Synthesis and Characterization of High-Photoactivity Electrodeposited Cu2O solar absorber by photoelectrochemistry and ultrafast spectroscopy

We present a systematic study on the effects of electrodeposition parameters on the photoelectrochemical properties of Cu2O. The influence of deposition variables (temperature, pH, and deposition current density) on conductivity has been widely explored in the past for this semiconductor, but the optimization of the electrodeposition process for the photoelectrochemical response in aqueous solutions under AM 1.5 illumination has received far less attention. In this work, we analyze the photoactivity of Cu2O films deposited at different conditions and correlate the photoresponse to morphology, film orientation, and electrical properties. The photoelectrochemical response was measured by linear sweep voltammetry under chopped simulated AM 1.5 illumination. The highest photocurrent obtained was −2.4 mA cm−2 at 0.25 V vs RHE for a film thickness of 1.3 μm. This is the highest reported value reached so far for this material in an aqueous electrolyte under AM 1.5 illumination. The optical and electrical properties of the most photoactive electrode were investigated by UV−vis spectroscopy and electrochemical impedance, while the minority carrier lifetime and diffusion length were measured by optical-pump THz-probe spectroscopy

Photoinduced processes in lead iodide solid-state solar cells

Organic-inorganic hybrid systems based on lead halide compounds have recently encountered considerable success as light absorbers in solid-state solar cells. Herein we show how fundamental mechanistic processes in mesoporous oxide films impregnated with CH3NH3PbI3 can be investigated by time resolved techniques. In particular, charge separation reactions such as electron injection into the titanium dioxide film and hole injection into the hole transporting material spiro-OMeTAD as well as the corresponding charge recombination reactions were scrutinized. Femtosecond transient absorption spectroscopy and time-resolved terahertz spectroscopy were applied to CH3NH3PbI3 deposited either on TiO2 or Al2O3 mesoporous films and infiltrated with the hole transporting material spiro-OMeTAD

Dynamics and mechanisms of interfacial photoinduced electron transfer processes of third generation photovoltaics and photocatalysis

Photoinduced electron transfer (PET) across molecular/bulk interfaces has gained attention only recently and is still poorly understood. These interfaces offer an excellent case study, pertinent to a variety of photovoltaic systems, photo- and electrochemistry, molecular electronics, analytical detection, photography, and quantum confinement devices. They play in particular a key role in the emerging fields of third-generation photovoltaic energy converters and artificial photosynthetic systems aiming at the production of solar fuels, creating a need for a better understanding and theoretical treatment of the dynamics and mechanisms of interfacial PET processes. We aim at achieving fundamental understanding of these phenomena by designing experiments that can be used to test and alter modern theory and computational modeling. One example illustrating recent investigations into the details of the ultrafast processes that form the basis for photoinduced charge separation at a molecular/bulk interface relevant to dye-sensitized solar cells is briefly presented here. Kinetics of interfacial PET and charge recombination processes were measured by fs and ns transient spectroscopy in a heterogeneous donor-bridge-acceptor (D-B-A) system, where D is a RuII(terpyridyl-PO3)(NCS)3 complex, B an oligo-p-phenylene bridge, and A nanocrystalline TiO2. The forward ET reaction was found to be faster than the vibrational relaxation of the vibronically excited state of the donor. Instead, the back ET occurred on the μs time scale and involved fully thermalized species. The D-A distance dependence of the electron transfer rate was studied by varying the number of p-phenylene units contained in the bridge moiety. The remarkably low damping factor β = 0.16 Å–1 observed for the ultrafast charge injection from the dye excited state into the conduction band of TiO2 is attributed to the coupling of electron tunneling with non-equilibrium vibrations redistributed on the bridge, giving rise to polaronic transport of charges from the donor ligand to the acceptor solid oxide surface

Linear and Time-Resolved THz Spectroscopy of Photonic and Charge Transporting Systems

