The Golden Fig: A Plasmonic Effect Study of Organic-Based Solar Cells

An optimization work on dye-sensitized solar cells (DSSCs) based on both artificial and natural dyes was carried out by a fine synthesis work embedding gold nanoparticles in a TiO2 semiconductor and perfecting the TiO2 particle sizes of the scattering layer. Noble metal nanostructures are known for the surface plasmon resonance peculiarity that reveals unique properties and has been implemented in several fields such as sensing, photocatalysis, optical antennas and PV devices. By embedding gold nanoparticles in the mesoporous TiO2 layer and adding a scattering layer, we were able to boost the power conversion efficiency (PCE) to 10.8%, using an organic ruthenium complex. The same implementation was carried out using a natural dye, betalains, extracted from Sicilian prickly pear. In this case, the conversion efficiency doubled from 1 to 2% (measured at 1 SUN illumination, 100 mW/cm2 under solar simulation irradiation). Moreover, we obtained (measured at 0.1 SUN, 10 mW/cm2 under blue light LED irradiation) a record efficiency of 15% with the betalain-based dye, paving the way for indoor applications in organic natural devices. Finally, an attempt to scale up the system is shown, and a betalain-based- dye-sensitized solar module (DSSM), with an active area of 43.2 cm2 and a PCE of 1.02%, was fabricated for the first time.

The Use of Ruthenium Complexes as Molecular Probes for Non-Canonical DNA

This study considered the preparation of a new DNA binding Ruthenium polypyridyl complex possessing an infrared active nitrile group. The binding abilities of a novel Ruthenium complex, [Ru(TMP)2DPPZ-10-CN], to various forms of DNA—both canonical and non-canonical—were examined by performing multiple DNA titrations. DNA is of great interest as it is the carrier of genetic information for all living things. Damage to DNA can have drastically detrimental effects, so the study of its structure and replication is of great importance. Two non-canonical structures that are important are the G-quadruplex and i-motif which form at the telomeric and regulatory regions of genes, respectively, and have the ability to block telomerase activity and influence transcription. The complex was synthesized by microwave irradiation and purified using a silica column and an ion exchange with Amberlite 402. Six titrations were, then, performed with salmon sperm dsDNA, guanine monophosphate (GMP), G4T4G4, human telomere G-quadruplex, i-motif C5T3, and i-motif C30. The complex was found to favor non-canonical structures, particularly the G-quadruplex structure, because of its high [bp]/[Ru] concentrations. The higher concentration of base pairs or structures per Ruthenium molecule indicated that the complex had a high binding affinity for that particular DNA structure. These results support the notion that Ruthenium metal complexes can be used for theragnostic purposes and can be used to target the telomeric region of genes where G-quadruplex structures can be found and influence transcription initiation and inhibit telomerase activity.

The Use of Ruthenium Complexes as Molecular Probes for Non-Canonical DNA” by Eleni Sullivan

This study considered the preparation of a new DNA binding Ruthenium polypyridyl complex possessing an infrared active nitrile group. The binding abilities of a novel Ruthenium complex, [Ru(TMP)2DPPZ-10-CN], to various forms of DNA—both canonical and non-canonical—were examined by performing multiple DNA titrations. DNA is of great interest as it is the carrier of genetic information for all living things. Damage to DNA can have drastically detrimental effects, so the study of its structure and replication is of great importance. Two non-canonical structures that are important are the G-quadruplex and i-motif which form at the telomeric and regulatory regions of genes, respectively, and have the ability to block telomerase activity and influence transcription. The complex was synthesized by microwave irradiation and purified using a silica column and an ion exchange with Amberlite 402. Six titrations were, then, performed with salmon sperm dsDNA, guanine monophosphate (GMP), G4T4G4, human telomere G-quadruplex, i-motif C5T3, and i-motif C30. The complex was found to favor non-canonical structures, particularly the G-quadruplex structure, because of its high [bp]/[Ru] concentrations. The higher concentration of base pairs or structures per Ruthenium molecule indicated that the complex had a high binding affinity for that particular DNA structure. These results support the notion that Ruthenium metal complexes can be used for theragnostic purposes and can be used to target the telomeric region of genes where G-quadruplex structures can be found and influence transcription initiation and inhibit telomerase activity.

Fabrication of Covalently Linked Ruthenium Complex Onto Carbon Nitride Nanotubes For The Photocatalytic Degradation of Tetracycline Antibiotic

Due to the problem of direct disposal of effluents contains antibiotics to the environment and the emergence of resistant bacterial pathogens, the wastewater treatment of pharmaceutical industry has known as an importance research background. In this study, the refinement and photodegradation ability of one of the most widely used antibiotics, “tetracycline” was investigated by ruthenium complex immobilized on the modified graphitic carbon nitride nanotubes. For this purpose, graphitic carbon nitride nanotubes (g-C3N4 NTs) were successfully synthesized by the hydrothermal method and functionalized with 1,10-Phenantroline-5,6-dione ligand during another step. Then, the functionalized g-C3N4 NTs were reinforced with immobilization of dichloro(p-cymene)ruthenium(II) dimer. The structure and morphology of the prepared photocatalyst was studied by X-ray diffraction (XRD), fourier transform infrared (FT-IR), scanning, and transmission electron microscopy (SEM & TEM) analyses. In the following, the photocatalyst's ability to optically degrade the tetracycline antibiotics was performed in a suspension reactor equipped with a LED lamp (60 W) and effective parameters such as the amount of catalyst, irradiation time, temperature, and pH were optimized. The results showed that the immobilization of Ru complex onto functionalized g-C3N4 NTs improved the photocatalytic activity and increased the degradation efficiencies to amount 43%. Furthermore, COD analysis was used for the determination of the amount of mineralization and results showed that the mineralization of 10 mg/L tetracycline solution of about 90% can be performed using 20 mg of Ru (II) complex/ g-C3N4 NTs at pH=7 after 480 min without any additive oxidant.