Exploration of Sputtered Thin Films—E.g., in Sample Preparation and Material Characterization

Roychowdhury, Tuhin

10 October 2019

My dissertation focuses on (i) the development sputtered films for solid phase microextraction (SPME) and (ii) the comprehensive characterization of materials using a suite of analytical techniques. Chapter 1 reviews the basics of SPME. This chapter also contains (i) a discussion of various sputtering techniques, (ii) a discussion of two techniques I focused on most of my work: spectroscopic ellipsometry (SE) and X-ray photoelectron spectroscopy (XPS). Chapter 2 focuses the major part of my work, which is to prepare new solid phases/adsorbents for SPME via silicon sputtering followed by thermal deposition of a polymer, polydimethylsiloxane (PDMS). PDMS was deposited by a simple gas phase technique which has never before been applied to prepare SPME stationary phases. The coatings were characterized by time-of-flight mass spectrometry (ToF-SIMS), XPS, scanning electron microscopy (SEM), SE, and contact angle goniometry. The extraction efficiencies of ca. 1.8 µm sputtered, PDMS-coated fibers were compared to a commercial fiber (7 µm PDMS) for a series of polycyclic hydrocarbons (PAHs). Large carry-over and phase bleed peaks are observed in case of commercial PDMS-based SPME coatings, which decrease the lifetime and usefulness of these fibers. It is of great significance that our sputtered fibers exhibit very small or negligible carry-over peaks and phase bleed peaks under the same conditions. Chapter 3 focuses on the multi-instrument characterization of copper and tungsten films sputtered by direct current magnetron sputtering (DCMS) and high-power impulse magnetron sputtering (HiPIMS) using a modern sputter source. The resulting films were characterized by energy dispersive X-ray spectroscopy (EDX), XPS, SEM, atomic force microscopy (AFM), SE, and X-ray diffraction (XRD). By EDX and XPS, all the sputtered films only showed the expected metal peaks. By XPS, the surfaces sputtered by DCMS were richer in oxygen than those produced by HiPIMS. By AFM, both surfaces were quite smooth. By SEM, the HiPIMS films exhibited smaller grain sizes, which was further confirmed by XRD. The crystallite sizes estimated by XRD are as follows: 18.2 nm (W, HiPIMS), 27.3 nm (W, DCMS), 40.2 nm (Cu, HiPIMS), and 58.9 nm (Cu, DCMS). By SE, the HiPIMS surfaces showed higher refractive indices, which suggested that they were denser and less oxidized than the DCMS surfaces. Chapter 4 reports characterization of liquid PDMS via SE, which required some experimental adaptations. The transmission measurements were obtained via a dual cuvette approach that eliminated the effects of the cuvettes and their interfaces. Only the reflection measurements were modeled with a Sellmeier function which produced decent fits. Chapters 5 consists of contributions to Surface Science Spectra (SSS) of near-ambient XPS spectra of various unconventional materials including cheese, kidney stone, sesame seeds, clamshell, and calcite. This dissertation also contains appendices of tutorial articles I wrote on ellipsometry and vacuum equipment.

SPME

PDMS

carry-over

phase bleed

DCMS

HiPIMS

multi-instrument characterization

SE

XPS

NAP-XPS

Physical Sciences and Mathematics

Role of Substrate Stiffness on Migratory Properties and Epithelial to Mesenchymal Transition in Human Lung Cancer Cells

Subisak, Angel Dharshini

January 2012

No description available.

Biomedical Engineering

Cell migration

cell motility

substrate stiffness

PDMS

Epithelial to Mesenchymal Transition

metastasis

2D migration assay

TGF-¿¿

A549

Microfluidic Lab-on-a-Chip for Studies of Cell Migration under Spatial Confinement

Sala, Federico, Ficorella, Carlotta, Osellame, Roberto, A. Käs, Josef, Martínez Vázquez, Rebeca

06 December 2023

Understanding cell migration is a key step in unraveling many physiological phenomena and predicting several pathologies, such as cancer metastasis. In particular, confinement has been proven to be a key factor in the cellular migration strategy choice. As our insight in the field improves, new tools are needed in order to empower biologists’ analysis capabilities. In this framework, microfluidic devices have been used to engineer the mechanical and spatial stimuli and to investigate cellular migration response in a more controlled way. In this work, we will review the existing technologies employed in the realization of microfluidic cellular migration assays, namely the soft lithography of PDMS and hydrogels and femtosecond laser micromachining. We will give an overview of the state of the art of these devices, focusing on the different geometrical configurations that have been exploited to study specific aspects of cellular migration. Our scope is to highlight the advantages and possibilities given by each approach and to envisage the future developments in in vitro migration studies under spatial confinement in microfluidic device

info:eu-repo/classification/ddc/570

ddc:570

Microfluidic Chemical Signal Generation

Azizi, Farouk

23 October 2009

No description available.

