Termodinâmica da partição do poli (oxido de propileno) em sistemas bifasicos aquosos/orgânicos / Thermodynamics of partitioning of poly (propylene oxide) in aqueous/organic systems

Anselmo, Aleteia Garcia

10 March 2006

Orientador: Watson Loh / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-07T11:45:40Z (GMT). No. of bitstreams: 1 Anselmo_AleteiaGarcia_M.pdf: 1348079 bytes, checksum: 03480ee468bf0185ae57c464c2020046 (MD5) Previous issue date: 2006 / Resumo: Neste trabalho estudou-se a partição do poli (óxido de propileno), PPO, poli (N - isopropilacrilamida), PNIPAM, poli (N-vinil-2- pirrolidona), PVP, e poli (óxido de etileno), PEO em sistemas líquidos bifásicos, entre as fases aquosa e orgânica (CHCI3, CH2Cl2 e C6H5CI). Os resultados obtidos indicaram que a partição do PPO, polímero hidrofóbico, é preferencial para as fases orgânicas em todos os sistemas bifásicos estudados, enquanto que para os polímeros hidrofílicos, tais como, o PVP e PNIPAM, a partição ocorre preferencialmente para a fase aquosa. As entalpias de transferência, da fase aquosa para a fase orgânica para estes polímeros, foram determinadas através da técnica de titulação calorimétrica isotérmica e revelaram que para todos os sistemas estudados o processo de transferência é endotérmico. Isto sugere que a solvatação dos polímeros pela fase aquosa é mais energética que quando comparada com a solvatação dos polímeros pela fase orgânica, e que, portanto, para o PPO, o processo de transferência é entropicamente dirigido. Spitzer e colaboradores observaram resultados similares para a partição do poli (óxido de etileno), PEO, em sistemas bifásicos contendo CHCl3 e CH2Cl2, (Spitzer et aI.; J. Phys. Chem. B 2002, 106, 12448). Em comparação com o PEO, os valores de entalpia de transferência obtidos para o PPO são mais positivos, o mesmo pode ser observado para o coeficiente de partição. A partição do PPO pode ser explicada em termos de efeito hidrofóbico, o qual propõe a liberação das moléculas de água que estariam solvatando o polímero quando este é transferido para a fase orgânica. / Abstract: In this work the partitioning of poly (propylene oxide), PPO, poly (Nisopropylacrylamide), PNIPAM, poly (vinyl pyrrolidone), PVP and poly (ethylene oxide), PEO between aqueous and organic phases (CHCI3, CH2Cl2 and C6H5CI) was investigated. The results reveal that for all biphasic systems the partitioning of PPO, a hydrophobic polymer, to organic phase is predominant, while for PVP and PNIPAM, hydrophilic polymers, partitioning is always preferential towards the aqueous phase. The enthalpies of transfer for these polymers from aqueous to organic phases were calorimetrically determined and revealed an endothermic process for all the systems investigated, suggesting that solvatation of polymers in aqueous phase is more energetic than organic phase and, therefore, the process of transfer must be entropically driven for PPO. Spitzer and coworkers observed similar results for the partitioning of PEO in biphasic systems containing CHCl3 and CH2Cl2, (Spitzer et aI.; J. Phys. Chem. B 2002, 106, 12448). In comparison with PEO, the enthalpies of transfer of PPO are more positive, the same being observed for the partition coefficients. These data indicate that partitioning of PPO can be explained within the framework of the hydrophobic effect, whereby water molecules that were originally solvating the polymer are released when this is transferred to the organic phase. / Mestrado / Físico-Química / Mestre em Química

Calorimetria

Poli (oxido de propileno)

Termodinâmica

Calorimetry

Poly (propylene oxide)

Thermodynamics

Enabling Synthesis Toward the Production of Biocompatible Magnetic Nanoparticles With Tailored Surface Properties

