Field-directed nanowire chaining enabling transparent electrodes

Xu, Manyan

08 January 2019

Transparent electrodes (TEs) require materials that have both transparency and electrical conductivity, a combination not usually found in nature. They are in increasing demand for use in solar cells, touch screens, displays, transparent heating films and several other devices. Most TEs used today are made of indium tin oxide (ITO). However, it has several disadvantages, such as high fabrication cost, rigidity and brittleness. Many ITO alternatives are being pursued, among which metallic nanowire (NW) networks on transparent substrates such as glass or polymer, have received much attention. This thesis demonstrates ordered silver NW networks on polyimide, fabricated by the field-directed chaining technique. We achieved a sheet resistance of 27 Ω/sq and 95.4% transparency at 550nm, with a Figure of Merit (FOM) 0.023Ω-1, which is higher than the FOM of commercial ITO, 0.005Ω-1. We have demonstrated that ordered NW networks, directed by alternative current (AC) electric fields, are easy to fabricate over a large area and at low cost, on rigid and flexible substrates. The AC electric field changes with different experiment setup. In this work, the effect of polymer thickness, electric field frequency, and gap size between electrodes are explored by COMSOL simulation and validated experimentally. By choosing the appropriate frequency and gap size, ordered NW networks are successfully created on a 23μm polyethylene terephthalate (PET) sheet. Fluid motion is one of the disruptors during NW chaining. We demonstrate control of this disruptor by the use of sandwiched channels for the NW suspension. Post-fabrication treatments are important and necessary for improving the connectivity and conductivity of Ag NW networks. In this work, we explore Joule heating and show its potential to improve the conductivity over other post-treatment approaches. However, Joule heating can also cause failures of NW networks. Ordered NW networks present better optical-electrical properties than random NW networks. Post-fabrication treatment can improve the properties, but there is a limit. In this work, a mathematical model is built for optical-electrical properties of perfectly ordered NW networks, which sets the upper bound of performance for transparent electrodes made of NW networks. A linear relationship is found between the transmittance and inverse sheet resistance. The model is then modified with factors to account for departure from the ideal. / Graduate / 2019-12-12

Transparent electrodes

Field-directed

Flexible substrates

Sandwiched channels

Nanowire chaining

Ordered nanowire networks

Joule heating

Localized Heating in Membrane Distillation for Performance Enhancement

Mustakeem, Mustakeem

12 1900

Membrane distillation (MD) is an emerging technology capable of treating high-saline feeds and operating with low-grade heat energy. However, commercial implementation of MD is limited by so-called temperature polarization, which is the deviation in the temperature at the feed-membrane interface with respect to the bulk fluid. This work presents solutions to alleviate temperature polarization in MD by employing a localized heating concept to deliver heat at the vicinity of the feed-membrane interface. This can be realized in multiple ways, including Joule heating, photothermal heating, electromagnetic induction heating, and nanofluid heating. In the first experiment, a Joule heating concept was implemented and tested, and the results showed a 45% increase in permeate flux and a 57% decrease in specific energy consumption. This concept was further improved by implementing a new dead-end MD configuration, which led to a 132% increase in the gained output ratio. In addition, the accumulation of foulants on the membrane surface could be successfully controlled by intermittent flushing of feedwater. Three-dimensional CFD calculations of conjugate heat transfer revealed a more uniform heat transfer and temperature gradient across the membrane due to the increased feedwater temperature over a larger membrane area. In another approach, a photothermal MD concept was used to heat the feed water locally. A 2-D photothermal material, MXene, recently known for its photothermal property, was used to coat commercial MD membranes. The coated membranes were evaluated under one-sun illumination to yield a permeate flux of 0.77 kg.m$^{−2}$h$^{−1}$ with a photothermal efficiency of 65.3% for a feed concentration of 0.36 g.L$^{−1}$. The system can produce around 6 liters of water per day per square meter of membrane. An energy analysis was also performed to compare the efficiency of various energy sources. Considering the sun as a primary energy source, the performance of different heating modes was compared in terms of performance and scale-up opportunities. Overall this work demonstrates that the application of localized heating will enable the scale-up and the use of renewable energy sources to make the MD process more efficient and sustainable. / The illustrative figure was produced by Ana Bigio, scientific illustrator, KAUST.

