Thin Film Solar Cells Using ZnO Nanowires, Organic Semiconductors and Quantum Dots

VanSant, Kaitlyn

01 May 2007

A thin film organic/ inorganic hybrid solar cell was fabricated by incorporating ZnO nanowires, n- and p-type organic semiconductors and inorganic quantum dots. The basic cell design involved the electrodeposition of ZnO nanowires grown on a substrate coated with a transparent conductive oxide. The ZnO nanowires were coated with a thin layer of an organic n-type material, followed by a deposition of inorganic quantum dots. A p-type polymer layer was subsequently deposited and the sample was then contacted with gold to form a quantum dot layer sandwiched between a p-n junction of organic conductive materials. Various materials and processing methods were adjusted, using I-V characteristics, photovoltage and/ or photocurrent measurements to determine the performance of the cell. Each constituent material in the basic device design was evaluated in terms of its contribution to the sample characteristics. A variety of deposition techniques were investigated to obtain homogeneous layers. Different annealing procedures were explored with the intent of balancing the time and temperatures required for electrical activation with material constraints such as tendency towards oxidation and low melting points. The effect of time on the sample characteristics was also observed. The evaluation primarily includes data for samples that led to design modifications aimed at improving both electrical properties and quantum efficiencies. This research led to the development of a hybrid solar cell sensitized by the addition of quantum dots. The organic semiconductors were used to form a p-n junction, and the p-type polymer also served as an active absorber layer. The quantum dots were used as the inorganic absorber fayer, and the results show that the range of optical absorption in the cell can be modified by adjusting particle size. In addition, the ZnO nanowires appear to improve charge transfer, when used with materials that have favorable band offsets.

Nanowires

Solar cells

Organic semiconductors

Quantum dots

Physics

Aspects of Photovoltaic Systems: Study and Simulation of Silicon Phthalocyanine Bulk Heterojunction Solar Cells and Monochromatic Photonic Power Converters

Kaller, Kayden

03 September 2021

This thesis discusses two different photovoltaic systems, organic solar cells, and photonic power converters. The open-source software package Solcore was used to simulate and analyze optoelectronic properties of both systems. It is widely accepted that the transition from a fossil-fuel driven economy is necessary in the coming future. Organic solar cells are an alternative energy generation method with potential for fast energetic and economic payback periods. Bulk heterojunction organic solar cells are a common design, as they have particularly low manufacturing costs due to a simple device architecture. In this work, two bulk heterojunction blends are experimentally assessed using the acceptor molecule silicon phthalocyanine (bis(tri-n-butyl silyl oxide) silicon phthalocyanine ((3BS)2-SiPc) as a potential low-cost non-fullerene alternative to the typical acceptor [6,6]-phenyl-C61-butyric acid methyl ester (PC₆₁BM). These acceptors are compared within blends with the typical donor compound poly(3-hexylthiophene) (P3HT), and also poly[(2,6-(4,8-bis(5-(2-ethylhexyl)thiophen-2-yl)-benzo [1,2-b:4,5-b’]dithiophene))-alt-(5,5-(1′,3′-di-2- thienyl-5′,7′-bis(2-ethylhexyl)benzo[1′,2′-c:4′,5′-c’]dithiophene-4,8-dione)] (PBDB-T). Device performance was assessed under standard conditions, increased angles of incidence, and reduced light intensities. Devices with the P3HT:(3BS)2-SiPc blend achieved a power conversion efficiency (PCE) of 3.6%, which outperformed P3HT:PC₆₁BM devices with a PCE of 3.0% due to a higher open-circuit voltage (VOC) of 0.76 V as opposed to 0.53 V. The PBDB-T:(3BS)2-SiPc achieved a high VOC of 1.09 V, but had a lower PCE of 3.4% in relation to the PBDB-T:PC₆₁BM device with a PCE of 6.4% and a VOC of 0.78 V. Photonic power converters are devices in optical networks that allow for optical power transmission rather than the conventional method of electrical power transmission. This provides benefits such as electrical isolation and resistance to electromagnetic interference, along with the ability to propagate along the same cable as data. These power converters are used to convert optical power to electrical power, and operate similarly to a solar cell with a narrow bandwidth. Multijunction designs are often used for increased operating voltage and efficiency. In such designs employing a vertical architecture, the bottom-most junction has the largest thickness along with the lowest efficiency due to increased recombination losses. To improve this lower efficiency, light trapping techniques can be employed to decrease the junction thickness while retaining the optical thickness. In this work, a current-matched 5- junction GaAs photonic power converter was simulated with both metallic and distributed Bragg reflectors at the rear of the device. These reflectors allowed for the thinning of the bottommost junction, which resulted in an increase in efficiency and overall power output of the power converter.

Organic Solar Cells

Phthalocyanine

Bulk Heterojunction

Photonic Power Converters

The Systematic Approach to Microplotter Printing of Perovskite Precursors

Holeman, Tara

January 2018

No description available.

Electrical Engineering

Perovskite Solar Cells

Microplotter

Combinatorial Method

Thermal Analysis and Design of the Photovoltaic Investigation on Lunar Surface (PILS) Payload

Thaikattil, Greeta Jose

January 2020

No description available.