Thompson, Michael Shane

07 August 2007

Amphiphilic tri- and penta-block copolymers containing a polyurethane central block with pendant carboxylic acid groups flanked by hydroxyl functional polyether tails were synthesized. Our intention was to investigate the activities of these copolymers as dispersants for magnetite nanoparticles in biological media. A benzyl alkoxide initiator was utilized to prepare poly(ethylene oxide) (BzO-PEO-OH), poly(propylene oxide) (BzO-PPO-OH) and poly(ethylene oxide-b-propylene oxide) (poly(BzO-EO-b-PO-OH)) oligomeric tail blocks with varying lengths of PEO and PPO. The oligomers had a hydroxyl group at the terminal chain end and a benzyl-protected hydroxyl group at the initiated end. The polyether oligomers were incorporated into a block copolymer with a short polyurethane segment having approximately three carboxylic acid groups per chain. The block co-polyurethane was then hydrogenated to remove the benzyl group and yield primary hydroxyl functionality at the chain ends. End group analysis by 1H NMR showed the targeted ratio of PEO to PPO demonstrating control over block copolymer composition. Number average molecular weights determined by both 1H NMR and GPC were in agreement and close to targeted values demonstrating control over molecular weight. Titrations of the pentablock copolymers showed that the targeted value of approximately three carboxylic acid groups per chain was achieved. Heterobifunctional poly(ethylene oxide) (PEO) and poly(ethylene oxide-b-propylene oxide) (PEO-b-PPO) copolymers were synthesized utilizing heterobifunctional initiators to yield polymers having a hydroxyl group at one chain end and additional moieties at the other chain end. For PEO homopolymers, these moieties include maleimide, vinylsilane, and carboxylic acid functional groups. Heterobifunctional PEO oligomers with a maliemide end group were synthesized utilizing a double metal cyanide coordination catalyst to avoid side reactions that occur with a basic catalyst. PEO oligomers with vinylsilane end groups were synthesized via alkoxide-initiated living ring-opening polymerization, and this produced polymers with narrow molecular weight distributions. Heterobifunctional PEO-b-PPO block copolymers were synthesized in two steps where the double metal cyanide catalyst was used to polymerize propylene oxide (PO) initiated by 3-hydroxypropyltrivinylsilane. The PPO was then utilized as a macroinitiator to polymerize ethylene oxide (EO) with base catalysis. Heterobifunctional PEO and PEO-b-PPO block copolymers possessing carboxylic acid functional groups on one end were synthesized by reacting the vinyl groups with mercaptoacetic acid via an ene-thiol addition. / Ph. D.

dispersion stabilizers

poly(propylene oxide)

Heterobifunctional

(ethylene oxide)

Electrochemical in-situ polymerization of graphene oxide/conducting star copolymer nanocomposite as supercapacitor electrode

Elgmati, Rugia Ali

January 2017

>Magister Scientiae - MSc / These days there are deep concerns over the environmental consequences of the rate of consumption of energy from non-renewable sources because of the accelerated increase in greenhouse effect. There is, therefore, increasing interest in research activities on renewable energy systems (e.g., supercapacitors, batteries, fuel cells and photovoltaic cells) and their materials. Supercapacitor materials have attracted much attention because of their high energy storage capacity, large surface area, high specific power density (watts/kg) and low cost. The development of advanced supercapacitor devices requires active electrode materials with high storage capacity and dispensability. Graphene oxide-dendritic star copolymer nanocomposites are fascinating as electrode materials, both scientifically and technologically, due to their exceptional properties, including light weight and high potential. / 2020-08-31

Graphene oxide

Poly(propylene imine)-co-polypyrrole

Nanocomposite

Electropolymerization

Synthesis and electrochemistry of novel conducting dendrimeric star copolymers on poly(propylene imine) dendrimer

