Water ingression into poly(imide-siloxane)s

Kaltenecker-Commerçon, Joyce Marie, 1965-

06 June 2008

The interaction of water vapor with the surface and bulk of poly(imidesiloxane) copolymers has been characterized in an attempt to determine the important factors in the copolymer's resistance to water ingression. The multi-block copolymers were synthesized from benzophenone tetracarboxylic dianhydride, bisaniline P and pre-formed amine-terminated poly(dimethylsiloxane) oligomers, with phthalic anhydride as an end-capping agent. Similar copolymers had been previously shown to have reduced water sorption, increased surface hydrophobicity, and increased adhesive durability in hot/wet environments. Inverse gas chromatography was used to conduct surface energetics studies on copolymers of different siloxane concentration and a polyirnide homopolymer. Free energies of specific interaction of water vapor, ΔG_sp°, with the polymer surfaces were found to decrease with the incorporation of siloxane into the polyirnide. The dispersive components of the solid surface free energy of the siloxane- containing copolymers were equal within error to that of pure poly(dimethylsiloxane), indicating a PDMS-rich, hydrophobic surface. The ΔG_sp° of the copolymers were not significantly different, suggesting that the copolymer surfaces were very similar. This indicated a minimum weight percent of siloxane incorporation required to maximize the copolymer's surface water resistance. The minimum amount for the studied system was at most ten percent. Diffusion coefficients of water vapor in the polyimide and copolymers were determined from gravimetric sorption experiments. Higher levels of siloxane incorporation caused a definite increase in the diffusion coefficient, indicating a decreased resistance to water ingression. The increase in diffusion was found to be influenced by siloxane block length and was interpreted in terms of morphological and free volume theories. The diffusion coefficient of a 10 weight percent PDMS copolymer, however, was found to be the same within error as the polyimide diffusion oefficient. The incorporation of siloxane into polyimides has been shown to increase water resistance due to the hydrophobicity of the siloxane-rich surface. However, high siloxane contents also increased the rate of water ingression in the bulk of the polymer. Increased water resistance of the surface may be achieved at lower siloxane concentrations without increasing diffusive (or decreasing mechanical) properties to undesirable levels. / Ph. D.

LD5655.V856 1992.K358

Block copolymers

Polyimide siloxanes

Water vapor transport

Synthesis and Characterization of Phosphine Oxide Containing Monomers and of the Flame Resistant Polymers Prepared Therefrom

Tchatchoua, Ngassa

05 May 2000

This thesis has focused on the synthesis and characterization of amino functional monomers, principally monomers containing aryl phosphine oxide units. Utilization of these monomers was demonstrated in various types of linear and network polymerizations. The diamines monomers included bis(3-aminophenyl) methyl phosphine oxide (DAMPO), bis(3-aminophenyl) phenyl phosphine oxide (DAPPO), bis(3-aminophenoxy phenyl) phenyl phosphine oxide (BAPPO) and bis(3-aminophenoxy phenyl) methyl Phosphine oxide (BAMPO). From these monomers high molecular weight poly(ether imides), polyurea-urethanes, poly(arylene ether ketones) poly(arylene ether sulfones) and poly(arylene ether phosphine oxides) were. Internal and external fire testing methodologies showed that the new polymers containing phosphine oxide units were fire resistant while maintaining the desirable physical characteristics of carefully selected control systems. In addition, suitable curing schedules for epoxy networks were determined by using dielectric monitoring techniques. The curing rates varied with the structure of the monomers and were slowest for the deactivated control (4,4'aminophenyl sulfone). Epoxy networks containing aryl phosphine oxide units had higher char yields in dynamic thermogravimetric analyses than control specimens. This correlated with their superior flame resistance. The brittle epoxy matrices were subsequently modified with reactive or non-reactive thermoplastic polymers in order to improve their fracture toughness. Poly(ether imides) and poly(ether sulfones) showed good phase separation behavior with tetrafunctional epoxy matrices during the curing reactions, as confirmed by scanning electron microscopy (SEM) and dynamic mechanical analysis (DMA). Mechanical tests showed that reactive thermoplastic modification of the epoxy networks improved the fracture toughness of the systems, without noticeable decreases in other characteristics such as flexural modulus. Reactive systems also maintained chemical resistance in contrast to non-reactive thermoplastic controls. / Ph. D.

