Growth and Characterization of Multisegment Chalcogenide Alloy Nanostructures for Photonic Applications in a Wide Spectral Range

January 2015

abstract: In this dissertation, I described my research on the growth and characterization of various nanostructures, such as nanowires, nanobelts and nanosheets, of different semiconductors in a Chemical Vapor Deposition (CVD) system. In the first part of my research, I selected chalcogenides (such as CdS and CdSe) for a comprehensive study in growing two-segment axial nanowires and radial nanobelts/sheets using the ternary CdSxSe1-x alloys. I demonstrated simultaneous red (from CdSe-rich) and green (from CdS-rich) light emission from a single monolithic heterostructure with a maximum wavelength separation of 160 nm. I also demonstrated the first simultaneous two-color lasing from a single nanosheet heterostructure with a wavelength separation of 91 nm under sufficiently strong pumping power. In the second part, I considered several combinations of source materials with different growth methods in order to extend the spectral coverage of previously demonstrated structures towards shorter wavelengths to achieve full-color emissions. I achieved this with the growth of multisegment heterostructure nanosheets (MSHNs), using ZnS and CdSe chalcogenides, via our novel growth method. By utilizing this method, I demonstrated the first growth of ZnCdSSe MSHNs with an overall lattice mismatch of 6.6%, emitting red, green and blue light simultaneously, in a single furnace run using a simple CVD system. The key to this growth method is the dual ion exchange process which converts nanosheets rich in CdSe to nanosheets rich in ZnS, demonstrated for the first time in this work. Tri-chromatic white light emission with different correlated color temperature values was achieved under different growth conditions. We demonstrated multicolor (191 nm total wavelength separation) laser from a single monolithic semiconductor nanostructure for the first time. Due to the difficulties associated with growing semiconductor materials of differing composition on a given substrate using traditional planar epitaxial technology, our nanostructures and growth method are very promising for various device applications, including but not limited to: illumination, multicolor displays, photodetectors, spectrometers and monolithic multicolor lasers. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2015

Electrical engineering

Materials Science

Physics

Dual Ion Exchange

Lasers

LEDs

Monolithic White Laser

Nano Materials

ZnCdSSe Quaternary Alloy Nanosheets

Sustainable New Energy Materials: Design and Discovery of Novel Materials and Architectures for Lithium Ion Batteries and Solar Energy Conversion

January 2016

abstract: There is a fundamental attractiveness about harnessing renewable energy in an age when sustainability is an ethical norm. Lithium ion batteries and hydrogen fuels are considered the most promising energy source instead of fossil fuels. This work describes the investigation of new cathode materials and devices architectures for lithium ion batteries, and photocatalysts for their usage in water splitting and waste water treatment. LiCoO2 and LiNi1/3Mn1/3Co1/3O2 were exfoliated into nanosheets using electrochemical oxidation followed by intercalation of tetraethylammonium cations. The nanosheets were purified using dialysis and electrophoresis. The nanosheets were successfully restacked into functional cathode materials with microwave hydrothermal assistance, indicating that new cathodes can be obtained by reassembling nanosheets. This method can pave the way for the synthesis of materials with novel structures and electrochemical properties, as well as facilitate the fabrication of hybrid and composite structures from different nanosheets as building blocks. Paper folding techniques are used in order to compact a Li-ion battery and increase its energy per footprint area. Full cells were prepared using Li4Ti5O12 and LiCoO2 powders deposited onto current collectors consisting of paper coated with carbon nanotubes. Folded cells showed higher areal capacities compared to the planar versions. Origami lithium-ion battery made in this method that can be deformed at an unprecedented high level, including folding, bending and twisting. Spray pyrolysis was used to prepare films of AgInS2 with and without Sn as an extrinsic dopant. The photoelectrochemical performance of these films was evaluated after annealing under a N2 or S atmosphere with different amounts of the Sn dopant. Density Function Theory (DFT) was used to calculate the band structure of AgInS2 and understand the role of Sn doping in the observed properties. Cr(VI) removal was investigated using multiple oxide photocatalyst and additives. The efficiency for Cr(VI) removal using these photocatalysts was investigated in synthetic neutral and alkaline water, as well as in cooling tower blowdown water. While sulfite alone can chemically reduce Cr(VI), sulfite in combination with a photocatalyst resulted in faster and complete removal of Cr(VI) in 10 min using a SO32−/Cr(VI) ratio >35 in pH ∼ 8 solutions. / Dissertation/Thesis / Doctoral Dissertation Materials Science and Engineering 2016