Baleg, Abd Almonam Abd Alsalam

January 2011

<p>One of the most powerful aspects of conducting polymers is their ability to be nanostructured through innovative, synthetically manipulated, transformations, such as to tailor-make the polymers for specialized applications. In the exponentially increasing wide field of nanotechnology, some special attention is being paid to innovative hybrid dendrimer-core based polymeric smart materials. Star copolymers are a class of branched macromolecules having a central core with multiple linear polymer chains extending from the core. This intrinsic structural feature yields a unique 3D structure with extended conjugated linear polymer chains, resulting in star copolymers, which have higher ionic conductivities than their corresponding non-star conducting polymer counterparts. In this study an in-depth investigation was carried out into the preparation and characterization of specialized electronic &lsquo / smart materials&rsquo / . In particular, the preparation and characterization of novel conducting dendrimeric star copolymers which have a central poly(propylene imine) (PPI) dendrimer core with conducting polypyrrole (PPy) chains extending from the core was carried out. This involved, first, the preparation of a series of dendrimeric polypyrrole poly(propylene imine) star copolymers (PPI-co-PPy), using generations 1 to 4 (G1 to G4) PPI dendrimer precursors. The experimental approach involved the use of both chemical and electrochemical synthesis methods. The basic procedure involved a condensation reaction between the primary amine of a diamino functional PPI dendrimer surface and 2-pyrrole aldehyde, to afford the pyrrole functionalized PPI dendrimer (PPI-2Py). Polymerization of the intrinsically contained monomeric Py units situated within the dendrimer backbone was achieved via two distinctly different routes: the first involved chemical polymerization and the second was based on potentiodynamic oxidative electrochemical polymerization. The star copolymers were then characterized using various sophisticated analytical techniques, in-situ and ex-situ. Proton nuclear magnetic resonance spectroscopy (1HNMR) and Fourier transform infrared spectroscopy (FTIR) were used to determine the structures. Scanning electron microscopy (SEM) was used to determine the morphology. Themogravimetric analysis (TGA) was used to study the thermal stability of the prepared materials. X-ray diffraction analysis (XRD) was used to study the structural make-up of phases, crystallinity and amorphous content. Hall effect measurements were carried out to determine the electrical conductivity of the chemically prepared star copolymers. The PPI-co-PPy exhibited improved thermal stability compared to PPI-2Py, as confirmed by TGA. SEM results showed that the surface morphology of the functionalized dendrimer and star copolymer differed. The surface morphology of the chemically prepared star copolymers resembled that of a flaky, waxy material, compared to the ordered morphology of the electrochemically grown star copolymers, which resembled that of whelk-like helixes. In the case the electrochemically grown star copolymers, SEM images recorded at higher magnifications showed that the whelk-like helixes of the star copolymers were hollow tubes with openings at their tapered ends, and had an average base diameter of 2.0 &mu / m. X-ray diffraction analysis of the first generation star copolymer G1PPI-co-PPy revealed a broadly amorphous structure associated with PPy, and crystalline peaks for PPI. Cyclic voltammetry (CV), square wave voltammetry (SWV) and electrochemical impedance spectroscopy (EIS) techniques were used to study and model the electrochemical reactivity of the star copolymer materials. Electrochemical impedance spectroscopy data showed that the G1PPI-co-PPy exhibited slightly higher ionic conductivity than pristine PPy in lithium perchlorate. The second generation star copolymer G2PPI-co-PPy electrochemically deposited on a platinum (Pt) electrode had a lower electrochemical charge transfer resistance compared to electrodeposited polypyrrole (PPy) on a Pt electrode, and bare Pt. The decrease in charge transfer resistance was attributed to an increase in the conjugation length of the polymer as a result of the linking of the highly conjugated PPy to the PPI dendrimer. Bode impedimetric analysis indicated that G2PPI-co-PPI was a semiconductor, with a maximum phase angle shift of 45.3&deg / at 100 MHz. The star copolymer exhibited a 2- electron electrochemistry and a surface coverage of 99%. Results of Hall effect measurements showed that the star copolymer is a semiconducting material, having a conductivity of 0.7 S cm-1, in comparison to the 1.5 S cm-1 of PPy. To the best of my knowledge, these new star copolymers have not been reported in the open literature. Their properties make them potentially applicable for use in biosensors.</p>