polyimide modified epoxy resins

Phosphorus monomers

toughened networks

flame retardant polymers

Synthesis and Characterization of Wholly Aromatic, Water-Soluble Polyimides and Poly(amic acid)s Towards Fire Suppression Foams

Stovall, Benjamin Joseph

28 May 2021

Polyimides epitomize one of the most versatile high-performance engineering polymers. Polyimides are inherently mechanically robust, chemically inert, and thermooxidatively stable to 400+ °C depending on their chemical structure, enabling their function in numerous aerospace, electronic, medical, and flame-retardant applications. Polyimides can be highly modular even within synthetic limitations, which promotes and sustains innovative research. One recent interest concerns the innovation of fire suppression foams. Aqueous film-forming foams (AFFFs) are regularly sought when engaging liquid fuel (gasoline, jet fuel) fires. AFFFs utilize perfluorinated compounds (PFCs) like perfluorooctanesulfonic acid (PFOS) and perfluorooctanoic acid (PFOA), which exhibit toxicity, bioaccumulation, and persistence in the environment resulting in the presence of fluorosurfactant chemicals in environments either through direct or secondary exposure via chemical migration. Recently, the USEPA has even detected PFAS in drinking water at hundreds of military training facilities and civilian airports. While fluorinated compounds provide desirable thermooxidative stability and excellent fire retardancy, the environmental impact imposed by these chemicals strongly encourages research that targets the complete removal of PFCs in conventional formulations. This thesis focuses on the fundamental development of water-soluble sulfonated polyimide (sPI) and poly(amic acid) (sPAA) systems for next-generation polymer-based fire suppression foams. The use of sulfonated monomers and poly(amic acid) salt formation enables tunable structures and water solubilities. The polymers maintain competitive thermal stabilities to conventional polyimides and, when combined with readily available, non-toxic surfactants (SDS), produce stable foams. The MIL-F-24385F performance requirement evaluates foam quality/stability, drainage time, and burnback resistance to access viability and provides comparison to other systems; preliminary testing shows that sPI/sPAA formulations perform well. Solution rheology offers insights into fundamental scaling relationships of specific viscosity vs. concentration in both salt and salt-free solution that are important to future foam development. Additionally, the structural nature of the sPIs/ sPAAs allows for their modification with phosphonium moieties or siloxanes, which are slated to have positive effects on performance. Overall, these sPIs and sPAAs provide a promising platform for the future direction of fire suppression foams. / Master of Science / High-performance polymers are used in the most demanding of engineering applications. Polyimides represent one of the most versatile high-performance polymers. Polyimides are mechanically strong, chemically inert, and resistant to extreme temperatures depending on their chemical structure, allowing their use in numerous aerospace, electronic, medical, and flame-retardant applications. Polyimides are synthetically versatile, which enables the discovery of new uses after decades of research. One new targeted application is fire suppression foams. Aqueous film-forming foams (AFFFs) are the standard when battling liquid fuel (gasoline, jet fuel) fires. AFFFs contain perfluorinated compounds (PFCs), which are toxic and persist in the environment; they migrate easily to affect indirectly exposed ecosystems. Recently, the USEPA has even detected PFAS in drinking water at hundreds of military training facilities and civilian airports. While AFFFs with PFCs are highly effective, replacement materials are needed. This thesis focuses on the fundamental development of water-soluble sulfonated polyimide (sPI) and poly(amic acid) (sPAA) systems for fire suppression foams. The polymers remain thermally stable, and when combined with readily available surfactants (SDS), produce stable foams. Preliminary fire testing shows that sPI/sPAA formulations perform well against military specifications. Solution rheology (study of flow) explores the solution behavior of sPI, which offers insights into fundamental concentration-viscosity relationships that are important to future foam development. Additionally, the structural nature of the sPIs/ sPAAs allows for their modification with phosphonium groups or siloxanes, which changes their characteristics. Overall, these sPIs and sPAAs are initially promising for the future direction of fire suppression foams.