Energy

Chemistry

Materials Science

Cathode materials

Cr(V) reduction

Foldable lithium ion batteries

nanosheets

photocatalysts

photoelectricalchemical cells

Soft-Template Construction of 3D Macroporous Polypyrrole Scaffolds

Liu, Shaohua, Wang, Faxing, Dong, Renhao, Zhang, Tao, Zhang, Jian, Zheng, Zhikun, Mai, Yiyong, Feng, Xinliang

07 May 2018

No description available.

dreidimensional (3D)

makroporös

selbstorganisierend

leitfähige Polymere

Nanoblätter

three-dimensional (3D)

macroporous

self-assembly

conducting polymer

nanosheets

ddc:541

rvk:VA 1120

Synthesis and Characterization of 1D & 2D Nanostructures : Performance Study for Nanogenerators and Sensors

Gaddam, Venkateswarlu

January 2015

Recently, efforts have been made for self-powering the batteries and portable electronic devices by piezoelectric nanogenerators. The piezoelectric nanogenerators can work as a power source for nano-systems and also as an active sensor. The piezoelectric nanogenerator is a device that converts random mechanical energy into electrical energy by utilizing the semiconducting and piezoelectric properties. Also, the mechanical energy is always available in and around us for powering these nano devices. The aim of the present thesis work is to explore 1D and 2D ZnO nanostructures (nanorods and nanosheets) on metal alloy substrates for the development of piezoelectric nanogenerators in energy harvesting and sensors applications. Hydrothermal synthesis method was adopted for the growth of ZnO nanostructures. The nanogenerators were fabricated by using the optimized synthesis parameters and subsequently studied their performance for power generation and as an active speed sensor. These 1D and 2D nanostructures based nanogenerators have opened up a new window for the energy harvesting applications and sensors development. The thesis is divided into following six chapters. Chapter 1: This chapter gives a general introduction about energy harvesting devices such as nanogenerators, available energy sources, mechanical energy harvesting, ZnO material and the details on hydrothermal synthesis process. A brief literature survey on different applications of piezoelectric nanogenerators is also included. Chapter 2: A novel flexible metal alloy (Phynox) and its properties along with its applications are discussed in this chapter. Details on the synthesis of 1D ZnO nanorods on Phynox alloy substrate by hydrothermal method are presented. Further, the optimization of parameters such as growth temperature, seed layer annealing and substrate temperature effects on the synthesis of ZnO nanorods are discussed in detail. As-synthesized ZnO nanorods have been characterized using XRD, FE-SEM, TEM and XPS. Chapter 3: It reports on the fabrication of piezoelectric nanogenerator on Phynox alloy substrate as power generating device by harvesting the mechanical energy. Initially, the performance of the nanogenerator for power generation due to finger tip impacts was studied and subsequently its switching polarity test was also carried out. Output voltage measurements were carried out using the in-house developed experimental setup. Stability test was also carried out to see the robustness of the nanogenerator. Finally, the output voltage response of the nanogenerator was studied for its use as an active speed sensor. Chapter 4: Synthesis of Al doped 2D ZnO nanorsheets on Aluminum alloy (AA-6061) substrate by hydrothermal method is reported in this chapter. The optimized parameters such as growth temperature and growth time effects on the synthesis of ZnO nanosheets are discussed. As-synthesized ZnO nanosheets were characterized using XRD, FE-SEM, TEM and XPS. The Al doping in ZnO is confirmed by EDXS and XPS analysis. Chapter 5: Cost effective fabrication of Al doped 2D ZnO nanosheets based nanogenerator for direct current (DC) power generation is reported in this chapter. The performance of the nanogenerator for DC power generation due to finger tip impacts was studied and subsequently its switching polarity test was also carried out. Output voltage measurements were carried out using the in-house developed experimental setup. Stability test was also carried out to see the robustness of the nanogenerator. Finally, the DC output voltage response of the nanogenerator was studied for its use as an active speed sensor. Chapter 6: The first section summarizes the significant features of the work presented in this thesis. In the second section the scope for carrying out the further work is given.

1D & 2D Nanostructures

Zinc Oxide Nanostructures (ZNO)

Metal Alloy Substrates

Piezollectric Nanogenerators

ZnO Nanosheets

ZnO Nanorods

Instrumentation and Applied Physics

Exciton Physics of Colloidal Nanostructures and Metal Oxides

Tang, Yiteng

20 May 2021

No description available.

Optics

Nanoscience

Materials Science

lead salt

PbSe nanorods

PbS nanosheets

optical properties

carbon quantum dots

gallium oxide

Study on Novel Proton Conducting Behavior in Free-Standing Coordination Polymer Membranes / 自立型配位高分子膜における特異なプロトン伝導挙動に関する研究

Lu, Jiangfeng

25 September 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24873号 / 理博第4983号 / 新制||理||1711(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 北川 宏, 教授 有賀 哲也, 教授 堀毛 悟史 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

Coordination polymer

Proton conducting

Free-standing membrane

Two-dimensional nanosheets

Flexible devices

All-solid-state

Rectification

400

Zero-dimensional and two-dimensional colloidal nanomaterials and their photophysics

Jiang, Zhoufeng, Jiang

23 April 2018

No description available.