Mechanical Engineering

thermal analysis

Thermal Desktop

lunar surface

solar cells

Exciton Transfer in Organic Photovoltaic Cells: A Theoretical Study. / 有機太陽電池における励起子移動の理論的研究

CAINELLI, MAURO

23 March 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24433号 / 理博第4932号 / 新制||理||1705(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 谷村 吉隆, 教授 林 重彦, 教授 鈴木 俊法 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

Solar Cells

Exciton Transfer

HEOM

TGF

Coherence Length

400

Design framework to improve the photo and thermal stability of organic solar cells

Paleti, Sri Harish Kumar

21 June 2022

The state-of-the-art organic solar cells (OSC) use bulk heterojunction (BHJ) blend architecture in the photo-active layer. The BHJ is formed by finely mixing polymer donor and small molecule acceptor, which was predominantly fullerene derivatives until the last five years. However, the emergence of non-fullerene acceptor (NFA) materials has been the viable alternative to overcome high synthetic costs, limited optical absorption, and poor bandgap tunability of fullerene-based acceptors. These unique properties of NFA has resulted in a rapid improvement of OSC efficiency and opened doors for wide variety of applications including building integrated photovoltaics, green houses and agrivoltaics. Despite these advantages, the shorter device lifetime under light and heat is a major concern for their commercialization. This dissertation is focused on improving poor photo- and thermal stability of high efficiency OSC based on the widely used NFA, ITIC and Y-series derivatives. The light-induced changes in the acceptor molecular structure and the active layer nanostructure results in the photo-induced traps in photo-aged devices. The selective addition of third component to the active layer impedes the changes in the active layer nanostructure and suppress trap formation. Under constant thermal stress, the growth of acceptor crystals results increases the trap-assisted recombination in thermally aged devices. Similar to photo-stability the selective addition of third or more component/s arrests the crystal growth by minimizing the Gibbs free energy. The results suggest that the fabricated hexanary and ternary OSC display a superior thermal stability than the respective binary devices. In addition, the hexanary devices displayed thickness independent thermal stability, which is essential for the active layer thermal stability printed via high throughput techniques.

Non fullerene acceptors

Organic Solar Cells

Photo stability

Thermal stability

Computational Prediction Of Efficiency Parameters In Organic Solar Cells : From Polymer Donors And Non Fullerene Acceptors / Beräkningsförutsägelse av effektivitets parametrar i organiska solceller : Från polymeriska donatorer och icke fullerenska acceptorer

Karlsson, Martin

January 2022

The field of organic solar cells is getting more and more attention as the need forrenewable energy sources rises. When developing new materials for organic solar cellssynthesizing the new materials, is a time consuming and costly process. Therefore acomputational model for predicting how effective a new material, is without the needfor synthesizing. In this thesis an attempt to create a model for predicting open circuitvoltage in organic solar cells. Descriptors was calculated using B3LYP/6-31G hybridfunctionals. By creating a data set of donor and acceptor molecules with known andunknown open circuit voltage, and empirically trying to find a correlation between thedata sets that can be extrapolated and modeled. The results of this thesis did notmeet the goal of creating a model for predicting the open circuit voltage. Where nosignificant correlation was found, due a to small sample size.

Organic solar cells

computational chemistry

DFT.

Materials Chemistry

Materialkemi

Metal Blacks As Scattering Centers To Increase The Efficiency Of Thin Film Solar Cells

Panjwani, Deep R

01 January 2011

Metal nano particles are investigated as scattering centers on front surface of thin-film solar cells to improve efficiency. The principle is that scattering, which is enhanced near the plasmon resonance frequency of the particle and depends on particle size, increases the effective optical path length of incident light, leading to more light absorption in active layer of thin film solar cell. The particular types of particles investigated here are known as "metal-black", well known as an IR absorber for bolometric infrared detectors. Gold-black was deposited on commercial thin-film solar cells using a thermal evaporator in a nitrogen ambient at pressures of ~1 Torr. We suggest that the broad range of length scales for gold black particles, as quantified by scanning electron microscopy, gives rise to efficient scattering over a broad range of wavelengths across the solar spectrum. The solar cell efficiency was determined both as a function of wavelength and for a solar spectrum produced by a Xe lamp and appropriate filters. Up to 20% increase in short-circuit photocurrent, and a 7% increase in efficiency at the maximum power point, were observed.

Nanoparticles

Plasmons (Physics)

Scattering (Physics)

Solar cells

Thin films

Physics

Ink Formulation, Green Processing, And Integration Strategies For Printable Organic Photovoltaics

Corzo Diaz, Daniel Alejandro

06 1900

As the Internet-of-everything continues diversifying, wireless nods sensors, wearables, and smart-objects will require mature technologies to harvest energy from the environment in which they are installed. Out of the many energy forms, solar and artificial light are constantly present and the utilization solar technologies including organic photovoltaics can provide advantages including flexibility, semitransparency, and lightweight. Additionally, the incredibly low environmental footprint and reduced manufacturing costs associated with solution processing can provide an edge for entry into the industrial and consumer markets. While the utilization of conjugated polymers and nonfullerenes elevated the efficiencies of organic photovoltaic for commercialization, increasing the technological readiness level requires the development of protocols to translate lab performance of state-the-art-materials to scalable manufacturing techniques that can be adapted for roll-to-roll processing. This dissertation demonstrates the full fabrication of high-performance OPV devices through techniques such as inkjet printing and slot-die coating. The development of ink formulation frameworks based on solvent engineering, rheological and interface properties, and solubility parameters sets the base for standardized high-yield processes with reduced environmental footprint in line with circular carbon initiatives. Moreover, the utilization of engineering strategies involving intrinsic properties of materials, device architectures, and integration enables the development of complex energy harvesting and sensing devices for potential utilization in agrivoltaics and biosensing.

Photovoltaics

Solar Cells

Printed Electronics

Ink Formulation

Energy Harvesting

Solar Cell Production Facility

Kukulka, Jerry

January 1979

<p> A technology to produce low cost solar cells was transferred to a microelectronics institution. Appropriate processing equipment was obtained and modifications to the procedure were performed which would permit the manufacture of 100-200, 3 inch diameter silicon solar cells per day. </p> / Thesis / Master of Engineering (ME)

solar

cell

silicon solar cells

microelectronics

solar cell production