Synthesis and electrochemistry of novel conducting dendrimeric star copolymers on poly(propylene imine) dendrimer

Baleg, Abd Almonam Abd Alsalam

January 2011

<p>One of the most powerful aspects of conducting polymers is their ability to be nanostructured through innovative, synthetically manipulated, transformations, such as to tailor-make the polymers for specialized applications. In the exponentially increasing wide field of nanotechnology, some special attention is being paid to innovative hybrid dendrimer-core based polymeric smart materials. Star copolymers are a class of branched macromolecules having a central core with multiple linear polymer chains extending from the core. This intrinsic structural feature yields a unique 3D structure with extended conjugated linear polymer chains, resulting in star copolymers, which have higher ionic conductivities than their corresponding non-star conducting polymer counterparts. In this study an in-depth investigation was carried out into the preparation and characterization of specialized electronic &lsquo / smart materials&rsquo / . In particular, the preparation and characterization of novel conducting dendrimeric star copolymers which have a central poly(propylene imine) (PPI) dendrimer core with conducting polypyrrole (PPy) chains extending from the core was carried out. This involved, first, the preparation of a series of dendrimeric polypyrrole poly(propylene imine) star copolymers (PPI-co-PPy), using generations 1 to 4 (G1 to G4) PPI dendrimer precursors. The experimental approach involved the use of both chemical and electrochemical synthesis methods. The basic procedure involved a condensation reaction between the primary amine of a diamino functional PPI dendrimer surface and 2-pyrrole aldehyde, to afford the pyrrole functionalized PPI dendrimer (PPI-2Py). Polymerization of the intrinsically contained monomeric Py units situated within the dendrimer backbone was achieved via two distinctly different routes: the first involved chemical polymerization and the second was based on potentiodynamic oxidative electrochemical polymerization. The star copolymers were then characterized using various sophisticated analytical techniques, in-situ and ex-situ. Proton nuclear magnetic resonance spectroscopy (1HNMR) and Fourier transform infrared spectroscopy (FTIR) were used to determine the structures. Scanning electron microscopy (SEM) was used to determine the morphology. Themogravimetric analysis (TGA) was used to study the thermal stability of the prepared materials. X-ray diffraction analysis (XRD) was used to study the structural make-up of phases, crystallinity and amorphous content. Hall effect measurements were carried out to determine the electrical conductivity of the chemically prepared star copolymers. The PPI-co-PPy exhibited improved thermal stability compared to PPI-2Py, as confirmed by TGA. SEM results showed that the surface morphology of the functionalized dendrimer and star copolymer differed. The surface morphology of the chemically prepared star copolymers resembled that of a flaky, waxy material, compared to the ordered morphology of the electrochemically grown star copolymers, which resembled that of whelk-like helixes. In the case the electrochemically grown star copolymers, SEM images recorded at higher magnifications showed that the whelk-like helixes of the star copolymers were hollow tubes with openings at their tapered ends, and had an average base diameter of 2.0 &mu / m. X-ray diffraction analysis of the first generation star copolymer G1PPI-co-PPy revealed a broadly amorphous structure associated with PPy, and crystalline peaks for PPI. Cyclic voltammetry (CV), square wave voltammetry (SWV) and electrochemical impedance spectroscopy (EIS) techniques were used to study and model the electrochemical reactivity of the star copolymer materials. Electrochemical impedance spectroscopy data showed that the G1PPI-co-PPy exhibited slightly higher ionic conductivity than pristine PPy in lithium perchlorate. The second generation star copolymer G2PPI-co-PPy electrochemically deposited on a platinum (Pt) electrode had a lower electrochemical charge transfer resistance compared to electrodeposited polypyrrole (PPy) on a Pt electrode, and bare Pt. The decrease in charge transfer resistance was attributed to an increase in the conjugation length of the polymer as a result of the linking of the highly conjugated PPy to the PPI dendrimer. Bode impedimetric analysis indicated that G2PPI-co-PPI was a semiconductor, with a maximum phase angle shift of 45.3&deg / at 100 MHz. The star copolymer exhibited a 2- electron electrochemistry and a surface coverage of 99%. Results of Hall effect measurements showed that the star copolymer is a semiconducting material, having a conductivity of 0.7 S cm-1, in comparison to the 1.5 S cm-1 of PPy. To the best of my knowledge, these new star copolymers have not been reported in the open literature. Their properties make them potentially applicable for use in biosensors.</p>

