Inorganic‐Based Nanocomposites of Conductive Polymers

Bissessur, Rabin

doi:10.1002/9780470661338.ch6

Cited by 5 publications

(4 citation statements)

References 91 publications

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“…The values of the HOMO and LUMO energy levels determine properties such as oxidative stability, optical absorption wavelengths, and whether a polymer is more likely to be n-type or p-type. 26,42 Polymers can be classified as being either n-type or p-type based on whether they are easily reduced or oxidized, respectively. Electron rich structures that have higher HOMO levels make good p-type materials due to their ability to stabilize a positive charge, while electron poor structures are able to stabilize negative charges in low-lying LUMO levels, making them good n-type materials.…”

Section: Operating Principlesmentioning

confidence: 99%

“…18,22,29 In light of this, conjugated polymers are ideal materials for hybrid composites in that they work synergistically with inorganic compounds that have high capacity but lack the conductivity and cyclability necessary for commercial application. [23][24][25][26] The combination of synthetic tuning, processing options, and mechanical flexibility results in plastic power sources that can be designed to suit the device rather than vice versa.…”

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confidence: 99%

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Recent advances in conjugated polymer energy storage

Mike

Lutkenhaus

2013

J Polym Sci B Polym Phys

185

152

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This review covers recent advances in conjugated polymers and their application in energy storage. Conjugated polymers are promising cost-effective, lightweight, and flexible electrode materials. The operating principles of conjugated polymers are presented within the framework of their potential for energy storage. Special focus is given to polyaniline electrodes. Recent advances are reviewed including new methods of synthesis, nanostructuring, and assembly. Also, covered are applications that take full advantage of the mechanical properties of conjugated polymers and future applications of these novel materials.

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Section: Operating Principlesmentioning

confidence: 99%

mentioning

confidence: 99%

Recent advances in conjugated polymer energy storage

Mike

Lutkenhaus

2013

J Polym Sci B Polym Phys

185

152

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“…CPs have been utilized in lightweight, flexible devices as part of watches, fabrics, or thin-film displays, for example. , CPs are low cost, processable, and easy to modify. − For example, the physical, chemical, and electrochemical properties of a CP can be modified to suit a particular application via side-chain chemistry. − They can also be potentially derived from domestic feedstock. Relevant to Li-ion batteries, CPs have also been used in conjunction with high-capacity inorganic components such as V 2 O 5 , − LiFePO 4 , sulfur, , or silicon with the goal of producing a hybrid composite that yields a performance exceeding that of either material alone …”

Section: Introductionmentioning

confidence: 99%

Charge Storage in Decyl- and 3,6,9-Trioxadecyl-Substituted Poly(dithieno[3,2-b:2,3-d]pyrrole) Electrodes

et al. 2013

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Poly(dithieno[3,2-b:2,3-d]pyrrole)s, or poly(DTP)s, are potentially promising electrode materials for electrochemical energy storage (EES) because of their ability to reversibly store charge and achieve relatively high doping levels. Here, we explore charge storage in two different side-chain-substituted poly(DTP)s. Substitution at the nitrogen with alkyl and alkyl ether chains is used to demonstrate the ability to tune electrochemical response through favorable interactions with the electrolyte. PolyDTP electrodes are electropolymerized and analyzed using various electrochemical techniques, spectroscopic measurements including UV–vis and Raman, and electron microscopy. Specific capacities for the poly(DTP)s range between approximately 35 and 70 mAh/g for discharge rates of 1–75 C, corresponding to considerably high doping levels of 0.5–0.9 electrons per repeat unit. After 1000 cycles, the alkyl-substituted polymer retains 75% of its initial capacity while the alkyl ether-substituted polymer only retains 50%. The specific capacitance was as high as 121 F/g. These results suggest that poly(DTP)s could be utilized on their own or in composite electrodes for energy storage.

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“…Cobalt, for example, is used in LiCoO 2 battery cathodes and is not produced domestically in the U.S . Polymers enable electrodes for flexible energy storage, can be functionalized synthetically with ease, − and, if conjugated, lend conductivity to otherwise insulating composites. − …”

mentioning

confidence: 99%

Electrochemically Active Polymers for Electrochemical Energy Storage: Opportunities and Challenges

Mike

Lutkenhaus

2013

ACS Macro Lett.

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Polymers have a particularly important place in electrochemical energy storage (EES), not just as the electrolyte, as has been a large focus for solidstate batteries, but also as the electrode. This Viewpoint will introduce how electrochemically active polymers (EAPs) are utilized in electrochemical energy storage with an emphasis on battery cathodes. Recent advances in high capacity EAPs and selected challenges (high voltage stability and ion transport) are presented. Should these needs be met, the resulting electrode would bear a high capacity, energy, power, and cycle life. The low cost, potential application in flexible EES, and synthetic versatility of EAPs offer many unique aspects relative to conventional metal oxides. In composites with metal oxides, EAPs can be used as a means to boost ionic and electronic conductivity. Promising examples regarding high capacity polymeric sulfur electrodes, electrochemically stable polyaniline/ polyacid complexes, porous polyaniline/V 2 O 5 electrodes, and hydrogel-based electrodes are highlighted.

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Inorganic‐Based Nanocomposites of Conductive Polymers

Cited by 5 publications

References 91 publications

Recent advances in conjugated polymer energy storage

Recent advances in conjugated polymer energy storage

Charge Storage in Decyl- and 3,6,9-Trioxadecyl-Substituted Poly(dithieno[3,2-b:2,3-d]pyrrole) Electrodes

Electrochemically Active Polymers for Electrochemical Energy Storage: Opportunities and Challenges

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