Electrical Engineering

Microfluidic

Micromixer

PDMS

Aplysia

Chemical Neurostimulation

Digital to Analog Converter

C-DAC

PCM

MPM

Dilution Network

Combinatorial Miromixer

New class of hybrid materials for detection, capture, and "on-demand" release of carbon monoxide

Pitto-Barry, Anaïs, Lupan, A., Ellingford, C., Attia, A.A.A., Barry, Nicolas P.E.

13 April 2018

Yes / Carbon monoxide (CO) is both a substance hazardous to health and a side product of a number of industrial processes, such as methanol steam reforming and large-scale oxidation reactions. The separation of CO from nitrogen (N2) in industrial processes is considered to be difficult because of the similarities of their electronic structures, sizes, and physicochemical properties (e.g., boiling points). Carbon monoxide is also a major poison in fuel cells because of its adsorption onto the active sites of the catalysts. It is therefore of the utmost economic importance to discover new materials that enable effective CO capture and release under mild conditions. However, methods to specifically absorb and easily release CO in the presence of contaminants, such as water, nitrogen, carbon dioxide, and oxygen, at ambient temperature are not available. Here, we report the simple and versatile fabrication of a new class of hybrid materials that allows capture and release of carbon monoxide under mild conditions. We found that carborane-containing metal complexes encapsulated in networks made of poly(dimethylsiloxane) react with CO, even when immersed in water, leading to dramatic color and infrared signature changes. Furthermore, we found that the CO can be easily released from the materials by simply dipping the networks into an organic solvent for less than 1 min, at ambient temperature and pressure, which not only offers a straightforward recycling method, but also a new method for the “on-demand” release of carbon monoxide. We illustrated the utilization of the on-demand release of CO from the networks by carrying out a carbonylation reaction on an electron-deficient metal complex that led to the formation of the CO-adduct, with concomitant recycling of the gel. We anticipate that our sponge-like materials and scalable methodology will open up new avenues for the storage, transport, and controlled release of CO, the silent killer and a major industrial poison. / The Royal Society, The Romanian Ministry of Education and Research, The University of Bradford, European Regional Development Fund of the European Union / Research Development Fund Publication Prize Award winner.

Carbon monoxide capture

Carbon monoxide release

Electron-deficient complexes

Organometallic chemistry

PDMS networks

A process recipe for bonding a silicone membrane to a plastic substrate

Schönström, Linus, Nordh, Anna, Strignert, Anton, Lemel, Frida, Ekengard, Jakob, Wallin, Sofie, Jabri, Zargham

January 2013

A spin-cast silicone membrane has been successfully bonded between two injection-molded microstructured plastic discs. This sandwich structure creates a useful platform for mass production of microfluidic systems, provided that the bonds are leakproof. The bonds were achieved by a silicon dioxide coating deposited on the plastic discs by evaporation. This investigation is concerned with the process and the result only, no theory is discussed.

bonding silicone

corona surface treater

SiO2 coating

thermoplastic substrate

PVD temperature

PDMS membrane

spin-coating

thickness measurements

microfluidic systems

bonding PDMS

silicon dioxide coating

spin-cast

silicone membrane

PDMS

polydimethylsiloxane

poly(dimethylsiloxane)

