Interface Studies of Small-Molecule Organic Photovoltaics; Surface Modifications, Electron Donor Texturing, and Co-Facial Variations at the Donor/Acceptor Heterojunctions

Placencia, Diogenes

January 2011

The role of the oxide/organic and organic/organic interfaces in small-molecule planar-Heterojunction (PHJ) photovoltaics was investigated with three interrelated projects: i) indium-tin oxide (ITO) bottom contact electrodes were modified with gold nanoparticles (Au-NPs) to improve rates of charge-transfer at the donor/oxide interface, ii) donor layers in OPVs were textured to increase charge generation at the organic/organic' interface, and iii) the effect of co-facial overlap on device performance via tuning of the electron acceptor orientation at the organic/organic interface. The modification of ITO with Au-NPs showed increased performance in small-molecule OPVs when compared to non-processed ITO devices due to the interactions between the Au-NPs and the donor material. Textured TiOPc increased overall device performance by a factor of 2X via the increased surface area, near-IR absorption, and increased mobilities. Modified and un-modified PTCDA acceptors showed that co-facial overlap at the organic/organic' interface is a large determinant in device performance, while the performance in small-molecule planar-heterojunction photovoltaics were severely affected by the pre-treatment process, most likely due to the particular interactions between the oxide and the donor material.

phthalocyanine

titanyl phthalocyanine

Chemistry

gold nanoparticles

photovoltaics

Gold nanoparticle uptake in synchronized cell populations and the effect on radiation sensitization

Rieck, Kristy

16 April 2019

To overcome the challenge in radiation therapy of delivering the prescribed dose to cancer cells while sparing normal tissue, preferential introduction of high Z material to tumour cells works as a method of radiation sensitization. Gold nanoparticles (GNPs) are very useful in this respect. It has been shown that the size, shape, and surface properties of GNPs affect their cellular uptake. Manipulation of the cell cycle to arrest cells at different stages offers a unique strategy to study the molecular and structural events as the cell cycle progresses. To optimize delivery of GNPs into tumour cells and enhance the effect of radiosensitization, nanoparticle (NP) uptake in synchronized populations of MDA-MB-231 breast cancer cells was investigated. Populations of MDA-MB-231 cells were first synchronized in S-phase using double-thymidine block, and allowed to progress through cell cycle in synchronization. Synchronized cells were incubated with 5 nm GNPs, 15 nm GNPs, 46 nm GNPs and two formulations of lipid NP encapsulated 5 nm GNPs. Uptake of NPs was visualized using hyperspectral optical imaging and quantified with inductively coupled plasma mass spectrometry (ICP-MS). Following internalization of GNPs, cells were irradiated with 6 MV photon beams from a linear accelerator, and the survival fraction and induced deoxyribonucleic acid (DNA) damage were studied. Cell cycle analysis after a double-thymidine block showed that the cell population was well synchronized. Uptake of NPs was 1.5-2 times higher in synchronized cell population compared to the control where cells were at different stages of the cell cycle. Clonogenic studies were used to evaluate the cell survival following radiation treatment. After a dose of 2 Gy, there was a decrease in cell survival fraction in synchronized cells treated with GNPs prior to radiation treatment compared to unsynchronized cells (control) indicating GNP-mediated dose-enhancement. The protein γ-H2AX, which is recruited to sites of DNA double strand breaks, was fluorescently labeled to evaluate damage due to the radiation treatment. Our results show more DNA double strand breaks in cells treated with GNPs prior to radiation. Interaction of ionization radiation with GNPs inside of cells produce secondary electrons. These secondary electrons can interact with water molecules and produce additional free radicals. These low energy electrons and free radicals interact with important cell structures and could cause cellular damage. Cell cycle synchronization has been shown to enhance GNP/PEG/RGD uptake in MDA-MB-231 cells resulting in greater cell radiosensitization and cellular damage. Cell synchronization is therefore an additional method available that can be employed to improve GNP uptake in cells. / Graduate

Cell cycle

Radiation therapy

Gold nanoparticles

Study of Self-assembled Gold Nanocluster Patterns in Ion Implanted Silicon: Order from Disorder

Venkatachalam, Dinesh Kumar, Dinesh.Venkatachalam@anu.edu.au

January 2008

Gold (Au) implantation in silicon (Si) has been a topic of great interest from both fundamental and applied perspectives. Ion implantation is a versatile technique due to its ability to form surface-embedded nanoparticles that provide better adhesion. Also, being an integral part of the substrate lattice, the nanoclusters produced by ion implantation are free from impurities and their size distribution can be controlled by carefully optimizing the beam parameters. During our experiments to produce nanoclusters of Au on Si for use as seeds for the growth of nanowires, we stumbled across an unusual pattern formation process under specific conditions. This unique self-assembly process is observed only within a critical threshold implantation fluence and above a threshold annealing temperature. Fabrication of ordered arrays of metal nanoparticles on Si substrates is of significance for both fundamental science associated with low-dimensional physics and technical app lications. The application of functional nanostructures strongly depends on their assembly in ordered one- or two- dimensional arrangements. These arrangements may play an important role in fabricating ordered arrays of semiconductor/oxide nanowires.This thesis discusses a systematic study performed to understand the temperature and time dependent nucleation, growth of Au nanoclusters and evolution of the self-assembled patterns. A growth model is proposed to show the re-crystallization behaviour of Au supersaturated amorphous silicon (a-Si) on Si substrate. The observed self-assembled periodic patterns of Au nanoclusters bear resemblance to the Liesegang ring structures prevalent in some chemical reaction-diffusion systems. Based on this systematic study of the growth and morphology of Au nanoclusters, a tentative growth mechanism has been proposed for the formation mechanism of this unusual self-assembled pattern. The pattern formation of this non-equilibrium process is expected to originate due to instabilities of the three scales of Au nanoclusters at elevated temperatures. The kinetics of pattern formation from a supersaturated solid solution (a-Si/Au alloy) is demonstrated using numerical solutions obtained by a two-dimensional growth model, which takes into account the nucleation, diffusion and the aggregation process. The numerical solution of the diffusion equations appear to be in good agreement with the experimental results.