Synthesis and electrochemistry of novel conducting dendrimeric star copolymers on poly(propylene imine) dendrimer

Baleg, Abd Almonam Abd Alsalam

January 2011

Philosophiae Doctor - PhD / One of the most powerful aspects of conducting polymers is their ability to be nanostructured through innovative, synthetically manipulated, transformations, such as to tailor-make the polymers for specialized applications. In the exponentially increasing wide field of nanotechnology, some special attention is being paid to innovative hybrid dendrimer-core based polymeric smart materials. Star copolymers are a class of branched macromolecules having a central core with multiple linear polymer chains extending from the core. This intrinsic structural feature yields a unique 3D structure with extended conjugated linear polymer chains, resulting in star copolymers, which have higher ionic conductivities than their corresponding non-star conducting polymer counterparts. In this study an in-depth investigation was carried out into the preparation and characterization of specialized electronic smart materials. In particular, the preparation and characterization of novel conducting dendrimeric star copolymers which have a central poly(propylene imine) (PPI) dendrimer core with conducting polypyrrole (PPy) chains extending from the core was carried out. This involved, first, the preparation of a series of dendrimeric polypyrrole poly(propylene imine) star copolymers (PPI-co-PPy), using generations 1 to 4 (G1 to G4) PPI dendrimer precursors. The experimental approach involved the use of both chemical and electrochemical synthesis methods. The basic procedure involved a condensation reaction between the primary amine of a diamino functional PPI dendrimer surface and 2-pyrrole aldehyde, to afford the pyrrole functionalized PPI dendrimer (PPI-2Py). Polymerization of the intrinsically contained monomeric Py units situated within the dendrimer backbone was achieved via two distinctly different routes: the first involved chemical polymerization and the second was based on potentiodynamic oxidative electrochemical polymerization. The star copolymers were then characterized using various sophisticated analytical techniques, in-situ and ex-situ. Proton nuclear magnetic resonance spectroscopy (1HNMR) and Fourier transform infrared spectroscopy (FTIR) were used to determine the structures. Scanning electron microscopy (SEM) was used to determine the morphology. Themogravimetric analysis (TGA) was used to study the thermal stability of the prepared materials. X-ray diffraction analysis (XRD) was used to study the structural make-up of phases, crystallinity and amorphous content. Hall effect measurements were carried out to determine the electrical conductivity of the chemically prepared star copolymers. The PPI-co-PPy exhibited improved thermal stability compared to PPI-2Py, as confirmed by TGA. SEM results showed that the surface morphology of the functionalized dendrimer and star copolymer differed. The surface morphology of the chemically prepared star copolymers resembled that of a flaky, waxy material, compared to the ordered morphology of the electrochemically grown star copolymers, which resembled that of whelk-like helixes. In the case the electrochemically grown star copolymers, SEM images recorded at higher magnifications showed that the whelk-like helixes of the star copolymers were hollow tubes with openings at their tapered ends, and had an average base diameter of 2.0 mu;m. X-ray diffraction analysis of the first generation star copolymer G1PPI-co-PPy revealed a broadly amorphous structure associated with PPy, and crystalline peaks for PPI. Cyclic voltammetry (CV), square wave voltammetry (SWV) and electrochemical impedance spectroscopy (EIS) techniques were used to study and model the electrochemical reactivity of the star copolymer materials. Electrochemical impedance spectroscopy data showed that the G1PPI-co-PPy exhibited slightly higher ionic conductivity than pristine PPy in lithium perchlorate. The second generation star copolymer G2PPI-co-PPy electrochemically deposited on a platinum (Pt) electrode had a lower electrochemical charge transfer resistance compared to electrodeposited polypyrrole (PPy) on a Pt electrode, and bare Pt. The decrease in charge transfer resistance was attributed to an increase in the conjugation length of the polymer as a result of the linking of the highly conjugated PPy to the PPI dendrimer. Bode impedimetric analysis indicated that G2PPI-co-PPI was a semiconductor, with a maximum phase angle shift of 45.3&deg; at 100 MHz. The star copolymer exhibited a 2- electron electrochemistry and a surface coverage of 99%. Results of Hall effect measurements showed that the star copolymer is a semiconducting material, having a conductivity of 0.7 S cm-1, in comparison to the 1.5 S cm-1 of PPy. To the best of my knowledge, these new star copolymers have not been reported in the open literature. Their properties make them potentially applicable for use in biosensors. / South Africa