Photo-induced charge separation and charge transport are fundamental processes in many energy conversion techniques, where light is converted into chemical energy (PEC), into electrical energy (solar cells) or in the opposite sense if electrical energy is converted into light (LEDs). In all cited examples, charge carriers have either to be transported towards an interface where they can undergo radiative recombination, trigger a chemical reaction, or they have to be evacuated from the interface as free charge carriers to be able to perform work in an external electrical circuit. In this work the charge generation dynamics and transport is studied using THz time domain spectroscopy and complimentary techniques on systems finding application in dye sensitized solar cells and PEC cells for water splitting. The functioning of a dye sensitized solar cell is based on the kinetic competition between several reactions, i.e. electron injection, dye-regeneration, electron back- reaction and charge extraction. Accordingly the rates of all of these reactions have to be optimized in order to optimize the cell performance. This requires a good understanding of the underlying mechanism of these processes. In photochemical cells, the encountered processes are in a way similar. After initial excitation, the generated charges have to be separated and have to reach either the interface to the electrolyte or the external circuit before being annihilated by recombining. Knowing the diffusion length and carrier lifetime in a specific material might therefore be helpful to optimize the film morphology, i. e. the aspect ratio. Chapter 1 gives an overview over the functioning of DSCs and PEC cells and summarizes some theoretical aspects of the processes encountered in these devices. Chapter 2 is devoted to the description of the experimental tools used and built in this work. In chapter 3, charge transport in a liquid molecular hole conductor, 10- methylphenoxazine, is investigated. The transport is rationalized using a model taking into account ionic diffusion and intermolecular hole transfer, i. e. hopping. It is found that the conduction occurs principally by hopping, as the HTM cation seems to be mainly present in an ion-paired form with the anion from the doping agent. Hopping of charge requires molecular vibration to bring acceptor and donor molecule in electronic resonance. Two vibrational modes of the HTM cation and neutral molecules that might be coupled to charge transport are observed. In chapter 4, electron injection from a dye into the conduction band of TiO2 films is investigated by monitoring the appearance of the free electron. This signal is compared to the signal arising from direct UV excitation of the TiO2. In addition to previous studies done in the group, the effect of dye aggregation leading to decelerated electron injection is investigated. Comparing the THz signal amplitude to the injected charge carrier concentration, the THz mobility in TiO2 films was found to be 0.1-0.15 cm2V-1s-1 and constant over the investigated charge carrier concentrations. Furthermore the influence of sintering temperature of the TiO2 film has been addressed in a preliminary study. In chapter 5, the influence of liquid electrolytes, of a solid state hole conducting material and of the commonly used additives Li+ and tBP on the charge generation dynamics have been investigated. While in this work the presence of an electrolyte/HTM has not shown any influence on the electron injection dynamics, the generation of the free electron seems to be strongly dependent on the molecular surrounding. This discrepancy is discussed in terms of a coulombic bound electron- hole pair as an intermediate state in the electron injection dynamics. Chapter 6 contains a study on the charge carrier dynamics in cuprous oxide, being used as material for photoelectrochemical water splitting. The wavelength and fluence dependence on the charge carrier lifetime, mobility and diffusion length was studied. The strong dependence of the charge carrier lifetime is discussed in terms of trapping mediated recombination

Solubility and Crystallizability: Facile Access to Functionalized pi-Conjugated Compounds with Chlorendylimide Protecting Groups

Functional pi-conjugated molecules are relevant for the preparation of new organic electronic materials with improved performance. However, their synthesis is often rendered difficult by their inherently low solubility, and the permanent attachment of solubilizing groups may change the properties of the material. Here, we introduced the chlorendylimidyl moiety as a new temporary protecting group for the straightforward large-scale synthesis of protected quarter-, sexi-, octathiophene, and perylene bisimide diamine and dicarboxylic acid derivatives. The obtained chlorendylimides and chlorendylimidyl active esters were highly soluble in organic solvents, and optical spectroscopy confirmed the low tendency of the compounds to aggregate in solution. At the same time, they could be conveniently purified by recrystallization or precipitation. Single-crystal X-ray structures obtained for most compounds showed supramolecular motifs highlighting the role of the rigid, polychlorinated chlorendyl moieties in their crystallization. The obtained protected diamine and dicarboxylic acid derivatives were easily deprotected and converted into various amide-substituted oligothiophenes and perylene bisimides that are of interest as new functional materials for organic electronic thin film or nanowire devices

Synthesis and Characterization of High-Photoactivity Electrodeposited Cu₂O Solar Absorber by Photoelectrochemistry and Ultrafast Spectroscopy

We present a systematic study on the effects of electrodeposition parameters on the photoelectrochemical properties of Cu₂O. The influence of deposition variables (temperature, pH, and deposition current density) on conductivity has been widely explored in the past for this semiconductor, but the optimization of the electrodeposition process for the photoelectrochemical response in aqueous solutions under AM 1.5 illumination has received far less attention. In this work, we analyze the photoactivity of Cu₂O films deposited at different conditions and correlate the photoresponse to morphology, film orientation, and electrical properties. The photoelectrochemical response was measured by linear sweep voltammetry under chopped simulated AM 1.5 illumination. The highest photocurrent obtained was −2.4 mA cm^–2 at 0.25 V vs RHE for a film thickness of 1.3 μm. This is the highest reported value reached so far for this material in an aqueous electrolyte under AM 1.5 illumination. The optical and electrical properties of the most photoactive electrode were investigated by UV–vis spectroscopy and electrochemical impedance, while the minority carrier lifetime and diffusion length were measured by optical-pump THz-probe spectroscopy

Outcomes in Newly Diagnosed Atrial Fibrillation and History of Acute Coronary Syndromes: Insights from GARFIELD-AF

BACKGROUND: Many patients with atrial fibrillation have concomitant coronary artery disease with or without acute coronary syndromes and are in need of additional antithrombotic therapy. There are few data on the long-term clinical outcome of atrial fibrillation patients with a history of acute coronary syndrome. This is a 2-year study of atrial fibrillation patients with or without a history of acute coronary syndromes