silicon dioxide PVD

SiO2 PVD

silicon dioxide evaporation

SiO2 evaporation

thickness of a thin film

silicon dioxide deposition

SiO2 deposition

adhesion testing

cycloolefincopolymer

cycloolefinpolymer

cyclic olefin copolymer

cyclic olefin polymer

COC

COP

plasma surface treater

surface activator

surface oxidizer

Electrically Actuated Micropost Arrays for Droplet Manipulation

Gerson, Jonas Elliott

04 March 2013

Precise manipulation of heterogeneous droplets on an open droplet microfluidic platform could have numerous practical advantages in a broad range of applications, from proton exchange membrane (PEM) fuel cells and microreactors, to medical diagnostic platforms capable of assaying complex biological analytes. Toward the aim of developing electrically controllable micropost arrays for use in open droplet manipulation, custom-designed titanium dioxide (TiO2)- loaded poly(dimethylsiloxane) (PDMS) micropost arrays were developed in this work and indirectly mechanically actuated by applying an electric field. Initial experiments explored the bulk properties of TiO2-loaded PDMS films, with scanning electron microscopy (SEM) confirming a uniform TiO2 particle distribution in the PDMS, and tensile testing of bulk films showing an inverse relationship between TiO2 % (w/w) and Young’s Modulus with the Young’s Moduli quantified as 4.22 ± 0.51 MPa for unloaded PDMS, 2.27 ± 0.18 MPa for 10 % (w/w) TiO2, and 1.39 ± 0.20 MPa for 20 % (w/w) TiO2. Following bulk material evaluation, soft lithography methods were developed to fabricate TiO2- loaded PDMS micropost arrays. Mathematical predictions were applied to design microposts of varying shape, length, and gap spacing to yield super-hydrophobic surfaces actuatable by an electric field. Visual inspection and optical microscopy of the resulting arrays confirmed a non- collapsed micropost geometry. Overall, round microposts that were 100, 200, and 300 μm in length, 15 μm in diameter, and spaced 50 μm apart were produced largely free of defects, and used in contact angle measurements and micropost deflection experiments. Droplet contact angles measured on the arrays remained above 120° indicating the arrays successfully provided super- hydrophobic surfaces. Individual microposts deflected most notably above an electric field strength of 520 kV/m (12.5 kV nominal voltage). The ability to mechanically deflect customized microposts using an electric field demonstrated by this work is promising for translating this technology to precise droplet manipulation applications. Indirect actuation of droplets could enable the manipulation of liquids with varying electrical properties, which is a limitation of current micropumping technologies. Once optimized, electrically actuated micropost arrays could significantly contribute to the micro- handling of heterogeneous, highly ionic, and/or deionized fluids. / Thesis (Master, Chemical Engineering) -- Queen's University, 2013-03-03 17:25:49.785

superhydrophobic

wetting gradient

droplet microfluidics

PDMS

polydimethylsiloxane

titanium dioxide

digital microfluidics

lab on a chip

micropost

micropillar

array

dielectric elastomer actuator

high aspect ratio

FABRICATION AND STUDY OF AC ELECTRO-OSMOTIC MICROPUMPS

Guo, Xin

07 May 2013

In this thesis, microelectrode arrays of micropumps have been designed, fabricated and characterized for transporting microfluid by AC electro-osmosis (ACEO). In particular, the 3D stepped electrode design which shows superior performance to others in literature is adopted for making micropumps, and the performance of such devices has been studied and explored. A novel fabrication process has also been developed in the work, realizing 3D stepped electrodes on a flexible substrate, which is suitable for biomedical use, for example glaucoma implant. There are three major contributions to ACEO pumping in the work. First, a novel design of 3D “T-shaped” discrete electrode arrays was made using PolyMUMPs® process. The breakthrough of this work was discretizing the continuous 3D stepped electrodes which were commonly seen in the past research. The “T-shaped” electrodes did not only create ACEO flows on the top surfaces of electrodes but also along the side walls between separated electrodes. Secondly, four 3D stepped electrode arrays were designed, fabricated and tested. It was found from the experiment that PolyMUMPs® ACEO electrodes usually required a higher driving voltage than gold electrodes for operation. It was also noticed that a simulation based on the modified model taking into account the surface oxide of electrodes showed a better agreement with the experimental results. It thus demonstrated the possibility that the surface oxide of electrodes had impact on fluidic pumping. This methodology could also be applied to metal electrodes with a native oxide layer such as titanium and aluminum. Thirdly, a prototype of the ACEO pump with 3D stepped electrode arrays was first time realized on a flexible substrate using Kapton polyimide sheets and packaged with PDMS encapsulants. Comprehensive experimental testing was also conducted to evaluate the mechanical properties as well as the pumping performance. The experimental findings indicated that this fabrication process was a promising method to create flexible ACEO pumps that can be used as medical implants and wearable devices. / Thesis (Ph.D, Mechanical and Materials Engineering) -- Queen's University, 2013-05-06 10:57:48.077

microfluidics

PDMS

Kapton

microelectrode

polyimide

SU-8

T-shaped electrodes

HSQ

surface oxide

PolyMUMPs

surface modification

microchannel

electro-osmosis

electrokinetic

MEMS

micropump

microfabrication

bonding

Avaliação de sistemas de cultivo in vitro em micropoços para embriões bovinos produzidos por handmade cloning (HMC)