polyimide

poly(amic acid)

AFFF

fire suppression

phosphonium

siloxane

rheology

aqueous foam

high-performance

Development of Bio-Impedance microprobes for Integration with a Smart Biopsy tool

Jayabalan, Vivek

14 November 2014

Biopsy is a standard practice in the diagnosis and treatment of many cancers. Despite its integral role in cancer diagnosis, in some instances, the biopsy tool facilitates metastasis by transferring cancerous cells attached to its exterior into the healthy tissue or the blood circulation during its retraction from the tumor. These few cancer cells can then serve as seeds for the malignant tumor to grow in the healthy tissue. Cauterization using extreme heat or cold can destroy cells in the region and minimize the chance of seeding but this can be an inexact process that increases damage to otherwise healthy tissue and prolongs healing time following a biopsy procedure. In our laboratory, we have developed the concept of a new smart biopsy tool that can reduce the chance of cancer cell dissemination during a biopsy. This tool improves on the conventional biopsy needle by introducing an impedance sensor on the biopsy tool which is housed in a sliding sheath. Due to the significant difference in the electrical conductivity of the tumor and the healthy tissue, the sensor is able to distinguish between the two and locate the exact tumor interface. The protective sheath placed around the instrumented biopsy tool and above the interface isolates the healthy tissue and prevents or at least minimizes the transfer of tumor cells. Delivering an RF dose through the sheath can kill any malignant cells that might be lurking around the interface. This thesis, in particular, will concentrate on the development of the design, fabrication and calibration of the impedance sensor and its integration with the biopsy tool. The impedance sensor essentially consists of conductive electrodes sandwiched between insulating layers. They are built on thin-film polymer, Polyimide, using conventional microfabrication techniques. These sensors are further calibrated to estimate the cell constant. Once calibrated, these probes are used to measure the conductivity of porcine tissues, and in-house prepared agar phantoms. / Master of Science

Bio-Impedance Micro Probes

Smart Biopsy tool

Cancer Cell Seeding

Prevention

Micro fabrication

Polyimide

Desenvolvimento de materiais híbridos baseados em poliimida / Development of hybrid materials based on polyimide