Chemistry

Nanoscience

Nanotechnology

Materials Science

Physics

semiconductor nanocrystals

nanosheets

emission

lead sulfide

absorption

cation exchange

carbon nanodots

Microwave-Assisted Topochemical Manipulation of Layered Oxide Perovskites: From Inorganic Layered Oxides to Inorganic-Organic Hybrid Perovskites and Functionalized Metal-Oxide Nanosheets

Akbarian-Tefaghi, Sara

19 May 2017

Developing new materials with desired properties is a vital component of emerging technologies. Functional hybrid compounds make an important class of advanced materials that let us synergistically utilize the key features of the organic and inorganic counterparts in a single composite, providing a very strong tool to develop new materials with ”engineered” properties. The research presented here, summarizes efforts in the development of facile and efficient methods for the fabrication of three- and two-dimensional inorganic-organic hybrids based on layered oxide perovskites. Microwave radiation was exploited to rapidly fabricate and modify new and known materials. Despite the extensive utilization of microwaves in organic syntheses as well as the fabrication of the inorganic solids, the work herein was among the first reported that used microwaves in topochemical modification of the layered oxide perovskites. Our group specifically was the first to perform rapid microwave-assisted reactions in all of the modification steps including proton exchange, grafting, intercalation, and exfoliation, which decreased the duration of multi-step modification procedures from weeks to only a few hours. Microwave-assisted grafting and intercalation reactions with n-alkyl alcohols and n-alkylamines, respectively, were successfully applied on double-layered Dion-Jacobson and Ruddlesden-Popper phases (HLaNb2O7, HPrNb2O7, and H2CaTa2O7), and with somewhat more limited reactivity, applied to triple-layered perovskites (HCa2Nb3O10 and H2La2Ti3O10). Performing neutron diffraction on n-propoxy-LaNb2O7, structure refinement of a layered hybrid oxide perovskite was then tried for the first time. Furthermore, two-dimensional hybrid oxides were efficiently prepared from HLnNb2O7 (Ln = La, Pr), HCa2Nb3O10, HCa2Nb2FeO9, and HLaCaNb2MnO10, employing facile microwave-assisted exfoliation and post-exfoliation surface-modification reactions for the first time. A variety of surface groups, saturated or unsaturated linear and cyclic organics, were successfully anchored onto these oxide nanosheets. Properties of various functionalized metal-oxide nanosheets, as well as the polymerization of some monomer-grafted nanosheets, were then investigated for the two-dimensional hybrid systems.

topochemical manipulation

layered oxide perovskites

microwave-assisted reactions

inorganic-organic hybrids

surface modification

functionalized metal-oxide nanosheets

Inorganic Chemistry

Materials Chemistry

Polymer Chemistry

Desenvolvimento de adesivos eletricamente condutivos na fixação de componentes eletrônicos em montagens de superfície (SMT)