Membrane Distillation

Localized Heating Dead-end

Photothermal membrane distillation

Joule heating membrane distillation

Interactive, Effective & Professional Comsol Applications : Based on COMSOL Modules Joule Heating & Corona Discharge

Sigstam, Axel, Olofsson, Linus

January 2023

This thesis will cover how two applications were developed using the commercial software COMSOL Multiphysics. The first application, the Joule heating application, simulates joule heating while taking the skin effect into consideration. The second application, the Corona Discharge application, is used to simulate corona discharges. It also estimates the initiation of charge propagation using the integration of the Townsend mechanism. The goal of this thesis is to verify that the COMSOL Application Builder can be used to create easy-to-use applications. With a high degree of accuracy and efficiency, it aims to aid Hitachi’s work with the design and effectiveness of bushings. These applications were developed to have similar graphical interfaces, making it easier for users to understand their functionality. Although a striking similarity in the graphical interfaces, the two applications have vastly different computational formulas, and physical properties, and are not based on the same COMSOL modules. The applications resulted in improving Hitachi’s workflow by significantly increasing efficiency and accuracy. The applications also contain a high degree of guidance to help the user optimize their results. However, as with all code-based projects, there is room for improvement. In the case of the Corona Discharge Application, one upgrade could be to allow the application to automatically find and calculate points with the highest potential. In conclusion, this thesis found that it is possible to create applications based onCOMSOL models, with a high degree of accuracy and efficiency, while still making them easy to use, interactive, and retaining all their physical properties.

COMSOL

Hitachi

applications

skin effect

joule heating

corona discharge

townsend

Engineering and Technology

Teknik och teknologier

Study on Forming and Resistive Switching Phenomena in Tantalum Oxide for Analog Memory Devices / アナログメモリ素子応用に向けたタンタル酸化物におけるフォーミングおよび抵抗変化現象に関する研究

Miyatani, Toshiki

23 March 2023

付記する学位プログラム名: 京都大学卓越大学院プログラム「先端光・電子デバイス創成学」 / 京都大学 / 新制・課程博士 / 博士(工学) / 甲第24622号 / 工博第5128号 / 新制||工||1980(附属図書館) / 京都大学大学院工学研究科電子工学専攻 / (主査)教授 木本 恒暢, 教授 白石 誠司, 准教授 小林 圭 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

resistive switching

analog memory devices

tantalum oxide

conductive filament

oxygen vacancy

Joule heating

500

Significance of the Alfvén waves in the thermospheric dynamics in the cusp region / カスプ域の熱圏ダイナミクスにおけるアルフベン波の重要性

Oigawa, Tomokazu

23 March 2022

京都大学 / 新制・課程博士 / 博士(理学) / 甲第23709号 / 理博第4799号 / 新制||理||1687(附属図書館) / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)教授 田口 聡, 教授 松岡 彩子, 教授 榎本 剛 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

mass density enhancement

cusp

Joule heating

Alfvén wave

neutral-ion drag

400

Transient Joule heating in nano-scale embedded on-chip interconnects

Barabadi, Banafsheh

22 May 2014

Major challenges in maintaining quality and reliability in today’s microelectronics devices come from the ever increasing level of integration in the device fabrication, as well as the high level of current densities that are carried through the microchip during operation. In order to have a framework for design and reliability assessment, it is imperative to develop a predictive capability for the thermal response of micro-electronic components. A computationally efficient and accurate multi-scale transient thermal methodology was developed using a combination of two different approaches: “Progressive Zoom-in” method and “Proper Orthogonal Decomposition (POD)” technique. The proposed technique has the capability of handling several decades of length scale from tens of millimeter at “package” level to several nanometers at “interconnects” level at a considerably lower computational cost, while maintaining satisfactory accuracy. This ability also applies for time scales from seconds to microseconds corresponding to various transient thermal events. The proposed method also provides the ability to rapidly predict thermal responses under different power input patterns, based on only a few representative detailed simulations, without compromising the desired spatial and temporal resolutions. It is demonstrated that utilizing the proposed model, the computational time is reduced by at least two orders of magnitude at every step of modeling. Additionally, a novel experimental platform was developed to evaluate rapid transient Joule heating in embedded nanoscale metallic films representing buried on-chip interconnects that are not directly accessible. Utilizing the state-of-the-art sub-micron embedded resistance thermometry the effect of rapid transient power input profiles with different amplitudes and frequencies were studied. It is also demonstrated that a spatial resolution of 6 µm and thermal time constant of below 1 µs can be achieved using this technique. Ultimately, the size effects on the thermal and material properties of embedded metallic films were studied. A state-of-the-art technique to extract thermal conductivity of embedded nanoscale interconnects was developed. The proposed structure is the first device that has enabled the conductivity measurement of embedded metallic films on a substrate. It accounts for the effect of the substrate and interface without compromising the sensitivity of the device to the thermal conductivity of the metallic film. Another advantage of the proposed technique is that it can be integrated within the structure and be used for measurements of embedded or buried structures such as nanoscale on chip interconnects, without requiring extensive micro-fabrication. The dependence of the thermal conductivity on temperature was also investigated. The experimentally measured values for thermal conductivity and its dependence on temperature agree well with previous studies on free-standing nanoscale metallic bridges.