Feltrin, Cristiano

January 2010

Sistemas de produção in vitro de embriões mamíferos muitas vezes requerem que o cultivo embrionário seja realizado de forma individualizada. Entretanto, os resultados obtidos com o cultivo in vitro (CIV) individual são inconstantes e, por vezes, inferiores ao CIV em grupo. Entre os sistemas que requerem o CIV individual, a técnica de handmade cloning (HMC) se destaca por produzir embriões sem zona pelúcida que não podem ser cultivados agrupados em protocolos convencionais de CIV. O objetivo deste experimento foi determinar as taxas de desenvolvimento in vitro e in vivo de embriões bovinos clonados pela técnica de HMC e submetidos a três diferentes sistemas de CIV em micropoços (Well of the well – WOW), sendo um industrial, confeccionado em polidimetilsiloxano (PDMS), que visou à padronização da configuração do sistema de CIV. Após 11 replicações, de 3.876 complexos cumuli-oócito bovinos maturados in vitro, 3.437 (88,6%) oócitos apresentaram a extrusão do 1º corpúsculo polar. Após a digestão da zona pelúcida, 2.992 estruturas foram bisseccionadas manualmente, com a produção de 2.288 hemi-citoplastos. Reconstruiram-se 1.011 embriões pela adesão de dois hemi-citoplastos a uma célula somática (célula-tronco mesenquimal bovina de uma fêmea adulta da raça Nelore), dos quais 751 (74,2%) embriões fusionaram após eletrofusão, sendo 715 ativados quimicamente. Os embriões clonados (n=705) foram então alocados aleatoriamente em três grupos experimentais para o CIV: Grupo 1 (G1) – micropoço modificado (WOW-modificado, FELTRIN et al., 2006a); Grupo 2 (G2) – micropoço convencional (WOW-convencional , VATJA et al., 2000); e Grupo 3 (G3) – micropoço – PDMS (WOW-PDMS) . Como grupo controle (FIV, Grupo 4, G4), 594 oócitos foram colocados em maturação, fecundação e cultivo in vitro, em paralelo aos grupos clonados. Os resultados das taxas de clivagem no Dia 2, de blastocisto no Dia 7 e de prenhez no Dia 30 de desenvolvimento foram analisados pelo teste do χ2 com nível de significância de 5%. Não houve diferença significativa quanto à taxa de clivagem nos diferentes grupos. Entretanto, a taxa de blastocisto (BL) no G1 (99/239; 41,4%) foi significativamente superior à observada no G2 (72/232; 31,0%) e no G3 (68/234; 29,1%), sendo estas últimas semelhantes entre si. A taxa de BL do grupo controle (315/594; 53,0%) foi superior aos três grupos experimentais. Finalmente, o desenvolvimento in vivo até o Dia 30 de prenhez não diferiu entre os grupos G1 (7/15; 46,7%), G2 (7/13; 53,9%) e G3 (6/16; 50,0%). O sistema em micropoço modificado promoveu melhores condições de CIV a embriões clonados por HMC, traduzido por maiores taxas de BL, não se refletindo, entretanto, em diferenças no desenvolvimento in vivo subseqüente à transferência para fêmeas receptoras. / In vitro production systems for mammalian embryos quite often require embryos to be cultured individually. However, results obtained after individual embryo in vitro culture (IVC) are frequently inconsistent and inferior to IVC in groups. The Handmade Cloning (HMC) procedure is among the systems that require individual IVC, since zona-free embryos cannot be grouped for culture by standard IVC protocols. The aim of this study was to evaluate the in vitro and in vivo development of bovine embryos cloned by HMC, after the IVC in three distinct microwell arrangements, including an industrial chip, manufactured in polydimethylsiloxane (PDMS), which aimed to standardize the pattern of the IVC system. After 11 replications, 3,437 (88.6%) oocytes were selected based on the extrusion of the first polar body, out of 3,876 in vitro-matured bovine cumuli-oocyte complexes. Following zona pellucida digestion, 2,992 structures were manually bisected, generating 2,288 hemi-cytoplasts. A total of 1,011 embryos were reconstructed by the adhesion of two hemi-cytoplasts to a somatic cell (bovine mesenchymal stem cells from an adult Nelore female), with 751 fusing (74.2%) following electrofusion, and 715 being chemically activated. Cloned embryos (n=705) were then randomly allocated to one of three IVC experimental groups: Group 1 (G1) – modified microwells (FELTRIN et al., 2006a); Group 2 (G2) – conventional microwells (VATJA et al., 2000); and Group 3 (G3) – microwells in PDMS. As control group (IVF, Group 4, G4), 594 oocytes were in vitro-matured, fertilized and cultured in parallel to the cloned groups. Cleavage, blastocyst and pregnancy rates evaluated on Days 2, 7 and 30 of development were analyzed by the χ2 test, for a significance level of 5%. No differences in cleavage rates were observed between groups. However, blastocyst rates in G1 (99/239; 41.4%) were significantly higher than in G2 (72/232; 31.0%) and in G3 (68/234; 29.1%), which did not differ between one another. Blastocyst rates in the IVF control group (315/594; 53.0%) were in turn higher than in all cloned experimental groups. Finally, in vivo development to Day 30 of pregnancy was not different between G1 (7/15; 46.7%), G2 (7/13; 53.9%) and G3 (6/16; 50.0%). In summary, the modified microwell system promoted superior development to the blastocyst stage than both the conventional and the DMPS-based microwell systems, with no impact on the subsequent in vivo development after transfer to female recipients.