Conducting dendrimeric star copolymer

Polypyrrole

Poly(propylene imine)

Dendrimer

Poly(propylene imine)-co-polypyrrole

Hall effect measurements

Conductivity

Electrical conductivity

Electrochemical impedance spectroscopy

Cyclic voltammetry

Platinum electrode

Electrochemical impedance modelling of the reactivities of dendrimeric poly(propylene imine) DNA nanobiosensors.

Arotiba, Omotayo Ademola.

January 2008

<p>In this thesis, I present the electrochemical studies of three dendrimeric polypropylene imine (PPI) nanomaterials and their applications as a platform in the development of a novel label free DNA nanobiosensor based on electrochemical impedance spectroscopy. Cyclic voltammetry (CV), differentia pulse voltammetry (DPV), square wave voltammetry (SWV) and electrochemical impedance spectroscopy (EIS) techniques were used to study and model the electrochemical reactivities of the nanomaterials on glassy carbon electrode (GCE) as the working electrode.</p>

Electrochemical DNA biosensor

Poly(propylene imine)

Dendrimer

Metallodendrimer

Gold nanoparticle

Glassy Carbon Electrode

Biosensor

Nanobiosensor.

Advanced Methods, Materials, and Devices for Microfluidics

White, Celesta E.

26 November 2003

Advanced Methods, Materials, and Devices for Microfluidics Celesta E. White 217 Pages Directed by Dr. Clifford L. Henderson Microfluidics is a rapidly growing research area that has the potential to influence a variety of industries from clinical diagnostics to drug discovery. Unlike the microelectronics industry, where the current emphasis is on reducing the size of transistors, the field of microfluidics is focusing on making more complex systems of channels with more sophisticated fluid-handling capabilities, rather than reducing the size of the channels. While lab-on-a-chip devices have shown commercial success in a variety of biological applications such as electrophoretic separations and DNA sequencing, there has not been a significant amount of progress made in other potential impact areas for microfluidics such as clinical diagnostics, portable sensors, and microchemical reactors. These applications can benefit greatly from miniaturization, but advancement in these and many other areas has been limited by the inability or extreme difficulty in fabricating devices with complex fluidic networks interfaced with a variety of active and passive electrical and mechanical components. Several techniques exist for the fabrication of microfluidic devices, but these methods have significant limitations, and alternative fabrication approaches are currently desperately needed. One such method that shows promise for its ability to integrate the desired high levels of functionality utilizes thermally sacrificial materials as place holders. An encapsulating overcoat material provides structural stability and becomes the microchannel walls when the sacrificial material is removed from the channel through thermal decomposition. Disadvantages of this method, however, include numerous processing steps required for sacrificial layer patterning and elevated temperatures needed for the decomposition of initial sacrificial materials. These limitations keep this method from becoming an economical alternative for microfluidic device fabrication. The materials needed for this method to reach its full potential as a valid fabrication technology for m-TAS are not currently available, and it was a major focus of this work to develop and characterize new sacrificial materials, particularly photosensitive polycarbonate systems. In addition to the development of new sacrificial polymers, the framework for a working microfluidic device was developed to show that this concept will indeed provide significant advancements in the development of future generations of microfluidic systems. Finally, novel fabrication methods for microfluidics through combined imprinting and photopatterning of photosensitive sacrificial materials was demonstrated.

