Dual-Functional Electrochemically Synthesized Copolymers via Incorporating Bithiophene Units into 3,4-Ethylenedioxythiophene for Superior Thermoelectric and Charge Storage Performances

Dual-Functional Electrochemically Synthesized Copolymers via Incorporating Bithiophene Units into 3,4-Ethylenedioxythiophene for Superior Thermoelectric and Charge Storage Performances

Free-standing or flexible substrate-supported poly(3,4-ethylenedioxythiophene) (PEDOT) films are much in demand due to their applications in various electronic, electrochromic, and thermoelectric devices. Prevalent methods of producing PEDOT free-standing films are from commercially available PEDOT:...

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Bibliographic Details
Main Author: Vibha Saxena (2853275) (author)
Other Authors: Pritam Sarkar (9132739) (author), A. Singh (806697) (author), A. K. Sahu (1374717) (author)
Published: 2025
Subjects:
Medicine
Biotechnology
Immunology
Space Science
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
thus improves mobility
present research focuses
mass specific capacitance
hinders polymer chains
functional copolymer electrodes
forming coiled structures
charge storage capabilities
thermoelectric power factor
commercially available pedot
deposited copolymer films
2 ′- bithiophene
producing pedot free
incorporating bth units
thermoelectric properties
thermoelectric devices
superior thermoelectric
pedot films
various electronic
supported poly
significant change
prevalent methods
prepared films
powered devices
magnitude enhancement
improved stability
flexible substrate
enable self
demand due
copolymerization results
copolymerization method
capacitive properties
alternative strategy
also increases
5 μw
274 f
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Summary:Free-standing or flexible substrate-supported poly(3,4-ethylenedioxythiophene) (PEDOT) films are much in demand due to their applications in various electronic, electrochromic, and thermoelectric devices. Prevalent methods of producing PEDOT free-standing films are from commercially available PEDOT:PSS, which has to be subjected to several pre- and post-treatments to tune the electrical and electrochemical properties. The present research focuses on developing dual-functional copolymer electrodes through the electrochemical polymerization of 2,2′-bithiophene (BTh) units with EDOT, aiming to enhance both thermoelectric properties and charge storage capabilities. By incorporating BTh units into the EDOT monomer, the copolymerization results in a significant change in morphological, structural, electrochemical, and electrical properties as well as improved stability, without any kind of pre- and post-treatments. This strategy serves dual purposes; it not only hinders polymer chains from forming coiled structures (and thus improves mobility) but also increases its electrochemical properties (and thereby charge storage capabilities). As a result of improved electrical and electrochemical properties, superior thermoelectric and capacitive properties are observed in copolymers compared to homopolymers. As-deposited copolymer films have approximately an order of magnitude enhancement in the mass specific capacitance (274 F/g) and thermoelectric power factor (11.5 μW/mK<sup>2</sup>) as compared to that of PEDOT films. The prepared films were free-standing and could be transferred onto solid substrates. The copolymerization method can be adopted as an alternative strategy to tune the electrical/electrochemical properties of polymers and opens a pathway to enable self-powered devices.

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