Biotécnicas de reprodução

Cultivo in vitro

Embrioes animais : Bovinos

Sistema de cultivo

Handmade cloning

Reprodução animal : Bovinos

Handmade cloning (HMC)

Well-of-the-well (WOW)

In vitro culture (IVC)

PDMS

Silicone supramoléculaire : un nouveau concept permettant l'auto-cicatrisation / Supramolecular silicone : a new concept allowing self-healing

Simonin, Léo

03 December 2018

Les silicones auto-cicatrisants de façon autonome (sans stimulus externe) présentent de faibles propriétés mécaniques, limitant leur utilisation industrielle. L’objectif de cette étude était de dépasser cette limitation. Nos travaux se sont intéressés aux copolymères segmentés PDMS-urée constitués de blocs souples (SS) et rigides (HS). Tout d’abord, nous avons étudié la relation entre la structure des bis-urées et les propriétés macroscopiques. Nous avons ainsi montré que la symétrie des HS gouverne la rigidité de ces matériaux. Toutefois, la présence de HS symétriques inhibe la cicatrisation du matériau. Puis, nous avons développé un nouveau concept permettant d’accélérer leur cinétique de cicatrisation. Un stoppeur de chaine macromoléculaire a été ajouté à la formulation de ces silicones thermoplastiques, créant un défaut dans l’assemblage supramoléculaire, conduisant à des clusters organiques plus petits et plus dynamiques. Néanmoins, contrairement aux plastifiants, la chute du module de Young observée par rapport à la matrice est limitée. D’ailleurs, nous reportons la synthèse d’un copolymère PDMS-urée avec un module de traction de 1MPa dont 90% de la contrainte à rupture peut être récupérée après cicatrisation pendant 24h à 25°C. Ce concept a aussi été adapté à un thermoplastique commercial (GENIOMER80). Enfin, notre défi a été d’optimiser la balance entre rigidité et autocicatrisation. Dans ce contexte, nous avons synthétisé de nouvelles matrices plus rigides, ainsi que des additifs avec des groupements associatifs de plus grande énergie cohésive. Nous avons alors pu repousser la limite de rigidité accessible aux silicones auto-cicatrisants de façon autonome (3MPa). / Autonomous self-healable (without external stimulus) silicones exhibit too low mechanical properties restricting their use in industry. The aim of this study was to overcome this limitation. We focused our work on segmented PDMS-urea copolymers made of soft (SS) and hard segments (HS). First the investigation of the relationship between the bis-urea chemical structure and the macroscopic properties was made. Results shown that, the symmetry of HS governs materials rigidity. Moreover, with a too symmetrical HS, the material does not exhibit self-healing abilities. We have developed a new concept improving the healing efficiency of these materials. The idea was to add to the formulation of these silicone thermoplastics a macromolecular chain stopper. The new additive creates a defect in the supramolecular assembly which leads to smaller and more dynamic H-bonding clusters and hence a faster healing kinetic. Unlike plasticizers, this additive deteriorates the tensile modulus only marginally. We therefore report a stress at break recovery of 90% after 24 hours at room temperature for a PDMS-urea copolymer with a tensile modulus of 1MPa. The concept was also extented to a commercial thermoplastic (GENIOMER80). Finally, our last challenge was to manage the balance between rigidity and chains dynamics allowing self-healable materials with good mechanical properties. In this context we have synthesized new matrixes with higher HS percentage and additives with stickers with higher cohesive energy. These new syntheses have led to an improvement of the rigidity limit reachable by the autonomous self-healable silicones (3MPa).

Silicone

Autocicatrisation

Liaisons hydrogène

Stoppeur de chaine

Bis-Urée

Polymères segmentés

Silicone

Self-healing

H-bonding

Chain stopper

PDMS-urea

Segmented polymers

541.2254