 32-fold fluorescence increase was overserved and calculation results suggested this could be due to the inhibition of the electron-transfer pathway and enhanced rigidity of sensor-Zn2+ complex. The response selectivity of Zn2+ over Ca2+, Mg2+, Cu2+, and Hg2+ ions was also studied using DFT calculations and it was found that Zn2+ has a strong binding affinity to the sensor, which could be a potential application in the detection of Zn2+.

Computational Chemistry

DFT

Fluorescence Sensors

Organic Dyes

Photophysical Studies

Solar Cells

PHOTOCHEMISTRY AND PHOTOPHYSICAL CHARACTERIZATION OF PORPHYRIN & N-CONFUSED PORPHYRIN DYADS: PORPHYRIN PHOTOPHYSICAL PROPERTIES AND ELECTRON AND ENERGY TRANSFER

Alemán, Elvin A.

January 2006

No description available.

Chemistry, Physical

Porphyrin Photophysical Properties

N-Confused Porphyrin

Electron Transfer

Energy Transfer

Effect of Side Chains on Organic Donor (D) and Acceptor (A) Complexes and Photophysical Properties of D-A Dyads

Bheemaraju, Amarnath

01 September 2011

This dissertation aims to understand the effect of incompatible side chains on the complexes of pi-conjugated electron-rich donors and electron-deficient acceptors in solution. The role of incompatible side chains were studied in simple mixtures of organic donor and acceptor molecules that form donor-acceptor complexes. The incompatible branched and linear alkane side chains on the acceptor and donor respectively prevented complex formation between naphthalene diimide acceptor and naphthalene ether donor. However, the incompatible hydrocarbon-fluorocarbon and polar-non polar side chain pairs did not affect complex formation between the donor and acceptor. In quaterthiophene-naphthalene diimide dyads, the incompatibility of the side chain on the acceptor with respect to the side chain on the donor do not have any influence on the donor-acceptor complex formation. Irrespective of the attached side chains, all the dyads show charge transfer absorption bands and have similar electron transfer rates. The effect of point of attachment of the acceptor to the donor in the quaterthiophene-flavin dyad is also studied.

donor-acceptor complex

donor-acceptor dyad

electron transfer

photophysical properties

quaterthiophene

side chains

Chemistry

Design, Synthesis, Photophysical, and Electrochemical Studies of Novel Cyclometalated Pyrazolate-Bridged Dinuclear Platinum(II) Complexes

Chakraborty, Arnab

28 March 2014

No description available.

Chemistry

Synthesis

Cyclometalated complexes

Photophysical characterization

Electrochemical study

Understanding the Thermal Stability and Environmental Sensitivity of Phycocyanin using Spectroscopic and Modelling Tools

Toong, Cally

25 October 2018

Phycocyanin (PC), a pigment-protein conjugate from Arthrospira platensis, is increasingly used in foods as a natural alternative to artificial blue dyes. Although PC has been classified as a color additive exempt from certification by the Food and Drug Administration, its limited stability has hindered its widespread application in food products. The objectives of this study were: a) to evaluate the photophysical properties of PC and their sensitivity to temperature, viscosity, and water activity, b) to monitor PC’s thermal degradation based on changes in the optical properties of its intrinsic fluorophores, namely its chromophores and aromatic amino acids, and c) to extract PC’s thermal degradation kinetics parameters from non-isothermal degradation profiles and validate their predictive ability. PC’s photophysical properties were monitored in solutions with viscosities from 1 to8000 mPa s and water activities, aw, from about 0 to 1. PC’s emission intensity showed high sensitivity to aw above 0.8 and mild sensitivity to the viscosity of its local environment. The effect of temperature on PC’s photophysical properties was tested in aqueous PC solutions (0.5 mM, pH: 6.1) subjected to non-isothermal temperature profiles with target temperatures from 42.5 to 80°C. The stability of PC was monitored in terms of its photophysical properties, i.e., fluorescence emission intensity, energy, and anisotropy (r) of its chromophore at set time intervals. Additionally, the photophysical properties of PC’s aromatic amino acids (AAs) tyrosine and tryptophan (lexc: 280 and 295 nm) were recorded. The thermal degradation kinetics of PC was assumed to follow a Weibullian model, and the temperature dependence of the degradation rate parameter, b(T), a logarithmic exponential model. Changes of PC fluorescence intensity under dynamic conditions were used to extract the degradation kinetics parameters using the endpoints method. Deviations between the estimated and experimental values were less than 10% for all temperature profiles. During thermal treatments, hypsochromic shifts of AAs’ emission spectra (from 340 to 315 nm) and significant increases in fluorescence anisotropy revealed that color losses were not solely associated with an alteration of the chromophore but with conformational changes and possible aggregation of the protein subunits. An increase in viscosity of the surrounding media provided a protected effect on discoloration during heating. Adequate modeling approaches and molecular spectroscopic techniques can help to develop effective strategies to enhance thermal stability, expand its use as a color and functional ingredient and operationalize it as an endogenous sensor of food quality.

phycocyanin

fluorescence

thermal stability

degradation kinetics

photophysical properties

natural color

Food Science