Joule heating

Interconnects

Nano-scale heat transfer

Multi-scale thermal modeling

Nanoelectromechanical systems

Heat Transmission

Development and Application of Theta Tips as a Novel nESI-MS Ion Source and Protein Identification Using Limited Trypsin Digestion and Mass Spectrometry

Feifei Zhao (6449489)

15 May 2019

<div><div><div><div>Mass spectrometry is a widely used tool for efficient chemical characterization and identification. The development of electrospray ionization as a soft ionization method enables mass spectrometry for large biomolecule investigation. Protein as one of the most important classes of biomolecules, its structural changes including folding, unfolding, aggregation, degradation and post-translational modification all influence protein bioactivity. Protein characterization and identification are important for protein behavior mechanism understanding, which may further contribute to disease treatment development. Protein conformation changes are normally very fast, and the initial stages, which significantly influence the conformation changing pathway, normally occur in milliseconds or shorter time scale. Such a fast structural change is hard to be monitored using traditional bulk solution manipulations, and fast sample preparation methods are required. </div><div><br></div><div>In this thesis project, theta tips are applied as a microreactor and nESI-MS emitter to perform fast protein manipulation immediately before MS analysis. Theta tips can be operated in two modes. The first mode is for submillisecond time scale reactions. Proteins and reagents are loaded into different channels and directly sprayed out simultaneously. Proteins and reagents mix and react in the Taylor cone and subsequent droplets for submillisecond time scale. Through this method, pH induced protein folding is investigated and protein folding intermediates were captured. The second mode is for milliseconds or longer reactions. Differential voltages can be applied to each channel before ionization and spray. The electric field between the two channels induces in-tip electroosmosis, which lead to an in-tip mixing and reaction. In this mode, the reaction time is not limited by the droplet lifetime as in the first mode, but is controlled by electroosmosis time. By changing the electroosmosis square wave frequency and cycles, the mixing time can be elongated to milliseconds or longer, which is suitable for slower reaction study. </div><div>Joule heating is discovered during theta tip electroosmosis when samples are dissolved in buffer. The Joule heating effect is high enough to heat up the aqueous solution to at least 75 oC based on Raman thermometry measurement, while the actual peak temperature could be higher. The Joule heating effect in theta tip electroosmosis can be easily controlled by electroosmosis voltage, time, buffer concentration etc.. Proteins are thermally denatured by the Joule heating effect, and the denaturation extent correlates with Joule heating parameters. </div><div>With this results in hand, we are developing a protein melting temperature measurement method using theta tip Joule heating effect and mass spectrometry. This new melting temperature measurement method measures changes in protein mass and charge state distributions. Therefore, it could sensitively detect ligand loss and protein tertiary structural changes, which is an important compensation to current protein melting temperature measurement techniques like CD or DSC. Since the heating time is short and protein concentration for MS is low, protein aggregation and thermal fragmentation are highly avoided so a complete protein thermal unfolding process is monitored. Theta tip electroosmosis combining MS characterized protein thermal denaturation behavior from a new aspect.</div><div><br></div><div>Besides single protein folding and unfolding, protein identification and post-translational modification are important for proteomics study. The traditional bottom-up, top-down and middle-down methods are not able to both preserve intact protein mass and efficiently generate enough fragment peaks easily without performing gas phase dissociation. In this thesis, we also developed a new way to identify proteins combining limited trypsin digestion and mass spectrometry. Intact protein mass was preserved for protein size and PTM identification. Enough tryptic peptides were also generated for protein identification through database search.</div></div></div></div><div><br></div>

mass spectrometry

theta tip

protein

folding

intermediate

Joule heating

nano-electrospray ionization

fast analysis

Joule heating as a smart approach in enhancing early strength development of mineral-impregnated carbon-fibre composites (MCF) made with geopolymer

Junger, Dominik, Liebscher, Marco, Zhao, Jitong, Mechtcherine, Viktor

04 March 2023

The article at hand presents a novel approach to accelerating the early strength development of mineralimpregnated carbon-fibre composites (MCF) by electrical Joule heating. MCF were produced with a metakaolin-based geopolymer suspension and subsequently cured using Ohmic heating under systemically varied voltages and durations. The MCF produced were characterised in respect of their mechanical and morphological properties. Threepoint-bending and uniaxial tension tests yielded significant enhancement of MCF mechanical properties due to curing within only a few hours. Thermogravimetric analysis (TGA), mercury intrusion porosimetry (MIP), environmental scanning electron microscope (ESEM) as well as micro-computed tomography (μCT) confirmed advanced geopolymerisation by the electrical heating process and a strong sensitivity to parameter selection. After only two hours of resistance heating MCF could demonstrate tensile strength of up to 2800 MPa, showing the great potential for applying the Joule effect as a possibility to enhance the strength development of geopolymer-based MCF. Moreover, the applied method offers a huge potential to manufacture automated fast out-of-oven cured MCF with a variety of shapes and dimensions.

