Design and Fabrication of Nanostructures for the Enhancement of Photovoltaic Devices

Prevost, Richard M, III

19 May 2017

In 2012 the net world electricity generation was 21.56 trillion kilowatt hours. Photovoltaics only accounted for only 0.1 trillion kilowatt hours, less than 1 % of the total power. Recently there has been a push to convert more energy production to renewable sources. In recent years a great deal of interest has been shown for dye sensitized solar cells. These devices use inexpensive materials and have reported efficiencies approaching 12% in the lab. Here methods have been studied to improve upon these, and other, devices. Different approaches for the addition of gold nanoparticles to TiO2 films were studied. These additions acted as plasmonic and light scattering enhancements to reported dye sensitized devices. These nanoparticle enhancements generated a 10% efficiency in device performance for dye sensitized devices. Quantum dot (QD) sensitized solar cells were prepared by successive ionic layer adsorption and reaction (SILAR) synthesis of QDs in mesoporous films as well as the chemical attachment of colloidal quantum dots using 3-mercaptopropionic acid (3-MPA). Methods of synthesizing a copper sulfide (Cu2S) counter electrode were investigated to improve the device performance. By using a mesoporous film of indium tin oxide nanoparticles as a substrate for SILAR growth of Cu2S catalyst, an increase in device performance was seen over that of devices using platinum. These devices did suffer from construction drawbacks. This lead to the development of 3D nanostructures for use in Schottky photovoltaics. These high surface area devices were designed to overcome the recombination problems of thin film Schottky devices. The need to deposit a transparent top electrode limited the success of these devices, but did lead to the development of highly ordered metal nanotube arrays. To further explore these nanostructures depleted heterojunction devices were produced. Along with these devices a new approach to depositing lead sulfide quantum dots was developed. This electrophoretic deposition technique uses an applied electric field to deposit nanoparticles onto a substrate. This creates the possibility for a low waste method for depositing nanocrystals onto nanostructured substrates.

quantum dots

solar cells

gold nanowire arrays

electrophoretic deposition

SILAR

Inorganic Chemistry

Materials Chemistry

Incorporation of Gold Nanowires into Photovoltaic Devices

Gordon, Scott W

23 May 2019

To this day, fossil fuels still make up over 80% of the earth’s energy production. Many sources of renewable energy are available, but photovoltaics is the only source with the capacity proven to meet the increasing world energy needs. Third generation devices such as dye-sensitized and organic solar cells have gained much interest due to their cost effectiveness and flexibility but have yet to become commercially viable. Here methods have been studied to improve these devices with the use of Gold nanowire arrays. These additions provide plasmonic and light scattering enhancements in dye-sensitized solar cells. Different TiO2 deposition methods have been studied to protect the gold from the redox couple in the electrolyte. Several novel methods have been undertaken to incorporate gold nanowire arrays in organic solar cells with some success. Structural characterization shows the proposed architecture is achieved, but working devices met suffered from low success rate.

dye-sensitized solar cells

organic photovoltaics

gold nanowire arrays

Materials Chemistry

Optics and spectroscopy of gold nanowires

Vasanthakumar, Priya

14 May 2012

We have reported the optical properties of isolated gold nanowires and of nanowire arrays. Despite the advantages gold has to offer as it is less sensitive to oxidation and as an biocompatible metal, it has been scarcely studied than silver or semiconductors nanowires. We have made surface enhanced Raman spectroscopic (SERS) studies on the isolated nanowires and nanowire arrays. Single molecule regime is attained and has been proven with the aid of two dye molecules that are co-deposited. The propagation of surface plasmons in these nanowires and their evolution with the excitation wavelength have been studied. We report a propagation distance of 3.8 µm which is longer than the values previously reported in literature. Nanowire arrays have been investigated with two dyes again to disentangle the various factors contributing to SERS. Polarization studies and the evolution of enhancement in the nanowires with the wavelength have been reported and explained with the aid of simulations obtained by the discrete dipole approximation (DDA). The scanning near field optical microscopy (SNOM) has been done to investigate the local field enhancements on the nanowire arrays. Two different polarizations and two excitation wavelengths have been used. The original idea of the technique includes the use of two illumination modes which serves two purposes. One, to map the regions of enhanced field and the other to study the propagation effects seen on the nanowire.

Gold Nanowire

Gold nanowire arrays

Plasmon propagation

SM-SERS

SNOM

Co-deposition

ATTO 740

Optics and spectroscopy of gold nanowires / Propriétés optiques et spectroscopiques de nanofils d'or

Vasanthakumar, Priya

14 May 2012

Les études portent sur les propriétés optiques de nanofils d’or individuels et de réseaux de nanofils d’or. Malgré ses avantages, comme une sensibilité moindre à l’oxydation et sa biocompatibilité, les nanofils en or ont été peu étudiés par comparaison avec les nanofils en argent ou semiconducteurs. Les études sur ces substrats ont été réalisées par spectroscopie Raman exaltée de surface (SERS). Le régime de la molécule unique est atteint, ce que j’ai démontré en utilisant deux molécules différentes de colorant, co-déposées. J’ai étudié la propagation des plasmons de surface dans les nanofils ainsi que son évolution en fonction de la longueur d’onde. Une distance de propagation de 3,8 µm a été observée, plus grande que les valeurs précédemment rapportées. Les réseaux de nanofils ont également été étudiés en combinant la réponse de deux molécules pour démêler les différents processus contribuant au signal de la diffusion Raman. Les résultats obtenus par des études en polarisation et en fonction de la longueur d’onde sur l’évolution de l’intensité du signal SERS ont été confrontés aux résultats de simulations réalisées par la méthode de l’approximation des dipôles discrets (DDA). La microscopie de champ proche optique à balayage (SNOM) a été mise en œuvre pour étudier les effets d’exaltation locale sur les réseaux de nanofils. Ces études ont été réalisées avec deux polarisations croisées et à deux longueurs d’onde différentes. L’originalité des études SNOM repose sur l’utilisation de deux modes différents d’éclairement. L’un est utilisé pour cartographier l’exaltation des champs électromagnétiques, l’autre pour étudier les effets de propagation des plasmons dans les nanofils. / We have reported the optical properties of isolated gold nanowires and of nanowire arrays. Despite the advantages gold has to offer as it is less sensitive to oxidation and as an biocompatible metal, it has been scarcely studied than silver or semiconductors nanowires. We have made surface enhanced Raman spectroscopic (SERS) studies on the isolated nanowires and nanowire arrays. Single molecule regime is attained and has been proven with the aid of two dye molecules that are co-deposited. The propagation of surface plasmons in these nanowires and their evolution with the excitation wavelength have been studied. We report a propagation distance of 3.8 µm which is longer than the values previously reported in literature. Nanowire arrays have been investigated with two dyes again to disentangle the various factors contributing to SERS. Polarization studies and the evolution of enhancement in the nanowires with the wavelength have been reported and explained with the aid of simulations obtained by the discrete dipole approximation (DDA). The scanning near field optical microscopy (SNOM) has been done to investigate the local field enhancements on the nanowire arrays. Two different polarizations and two excitation wavelengths have been used. The original idea of the technique includes the use of two illumination modes which serves two purposes. One, to map the regions of enhanced field and the other to study the propagation effects seen on the nanowire.

Nanofil en or

Réseau de nanofils en or

Propagation de plasmons

SM-SERS

Microscopie de champ proche optique

Co-déposition

ATTO 740

Gold Nanowire

Gold nanowire arrays

Plasmon propagation

SM-SERS

SNOM

Co-deposition

ATTO 740