Ferreira, Fábio Augusto de Souza

10 July 2014

Nesse trabalho são discutidos os resultados a respeito de materiais híbridos baseados na poliimida, PI, obtida por reações de policondensação entre a diamina 4,4\'-Oxidianilina (ODA) e o dianidrido 4,4\'-Oxidiftálico (ODPA), seguida de imidização térmica. O estudo foca na influência do tempo de tratamento (1, 15 e 60 min) e na temperatura de decomposição térmica (500°C) sobre as propriedades da PI. Os experimentos foram realizados sob fluxo de Argônio e os materiais obtidos apresentam características intermediárias entre PI e materiais carbonáceos. Dados de Nanoindentação (NI) revelaram aumento de até 50% de dureza para os filmes tratados por 60 min. ODPA e ODA serviu ainda de base para a preparação do revestimento híbrido contendo ORMOSIL gerado in situ por catálise ácida via processo sol-gel a partir do (3-aminopropil)trietóxissilano (APTES) e Tetraetil Ortossilicato (TEOS). O revestimento obtido é homogêneo e tem boa interação com o substrato (aço inoxidável 316L). A polarização potenciodinâmica revelou uma proteção elevada tanto em solução de NaCl 3,5% em massa quanto em H2SO4 0,5 mol L-1, em relação ao aço sem revestimento, com densidade de corrente da ordem de 10-9 A cm-2, na faixa de -700 a 500 mV vs Ag/AgCl. Por fim, filmes híbridos baseados em ODPA, ODA, APTES e TEOS, adicionados de Ácido Fosfotungstico (HPW) foram preparados e avaliados por Espectroscopia na região do Infravermelho com Transformada de Fourier e Ressonância Magnética Nuclear de Silício e Fósforo (29Si e 31P MAS NMR) que confirmaram a formação da PI e da rede ORMOSIL, bem como revelam que a estrutura do HPW permaneceu intacta após o processo de síntese. Mapeamentos realizados por Micro-fluorescência de Raios X assistida por Luz Síncrotron (μ-XRF) mostram uma boa dispersão da fase inorgânica (ORMOSIL e HPW) na orgânica (POO), e todos os materiais são termicamente estáveis até aproximadamente 500°C, de acordo com as curvas obtidas por Termogravimetria (TGA). Outras técnicas de caracterização também foram usadas para uma investigação mais detalhada dos materiais. / In this thesis are presented the results and considerations related to several hybrid materials derived from the polyimide, PI, obtained by polycondensation reactions between 4,4\'-Oxydianiline (ODA) and 4,4\'-Oxydiphthalic (ODA), followed by thermal imidization. The study focuses on the effect of thermal treatment time (1, 15 and 60 min) and the temperature of beginning of thermal decomposition (773 K) on the properties of PI. The experiments were performed under Argon flow, and the materials presented intermingled properties of PI and carbonaceous materials. The hardness, evaluated by Nanoindentation (NI), reached an increase of 50% for POO films treated for 60 min. POO was also used for the preparation of the hybrid coating containing ORMOSIL obtained in situ by acid catalysis via sol-gel process from (3-aminopropyl)triethoxysilane (APTES) and Tetraethyl Orthosilicate (TEOS). The coating is homogeneous and present a good interaction with the substrate (316L stainless steel). Data of potendynamic polarization revealed a high protection both under NaCl 3.5 wt% and H2SO4 0.5 mol L-1 solutions related to the neat substrate, with current density of order 10-9 A cm-2, in range potential of -700 to 500 mV vs Ag/AgCl. Finally, hybrid films were prepared based on ODPA, ODA, APTES and TEOS, in addition to Phosphotungstic Acid (HPW). The characteristics of all materials were evaluated by Fourier Transform Infrared Spectroscopy in Middle and Near Infrared region (FTMIR and FTNIR), and Magic Angle Spinning-Nuclear Magnetic Resonance of Silicon 29 and Phosphorus 31 (29Si and 31P MAS NMR) which confirmed the ORMOSIL network formation, as well as revealed that the HPW structure remained intact after the synthesis process. Mapping performed by Assisted Synchrotron Light X-ray Micro Fluorescence (μ-XRF) the good dispersion of the inorganic phase (ORMOSIL and HPW) in the organic phase (POO). All materials are thermally stable up to 773 K, according to Thermogravimetric Analysis (TGA). Other techniques of characterization were also used to further investigation of the materials.

Anticorrosive coating

Dielectric materials

HPW

HPW

Hybrid materials

Materiais dielétricos

Materiais híbridos

ORMOSIL

ORMOSIL

Poliimida

Polyimide

Revestimento anticorrosivo

ETUDE DES PROPRIETES ELECTRIQUES D'UN MATERIAU POLYIMIDE A HAUTE TEMPERATURE : APPLICATION A LA PASSIVATION DES COMPOSANTS DE PUISSANCE EN CARBURE DE SILICIUM