info:eu-repo/classification/ddc/660

ddc:660

Novel considerations for lightning strike damage mitigation of Carbon Fiber Reinforced Polymer Matrix (CFRP) composite laminates

Yousefpour, Kamran

06 August 2021

Lightning current with high amplitude disseminates through the body of aircraft and causes physical damages including the delamination and puncture of materials. Also , such high-amplitude and high-frequency current could interfere with electronic devices through electromagnetic coupling with the conductive interfaces of an airplane. Hence, robust protection against lighting strike is essential in the aerospace industry. Carbon Fiber Reinforced Polymer (CFRP) Matrix Composites have become significant alternatives to conventional metal-base materials. Despite the superior physical and structural properties of CFRP composites, these materials are vulnerable to lightning strikes due to the low electrical conductivity compared to the metal counterpart. Many researchers have been working on the lightning strike damage mitigation of CFRP composites by increasing the electrical conductivity of materials. Conventional methods are adding conductive layers such as metal foil and copper mesh to the composite structures. These layers are added to the composite structure during the manufacturing process and are placed at the top layer for the effective bypassing of lightning current to the ground. While adding the conductive layers reduces the lightning strike damage significantly, the industry is more interested in using conductive nanofillers to prevent the corrosion of metal layers in contact with carbon fibers and to avoid the higher weight of conductive layers than nanofillers. The lightning damage mitigation methods are studied by applying lightning strike current to the CFRP composites using an impulse current generator. Conventional lightning strike damage tolerance of CFRP composites are prone to misinterpretation. The risk of misinterpretation originates from the lack of standards clearly defining testbed design requirements including electrode size and ground electrode edge configuration. In this dissertation, the effects of testbed configuration including discharge and ground electrode on lightning strike damage evaluation studies are demonstrated. Finite element analysis is applied to perform the simulations through the COMSOL Multiphysics to validate the experimental test results. Furthermore, after improving the testbed design, carbon black was added to the CFRP composites as a cost-effective additive for lightning strike damage mitigation performance. Correlations between lightning strike damage intensity and the added carbon black fillers as well as with other additive nanofillers are reported.

Lightning

Aircraft

Impulse Current Generator

Carbon nanofiller

Ground Electrode

Discharge Electrode

COMSOL Multiphysics

Plasma

Anode

Cathode

Joule Heating

Multi-functional PAN based composite fibers

Chien, An-Ting

07 January 2016

Various nano-fillers can introduce specific functions into polymer and expand their application areas. Myriad properties, such as mechanical, electrical, thermal, or magnetic properties can be combined with original polymer characteristics, including flexible, light weight, and ease of use. These composites can be used to produce multi-functional fibers as the next generation textile or fabrics. In this research, Polyacrylonitrile (PAN) is adopted as the main polymer with different nano-fillers, such as carbon nanotube (CNT), iron oxide nanoparticle, and graphene oxide nanoribbon (GONR). Using gel-spinning technology, PAN-based composite fibers are fabricated in single- or bi-component fibers. Fibers are also characterized for their structure, morphology, mechanical properties, as well as for their electrical, thermal, or magnetic properties. For example, bi-component fibers with polymer sheath and polymer-CNT core as well as polymer-CNT sheath and polymer core are processed. With electrical and thermal conductivity introduced by CNT, such bi-components fibers can be applied for wearable electronics or for thermal management. Joule-heating effect owing to applied electrical current on single component PAN/CNT fibers is also investigated. With controllable electrical conductivity and fiber temperature, this active functional fiber can be applied for temperature regulation fibers or new carbon fiber manufacturing process. Another example is magnetic fiber with superparamagnetic iron oxide nano-particles. These novel magnetic fibers with high strength can be used for actuator, inductors, EMI shielding, or microwave absorption. GONR is also discussed and used to reinforce PAN-based fibers. Several theoretical models are considered to analyze the observed results.

Composites

Polyacrylonitrile

Gel spinning

Bi-component fibers

Carbon nanotube

Graphene

Iron oxide nanoparticle

functional materials

Wearable electronics

Joule heating

Superparamagnetism

Carbon fibers