Non-conjugate potential-stepping phenothiazine and phenoxazine based polymer hole-transport material for dye-sensitized solar cells & increasing void space in porous TiO2: to study diffusion properties of a cobalt mediator

Abstract

As energy demands increase so has the search for alternative sources of energy. Although, fossil fuels have proven useful in energy production, they are also detrimental due to the negative impact on our environment. Considering the current alternative energy sources, such as wind, hydroelectric, biofuels, etc, one source of alternative energy shines above the rest, solar energy. Solar energy provides a possible solution to the energy demands of our modern world with little effect on the environment. The only waste produced from the solar cell industry is from producing and recycling the cells. After production, solar cells require no resources to function other than solar radiation, and no waste is produced. The sun has been powering life on this planet for billions of years, and bombards the earth with 3x1024 J of energy per year. Only 0.02% of this energy is currently needed to power the world, thus making the sun a viable solution to energy demands, while decreasing current pollution issues. This thesis focuses on dye sensitized solar cell (DSSCs), in particular, the Grätzel cell, which incorporates thin films of TiO2 as the semiconductor, DSSC's work very similarly to a battery, but instead of using chemical energy to drive electrons through the circuit, it uses photons. Several issues have arisen with these types of solar cells and their use in the modern world. One particular problem is that the iodide/triiodide (I-/I3-) mediator, which currently produces the most efficient DSSCs, is corrosive and volatile. To address this and other issues, a conductive phenothiazine (PTZ) and phenoxazine (POZ) based polymer is hypothesized to be a suitable replacement for the mediator and solvent by acting as a charge separator and hole transport material, without any volatile or corrosive problems. This polymer would hypothetically function similarly to proposed electron transport in DNA. When charges are injected into a DNA strand they are transferred through π-stacking interactions at the center of the helix, which allows electrons to tunnel through the DNA strand. A potential-stepping block co-polymer incorporating phenothiazine (PTZ) and phenoxazine (POZ) groups attached to the polymer backbone can π-stack like the base pairs in DNA. By creating a two-block co-polymer, with one composed of PTZ monomers and the other of POZ monomers, charge separation can be achieved by trapping the hole on the POZ groups due to their more negative oxidation potentials. This potential-stepping polymer charge separator is the focus of the first part of this thesis. The second section of this thesis is centered on diffusion issues in DSSCs where the I-/ I3- mediator is replaced with tris((2,2'-bipyridyl-4,4'-di-tert-butyl)cobalt(III) perchlorate, CoDTB+3 (ClO4-)3 (DTB = 4,4'-di-tert-butyl-2,2'-bipyridine). The cobalt mediator has many advantages: it is non-corrosive, non-volatile, and it is able to be tuned to optimize the electron transfer process to the dye by simple structural modifications of the ligand. However, cobalt mediators have small diffusion coefficients on the order of 1x10-7 cm2 s-1 or less in TiO2 mesoporous thin films. It has been hypothesized that changing the structure of the TiO2 layer or increasing the void space in the films in the correct manner may dramatically increase the effective rate of diffusion. The introduction of appropriate void space will hypothetically create channels and allow faster diffusion of the mediator. The second half of this thesis explores the effects of introducing void space into TiO2 thin films using various nanoparticles.