Theory of block copolymers. I. Domain formation in A-B block copolymers

Meier, D. J.

doi:10.1002/polb.1996.926

Cited by 3 publications

(2 citation statements)

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“…Microphase separation has now been researched for quite some time 39, 182. Initiated by the theoretical studies of Meier in 1969,183 most work has been into the related non‐conjugated coil–coil diblock copolymers, and these systems are now generally well understood. In the 1990s, Matsen and Bates184 proposed a theoretical phase diagram, according to the volume fraction ( f ) of each component and the product (χ N ) due to the characteristics of the block.…”

Section: Conjugated Rod–coil Block Copolymersmentioning

confidence: 99%

Conjugated rod–coil block copolymers and optoelectronic applications

Cuendias¹,

Hiorns²,

Cloutet³

et al. 2010

Polymer International

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This review gives a simple introduction to the electronic, optical and structural behaviour of rod-coil block copolymers in which the rod block is conjugated. The current understanding of the optical properties of conjugated polymers is discussed, as is the self-assembly characteristics of rod-coil block copolymers, along with their behaviour with respect to organic light-emitting diode and photovoltaic devices. Poly(p-phenylene), poly(p-phenylenevinylene) and polythiophenes are then used to give concrete examples and a short history of the developments of this astounding field.can have a strong influence on the type of morphology obtained. The asymmetric nature of the highly rigid conjugated block and the coil block tends to increase the Flory-Huggins parameter (χ ) leading to domain formation even with relatively short polymers and oligomers. 42 Indeed, a wide variation of morphologies has been demonstrated through the preparation of mushroomlike aggregates, 43 honeycomb structures, 44 -47 vesicles 48,49 and cylindrical and lamellar aggregates. 50 -52 And it has been shown that, due to charge confinement within domains, the self-assembly process can be altered by using parameters such as light and temperature. 53 -55 It is apparent that rod-coil copolymers containing conjugated segments can lead to well-defined objects at the nanometric scale and that this in turn leads to the materials having an extraordinary range of applications.This review aims to give an overview of the main applications of π -conjugated systems, highlighting the importance of controlling the ineluctable aggregation phenomena and concentrating on the qualities of rod-coil block copolymers. An initial review of the basic electronic and optoelectronic properties of conjugated polymers along with a brief synopsis of their use and operation in more notable applications is given as this helps to explain the characteristics found and sought for with conjugated rod-coil copolymers. ARCHETYPAL CONJUGATED POLYMERSThe discovery in 1977 that polyacetylene exhibits a conductivity of about 10 3 S cm −1 on doping with Br 2 , I 2 or AsF 5 initiated a true interest in this material. 2 However, polyacetylene exhibits low environmental and thermal stabilities and poor solubilities that limit its technical use. Following these observations, many aromatic conjugated polymers such as poly(p-phenylene) (PPP), 56 polythiophene (PT), 57 polypyrrole 58 and others shown in Fig. 1 were studied. Currently, many other analogues are regularly prepared. Poly(3,4-ethylenedioxythiophene) (PEDOT), marketed by the Bayer company since the 1980s, is one of the most widely exploited. 59 -63 This polymer shows reasonable conductivity (ca 1 S cm −1 ), quasi-transparency in films and high stability in the oxidized state. 62 -64 An important development was the discovery of the green electroluminescence of undoped poly(p-phenylenevinylene) (PPV) by Friend and colleagues in 1990. 65 This breakthrough was followed by the ground-breaking preparation of the first blue PLED based ...

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Section: Conjugated Rod–coil Block Copolymersmentioning

confidence: 99%

Conjugated rod–coil block copolymers and optoelectronic applications

Cuendias¹,

Hiorns²,

Cloutet³

et al. 2010

Polymer International

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“…It was revealed in the classical work of Holden et al (1969) that in ABA copolymers a three-dimensional structure of effective cross-links can exist without vulcanization, even when all phases are above their glass transition temperatures (T,) and are therefore in the liquid state Meier (1969) developed a thermodynamic model defining conditions for phase separation in terms of an interfacial surface tension and a critical molecular weight (MW). gives these materials a unique (nonlinear) rheological character.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Viscoelasticity of ABA Block Copolymer Melts: Stress Relaxation and Recovery

Spaans¹,

Williams²

1995

Ind. Eng. Chem. Res.

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The nonlinear rheological character of microphase-separated ABA-type block copolymer melts was investigated in the context of stress relaxation experiments. Five grades of triblock copolymers were studied in step strain programs. End blocks were polystyrene and middle blocks either polybutadiene or polyisoprene. Molecular weights ranged from 61 300 to 140 000 and styrene fractions from 0.14 to 0.44. Test temperatures (90-110 "C) were above Tg of the styrenic microphases and below the separation temperatures of these polymers, so all were multiphase systems with each phase in the liquid state. Strain amplitudes (yo) ranged from 0.05% to 3.86%. At the highest yo, relaxation moduli dropped steadily in liquidlike fashion; at lowest yo, the stress relaxation was overtaken by a competing microstructural recovery process which caused the modulus to pass through a minimum and then increase. Results are discussed in terms of the interfacial diffuse phase (interphase), morphology, and molecular weight. IE950035L@ Abstract published in Advance ACS Abstracts, September 1, 1995.

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Les polymères organisés

Sadron¹

1962

Pure and Applied Chemistry

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Theory of block copolymers. I. Domain formation in A-B block copolymers

Cited by 3 publications

References 11 publications

Conjugated rod–coil block copolymers and optoelectronic applications

Conjugated rod–coil block copolymers and optoelectronic applications

Nonlinear Viscoelasticity of ABA Block Copolymer Melts: Stress Relaxation and Recovery

Les polymères organisés

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