Zelmat, Samir

30 March 2006

L'objectif de cette étude est d'évaluer les potentialités du polyimide pour la passivation des composants de puissance en carbure de silicium (SiC), laquelle sera soumise à des températures et des champs électriques nettement supérieurs à ceux rencontrés dans l'environnement des puces en silicium (jusqu'à 350°C et 3 MV/cm respectivement).<br />Pour quantifier les propriétés ‘intrinsèques' du polyimide, des caractérisations électriques ont été réalisées dans une gamme de température étendue jusqu'à 260 °C, sur des structures MIM (Métal Isolant Métal), avec des films de polyimide élaborés selon le procédé de fabrication standard préconisé par le fabricant. Les résultats ont montré de bonnes propriétés électriques à température ambiante et jusqu'à 180 °C. Cependant, des valeurs de facteur de pertes et de permittivité diélectrique trop élevées pour satisfaire l'application visée ont été montrées au-delà de 180°C. Une amélioration des propriétés diélectriques et d'isolation a été cependant observée après la réalisation d'un traitement thermique additionnel, dans lequel les échantillons sont exposés longuement à des températures élevées, indiquant que la stabilité des propriétés du matériau n'est pas atteinte à l'issue du recuit d'imidisation du film polyimide.<br />L'analyse des caractérisations électriques et physico-chimiques montrent que cette instabilité est liée à l'évolution du taux d'imidisation de l'acide polyamique en polyimide, et de la concentration d'impuretés résiduelles (eau, solvant) lesquels dépendent des paramètres (durée, température) du recuit final d'élaboration du polyimide. Cette étude a permis de mettre en évidence la nécessité d'optimiser le recuit d'imidisation du procédé d'élaboration du film de polyimide afin d'obtenir des propriétés électriques adaptées au cahier des charges de l'application visée, dans une gamme de température étendue jusqu'à 350 °C.

Polyimide

Passivation

Carbure de silicium

Caractérisations électriques

Haute température

Imidisation

Thermally crosslinked polyimide hollow fiber membranes for natural gas purification

Chen, Chien-Chiang

05 October 2011

Robust industrially relevant membranes for CO₂ removal from aggressive natural gas feed streams were developed and characterized. Asymmetric hollow fiber membranes with defect-free selective skin layers on an optimized porous support substructure were successfully spun and subsequently stabilized by covalent crosslinking within the economical membrane formation process. Thermal treatment conditions, which promote sufficient crosslinking without introducing defects or undesired substructure resistance, were identified. It was found that crosslinking improves membrane efficiency and plasticization resistance as well as mechanical strength of fibers. The capability to maintain attractive separation performance under realistic operating conditions and durability against deleterious impurities suggests that the crosslinked fibers have great potential for use in diverse aggressive applications, even beyond the CO₂/CH₄ example explored in this work.

Membrane

Gas separation

Polyimide

Crosslinked polymer

Natural gas

Hollow fiber

Gases Purification

Gases Separation

Separation (Technology)

Membranes (Technology)

Modeling Time-dependent Responses of Piezoelectric Fiber Composite

Li, Kuo-An

2009 December 1900

The existence of polymer constituent in piezoelectric fiber composites (PFCs) could lead to significant viscoelastic behaviors, affecting overall performance of PFCs. High mechanical and electrical stimuli often generate significant amount of heat, increasing temperatures of the PFCs. At elevated temperatures, most materials, especially polymers show pronounced time-dependent behaviors. Predicting time-dependent responses of the PFCs becomes important to improve reliability in using PFCs. We study overall performance of PFCs having unidirectional piezoceramic fibers, such as PZT fibers, dispersed in viscoelastic polymer matrix. Two types of PFCs are studied, which are active fiber composites (AFCs) and macro fiber composites (MFCs). AFCs and MFCs consist of unidirectional PZT fibers dispersed in epoxy placed between two interdigitated electrode and kapton layers. The AFCs have a circular fiber cross-section while the MFCs have a square fiber cross-section. Finite element (FE) models of representative volume elements (RVEs) of active PFCs, having square and circular fiber cross-sections, are generated for composites with 20, 40, and 60 percent fiber contents. Two FE micromechanical models having one fiber embedded in epoxy matrix and five fibers placed in epoxy matrix are considered. A continuum 3D piezoelectric element in ABAQUS FE is used. A general time-integral function is applied for the mechanical, electrical, and piezoelectric properties in order to incorporate the time-dependent effect and histories of loadings. The effective properties of PZT-5A/epoxy and PZT-7A/LaRC-SI piezocomposites determined from the FE micromechanical models are compared to available experimental data and analytical solutions in the literature. Furthermore, the effect of viscoelastic behaviors of the LaRC-SI matrix at an elevated temperature on the overall electro-mechanical and piezoelectric constants are examined.