Self-assembly

gold nanoparticles

silicon

ion implantation

Single Stranded DNA Induced Assembly of Gold Nanoparticles

Yang, Jun, Lee, Jim Yang, Deivaraj, T.C., Too, Heng-Phon

01 1900

The binding affinity of single stranded DNA (ssDNA) for gold nanoparticle surface is studied in this work. The data indicate that the strength of interaction between ssDNA and Au particle surface is closely related to the particle size, with smaller particles (5 nm) producing the most pronounced effects. From these experimental findings, a single stranded DNA (ssDNA) based method to assimilate 13 and 5 nm gold nanoparticles was developed, and verified by transmission electron microscopy (TEM). / Singapore-MIT Alliance (SMA)

self assembly

gold nanoparticles

DNA

oligonucleotides

Adsorption mechanism and dynamical behavior of water molecules surrounding icosahedral Au nanoclusters

Chang, Chia-wei

09 September 2007

Molecular dynamic simulation is utilized to investigate the adsorption mechanism of water molecules surrounding Au nanoparticle of different sizes. We selected 13, 55, 147 atoms icosahedral gold nanopartilce in our model and their diameter are 7.92Å, 13.2Å, 18.5Å, respectively. We calculated density profile of water molecules and found that there were two adsorption layers out of the surface of gold nanoparticles. We also calculated average number of hydrogen bonds per water . It is higer in the adsorption layer than in bulk water region and we found that the direction of hydrogen bonds are numerously parallel with gold surface in the adsorption layer. We also claculated orientational order parameter for water molecules and explore the difference of the tetrahedral structure of the water molecules between the adsorption layer and bulk water region. Besides, we compared of cases of different gold sizes.

water molecules

molecular dynamics

gold nanoparticles

Functionalized gold nanoparticles as probe for reactive oxygen species and heavy metal ions determination

Lin, Cheng-Yan

21 June 2010

none

glucose

ROS

gold nanoparticles

Hg2+

Ag+

Developments of adequate additives for protein separations in capillary electrophoresis and applications of functional nanomaterials for biological and environmental detections in optical nanosensors

Yu, Cheng-ju

26 August 2010

none

Magnetic nanoparticles

Capillary Electrophoresis

Gold Nanoparticles

Colorimetric

none

Su, Chih-lin

14 July 2007

none

Homocysteine

gold nanoparticles

SALDI-MS

glucose

NDA

none

Li, Mu-de

13 July 2009

none

indoleamine

Tween 20

aminothiol

gold nanoparticles

Photothermal Effect in Plasmonic Nanostructures and its Applications

Chen, Xi

January 2014

Plasmonic resonances are characterized by enhanced optical near field and subwavelength power confinement. Light is not only scattered but also simultaneously absorbed in the metal nanostructures. With proper structural design, plasmonic-enhanced light absorption can generate nanoscopically confined heat power in metallic nanostructures, which can even be temporally modulated by varying the pump light. These intrinsic characters of plasmonic nanostructures are investigated in depth in this thesis for a range of materials and nanophotonic applications.   The theoretical basis for the photothermal phenomenon, including light absorption, heat generation, and heat conduction, is coherently summarized and implemented numerically based on finite-element method. Our analysis favours disk-pair and particle/dielectric-spacer/metal-film nanostructures for their high optical absorbance, originated from their antiparallel dipole resonances.   Experiments were done towards two specific application directions. First, the manipulation of the morphology and crystallinity of Au nanoparticles (NPs) in plasmonic absorbers by photothermal effect is demonstrated. In particular, with a nanosecond-pulsed light, brick-shaped Au NPs are reshaped to spherical NPs with a smooth surface; while with a 10-second continuous wave laser, similar brick-shaped NPs can be annealed to faceted nanocrystals. A comparison of the two cases reveals that pumping intensity and exposure time both play key roles in determining the morphology and crystallinity of the annealed NPs.   Second, the attempt is made to utilize the high absorbance and localized heat generation of the metal-insulator-metal (MIM) absorber in Si thermo-optic switches for achieving all-optical switching/routing with a small switching power and a fast transient response. For this purpose, a numerical study of a Mach-Zehnder interferometer integrated with MIM nanostrips is performed. Experimentally, a Si disk resonator and a ring-resonator-based add-drop filter, both integrated with MIM film absorbers, are fabricated and characterized. They show that good thermal conductance between the absorber and the Si light-guiding region is vital for a better switching performance.   Theoretical and experimental methodologies presented in the thesis show the physics principle and functionality of the photothermal effect in Au nanostructures, as well as its application in improving the morphology and crystallinity of Au NPs and miniaturized all-optical Si photonic switching devices. / <p>QC 20140331</p>

Plasmonic

Photothermal Effect

Silicon Photonics

Gold Nanoparticles