Lunardi, Tiago di Giovani

21 March 2018

Submitted by JOSIANE SANTOS DE OLIVEIRA (josianeso) on 2018-04-19T17:05:39Z No. of bitstreams: 1 Tiago di Giovani Lunardi_.pdf: 6951536 bytes, checksum: 4d60fac658887a2701421d77cb011f8d (MD5) / Made available in DSpace on 2018-04-19T17:05:39Z (GMT). No. of bitstreams: 1 Tiago di Giovani Lunardi_.pdf: 6951536 bytes, checksum: 4d60fac658887a2701421d77cb011f8d (MD5) Previous issue date: 2018-03-21 / HT Micron / Por muitos anos a liga metálica mais utilizada como solda foi a liga Pb-Sn, material maleável e de baixa temperatura de fusão. Com a diretiva europeia 2002/95/CE (conhecida como diretiva RoHS), é homologada a suspensão do uso de substâncias nocivas como o chumbo. Ocorre a necessidade de substituir a liga de solda Pb-Sn por novos materiais e as mais utilizadas deste então são as ligas da família SAC (abreviação dos elementos que compõe a liga - Sn-Ag-Cu). Essa liga, funde em temperaturas superiores a 210ºC, o que pode vir a danificar os componentes eletrônicos, cada vez menores e com mais funções. Surge então a possibilidade da utilização de adesivos eletricamente condutivos. Estes são formulados, em sua maioria, utilizando-se partículas de prata e outros metais bons condutores como ouro e níquel, dispersas em uma matriz polimérica. Dessa forma, há economia de metais, frente à utilização de pastas de solda. Este trabalho propõe três formulações para adesivos eletricamente condutivos, obtidos a partir de uma resina epóxi com butadieno e com diferentes tipos de partículas condutivas: nanotubos de carbono e prata com diferentes morfologias. Todos os materiais foram caracterizados quanto as suas características físicas, morfológicas e elétricas através das técnicas de MEV, medição da resistência elétrica pelo método 4 pontas, choque térmico e envelhecimento. A resistência elétrica de cada material e a resistência de contato foram testadas e comparadas com adesivos comerciais e a referência solda metálica SAC305. Foi identificado que os adesivos demonstraram resiliência em relação ao contato com a PCI mesmo após sucessivos ciclos de envelhecimento em 85°C com 85% UR ou ensaios de choque térmico. A resistência elétrica medida no adesivo formulado a partir das nanofolhas de prata aproxima-se muito dos valores obtidos com a referência comercial, na ordem de 10-4 cm. Foi também o único material que apresentou variação de resistência elétrica inferior a 20% após o choque térmico, comprovando seu bom desempenho frente às demais formulações deste trabalho. / For many years the most commonly used metal alloy as solder was the Pb-Sn alloy, a malleable material with a low melting temperature. With the European Directive 2002/95/CE (as known as RoHS Directive), the suspension of the use of hazardous substances such as lead is approved. It is necessary to replace the Pb-Sn solder alloy with new materials and the most used of these are the alloys of the SAC family (metal alloy composed by Sn-Ag-Cu). This alloy melts at temperatures above 210°C, which can damage the electronic components, that are becoming smaller and with more functions. The possibility of using electrically conductive adhesives arises. These are mostly formulated using silver particles and other good conducting metals such as gold and nickel, dispersed in a polymer matrix. In this way, there is economy of metals, compared to the use of solder pastes. This work proposes three formulations for electrically conductive adhesives, obtained from an epoxy resin with butadiene with different types of conductive fillers: carbon nanotubes and silver with different morphologies. All the materials were characterized as their physical, morphological and electrical characteristics through MEV, electrical resistance measurement by the 4-point probes method, thermal shock and aging. Electrical resistance of each material and the contact resistance were tested and compared with commercial adhesives and the reference SAC305 alloy solder. It was identified that the adhesives demonstrated resilience in relation to the contact with the PCI even after successive aging cycles at 85°C with 85% RH or thermal shock tests. Electrical resistance measured on the adhesive formulated using silver nanosheets is very close to the values obtained with the commercial reference, in the order of 10-4 cm. It was also the only material that presented less than 20% variation of electrical contact resistance after thermal shock, proving its good performance against the other formulations of this work.

Adesivos eletricamente condutivos

ICA

Nanofolhas de prata

Partículas de prata

Nanotubos de carbono

Electrically conductive adhesives

ICA

Silver nanosheets

Silver particles

Carbon nanotubes

Deformation of hexagonal boron nitride

Alharbi, Abdulaziz

January 2018

Boron nitride (BN) materials have unique properties, which has led to interest in them in the last few years. The deformation of boron nitride materials including hexagonal boron nitride, boron nitride nanosheets (BNNSs) and boron nitride nanotubes have been studied by Raman spectroscopy. Both mechanical and liquid exfoliations were employed to obtain boron nitride nanostructures. Boron nitride glass composites were synthesised and prepared in thin films to be deformed by bending test in-situ Raman spectroscopy. Hexagonal boron nitride in the form of an individual flake and as flakes dispersed in glass matrices has been deformed and Raman measurement shows its response to strain. The shift rates were, -4.2 cm-1/%, -6.5 cm-1/% for exfoliated h-BN flake with thick and thin regions and -7.0 cm-1/%, -2.8 cm-1/% for the h-BN flakes in the h-BN/ glass (I) and glass (II) composites. Boron nitride nanosheets (BNNSs) shows a G band Raman peak at 1367.5 cm-1, and the deformation process of BNNSs/ glass composites gives a shift rate of -7.65 cm-1/% for G band. Boron nitride nanotubes (BNNTs) have a Raman peak with position at 1368 cm-1, and their deformation individually and in composites gives Raman band shift rates of -25.7 cm-1/% and -23.6 cm-1/%. Glass matrices shows compressive stresses on boron nitride fillers and this was found as an upshift in the frequencies of G band peak of boron nitride materials. Grüneisen parameters of boron nitride (BN) were used to calculate the residual strains in glass matrices of BNNSs nanocomposites as well as to estimate the band shift rates which found to be in agreement with the experimental shift rate of bulk BN and BNNTs.

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