PFC

AFC

MFC

piezoelectric composite

PZT-7A

PZT-5A

epoxy

LaRC-SI

polyimide

finite element

viscoelastic

time-dependent

creep

relaxation

Crosslinkable mixed matrix membranes for the purification of natural gas

Ward, Jason Keith

11 January 2010

Mixed matrix nanocomposite membranes composed of a crosslinkable polyimide matrix and high-silica molecular sieve particles were developed for purifying natural gas. It was shown that ideal mixed matrix effects were not possible without sieve surface modification. A previously developed Grignard procedure was utilized to deposit magnesium hydroxide nanostructures on the sieve surface in order to enhance polymer adhesion. Analyses of Grignard-treated sieves pointed to the formation of non-selective voids within the surface deposited layer. These voids were suspected to lead to lower-than-expected membrane performance. In order to improve membrane transport, a reactive sizing procedure was developed to fill these voids with polyimide-miscible material. In a serendipitous discovery, as-received sieves--when treated with this reactive sizing procedure--resulted in nearly identical membrane performance as reactive-sized, Grignard-treated sieves. This observation lead to the speculation of a non-ideal transport mechanism in mixed matrix membranes.

Nanocomposite

Mixed matrix membrane

Polyimide

Gas separation

Crosslinkable polymer membrane

Natural gas Purification

Gas separation membranes

Crosslinked polymers

Crosslinked polyimide hollow fiber membranes for aggressive natural gas feed streams

Omole, Imona C.

01 December 2008

Natural gas is one of the fastest growing primary energy sources in the world today. The increasing world demand for energy requires increased production of high quality natural gas. For the natural gas to be fed into the mainline gas transportation system, it must meet the pipe-line quality standards. Natural gas produced at the wellhead is usually "sub-quality" and contains various impurities such as CO2, H2S, and higher hydrocarbons, which must be removed to meet specifications. Carbon dioxide is usually the most abundant impurity in natural gas feeds and high CO2 partial pressures in the feed can lead to plasticization, which causes loss of some methane product and may ultimately render the membrane ineffective. Moreover, the presence of highly sorbing higher hydrocarbons in the feed can further reduce membrane performance. Covalent crosslinking has been shown to increase plasticization resistance in dense films by suppressing the degree of swelling and segmental chain mobility in the polymer, thereby preserving the selectivity of the membrane. This research focuses on extending the dense film success to asymmetric hollow fibers. In this work, the effect of high pressure CO2 (up to 400 psia CO2 partial pressure) on CO2/CH4 mixed gas separation performance was investigated on defect-free the hollow fiber membrane at different degrees of crosslinking. All the crosslinked fibers were shown to exhibit good resistance to selectivity losses from CO2 induced plasticization, significantly more than the uncrosslinked fibers. Robust resistance of the hollow fiber membranes in the presence of toluene (a highly sorbing contaminant) was also demonstrated as the membranes showed no plasticization. Antiplasticization was found to occur in the presence of toluene feeds with the crosslinkable fibers used in this work.

Membrane

Carbon dioxide

Natural gas

Hollow fiber

Polyimide

Gas separation

Gas separation membranes

High pressure (Technology)

Natural gas

Crosslinked polymers