Polycarbonates

Sacrificial materials

Microfluidics

Poly(propylene carbonate)

Photosensitive polycarbonates

Microelectromechanical systems

Polycarbonates

Microelectromechanical systems

Photosensitive polyimides

Nematinių skystakristalinių dendrimerų su įterptomis Co nanodalelėmis struktūrinių ir optinių savybių tyrimai / Structural and optical properties of nematic liquid crystalline PPI dendrimers encapsulated with Co nanoparticles

Franckevičius, Marius

16 August 2007

Darbe tirtos struktūrinės ir spektroskopinės dviejų šeimų nematinių skystakristalinių dendrimerų ištirpintų chloroforme savybės. Taip pat struktūrinės, spektroskopinės ir magnetooptinės dendrimerų su įterptomis Co nanodalelėmis savybės. Dviejų šeimų skystakristalinių dendrimerų ištirpintų chloroforme optiniai tyrimai parodė, kad pirmos šeimos skystakristalinių dendrimerų vidinę dalį nusakanti sugerties juosta antros ir penktos generacijų atžvilgiu yra paslinkusi per 8nm, tuo tarpu antros šeimos atitinkamai pirmos ir penktos generacijų atžvilgiu per 19nm. Dendrimerų su įterptomis Co nanodalelėmis magnetooptiniai tyrimai parodė, kad Co nanodalelės gali būti valdomos magnetiniais laukais. / Dendritic structure is one of the prevalent topologies on our planet [1]. Dendrimers is generally described as monodispersed low viscosity macromolecules with highly branched, well defined 3D structure, first reported in 1978 by Vögtle. They are always composed of a core molecule and dendritic branches extended from core to terminal groups [26]. The number of functional groups on the dendrimer surface increases exponentially as a function of generation, of that in the higher generations they become much more spherical and amplified highly ordered architectures. Liquid crystalline dendrimers of their unique structural and physical properties have attached considerable attention. Because of their hyper branched spherical structure, interior inside dendrimers have fixed cavities. Strong interaction forces in the terminal mesogenic units determine that in the interior can be incorporated atoms, ions, guest molecules or nanoparticles. They are particularly well suited materials for hosting nanoparticles of the following reasons: nanoparticles are stabilized and don’t agglomerate, dendrimer branches can be use as selective gates to control access of small molecules [19]. As result of their architecture, dendrimers can possess essential physical, chemical and biological properties and whole range of applications in energy, medicine, engineering, information technology and ect. We present optical and structural studies of liquid crystalline poly(propylene imine) (PPI) dendrimers... [to full text]

Physics

Dendrimeras

Poli (propilenas iminas)

Nanodalelė

Skystakristalinis

Dendrimers

Poly (propylene imine)

Nanoparticles

Liquidcrystalline

Electrochemical impedance modelling of the reactivities of dendrimeric poly(propylene imine) DNA nanobiosensors.

Arotiba, Omotayo Ademola.

January 2008

<p>In this thesis, I present the electrochemical studies of three dendrimeric polypropylene imine (PPI) nanomaterials and their applications as a platform in the development of a novel label free DNA nanobiosensor based on electrochemical impedance spectroscopy. Cyclic voltammetry (CV), differentia pulse voltammetry (DPV), square wave voltammetry (SWV) and electrochemical impedance spectroscopy (EIS) techniques were used to study and model the electrochemical reactivities of the nanomaterials on glassy carbon electrode (GCE) as the working electrode.</p>

Electrochemical DNA biosensor

Poly(propylene imine)

Dendrimer

Metallodendrimer

Gold nanoparticle

Glassy Carbon Electrode

Biosensor

Nanobiosensor.