3D cellulose fiber networks modified by PEDOT:PSS/graphene nanoplatelets for thermoelectric applications

Mardi, Saeed; Cataldi, Pietro; Athanassiou, Athanassia; Reale, Andrea

doi:10.1063/5.0075918

Cited by 13 publications

(12 citation statements)

References 30 publications

(44 reference statements)

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“…According to literature, the particles and elongated features represent the conducting parts and insulating domains of PEDOT:PSS, respectively. [ 18–20 ]…”

Section: Resultsmentioning

confidence: 99%

“…According to literature, the particles and elongated features represent the conducting parts and insulating domains of PEDOT:PSS, respectively. [18][19][20] Simple vertical supercapacitor structures are composed of the ion gel between two electrodes of either PEDOT:PSS or AuNWs (Figure 2a). The ability of those electrodes to store charges is investigated by the cyclic voltammetry (CV) and galvanic charge-discharge (GCD) techniques (Figure S2, Supporting Information).…”

Section: Supercapacitor Electrodes and Electrolytesmentioning

confidence: 99%

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Interfacial Effect Boosts the Performance of All‐Polymer Ionic Thermoelectric Supercapacitors

Mardi

Zhao

Tybrandt

et al. 2022

Adv Materials Inter

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Ionic thermoelectric supercapacitors (ITESCs) have recently been developed for converting low‐grade waste heat into electricity. Until now, most reports of ITESCs have been focused on the development of electrolytes, which then have been combined with a specific electrode material. Here, it is demonstrated that the electrode is not only critical for electrical energy storage but also greatly affects the effective thermopower (Seff) of an ITESC. It is shown that the same ion gel can generate a positive thermopower in an ITESC when using gold nanowire (AuNW) electrodes, while generating a negative thermopower when using poly(3,4‐ethylendioxythiophene):polystyrene sulfonate (PEDOT:PSS) electrodes. The achieved negative sign of the Seff could be attributed to the Donnan exclusive effect from the polyanions in the PEDOT:PSS electrodes. After examining the thermovoltage, capacitance and charge retention performance of the two ITESCs, it is concluded that PEDOT:PSS is superior to AuNWs as electrodes. Moreover, a new strategy of constructing an ionic thermopile of multiple p‐ and n‐type legs is achieved by series‐connecting these legs with same electrolyte but different electrodes. Using interfacial effect at ionic gels/PEDOT:PSS electrode interface, an enhanced thermoelectric effect in ITESCs is obtained, which constitutes one more step towards efficient, low‐cost, flexible, and printable ionic thermoelectric modules for energy harvesting.

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“…According to literature, the particles and elongated features represent the conducting parts and insulating domains of PEDOT:PSS, respectively. [ 18–20 ]…”

Section: Resultsmentioning

confidence: 99%

Section: Supercapacitor Electrodes and Electrolytesmentioning

confidence: 99%

Interfacial Effect Boosts the Performance of All‐Polymer Ionic Thermoelectric Supercapacitors

Mardi

Zhao

Tybrandt

et al. 2022

Adv Materials Inter

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“…147 Cotton and cellulose have been used as a host for active materials with mixed results. [147][148][149] Cataldi et al have shown that similar fiber-based TEGs can be realized by spray-coating cotton fibers with a mixture of doped nanocarbon species (active material) and aleuritic acid (binder) to produce a biodegradable composite for thermoelectric applications. 147 The proof-of-concept TEG made entirely from the organic textile-based thermocouples yielded a maximum power output of %1.0 nW at DT ¼ 70 K. 147 Spraycoated or solution-soaked thermoelectric fibers also have the benefit of being extremely scalable.…”

Section: Thermoelectric Fibersmentioning

confidence: 99%

Solution processed organic thermoelectric generators as energy harvesters for the Internet of Things

Pataki

Rossi

Caironi

2022

Applied Physics Letters

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Organic thermoelectric generators (TEGs) are a prospective class of versatile energy-harvesters that can enable the capture of low-grade heat and provide power to the growing number of microelectronic devices and sensors in the Internet of Things. The abundance, low-toxicity, and tunability of organic conducting materials along with the scalability of the fabrication techniques promise to culminate in a safe, low-cost, and adaptable device template for a wide range of applications. Despite recent breakthroughs, it is generally recognized that significant advances in n-type organic thermoelectric materials must be made before organic TEGs can make a real impact. Yet, in this perspective, we make the argument that to accelerate progress in the field of organic TEGs, future research should focus more effort into the design and fabrication of application-oriented devices, even though materials have considerable room for improvement. We provide an overview of the best solution-processable organic thermoelectric materials, design considerations, and fabrication techniques relevant for application-oriented TEGs, followed by our perspective on the insight that can be gained by pushing forward with device-level research despite suboptimal materials.

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“…PEDOT:PSS conductive fibers have relatively high electrical conductivity, , stability, and charge storage, which is why they are used for many high-tech applications, such as smart textiles, , flexible electrodes, , sensors, , and actuators . PEDOT:PSS can be spun into a conductive fiber or filament or can be produced during wet spinning , or electrospinning of fibers …”

Section: Pedot:pss-based Conductive Fibersmentioning

confidence: 99%

Review on PEDOT:PSS-Based Conductive Fabric

et al. 2022

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This article reviews conductive fabrics made with the conductive polymer poly (3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), their fabrication techniques, and their applications. PEDOT:PSS has attracted interest in smart textile technology due to its relatively high electrical conductivity, water dispersibility, ease of manufacturing, environmental stability, and commercial availability. Several methods apply PEDOT:PSS to textiles. They include polymerization of the monomer, coating, dyeing, and printing methods. In addition, several studies have shown the conductivity of fabrics with the addition of PEDOT:PSS. The electrical properties of conductive textiles with a certain sheet resistance can be reduced by several orders of magnitude using PEDOT:PSS and polar solvents as secondary dopants. In addition, several studies have shown that the flexibility and durability of textiles coated with PEDOT:PSS can be improved by creating a composite with other polymers, such as polyurethane, which has high flexibility and extensibility. This improvement is due to the stronger bonding of PEDOT:PSS to the fabrics. Sensors, actuators, antennas, interconnectors, energy harvesting, and storage devices have been developed with PEDOT:PSS-based conductive fabrics.

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3D cellulose fiber networks modified by PEDOT:PSS/graphene nanoplatelets for thermoelectric applications

Cited by 13 publications

References 30 publications

Interfacial Effect Boosts the Performance of All‐Polymer Ionic Thermoelectric Supercapacitors

Interfacial Effect Boosts the Performance of All‐Polymer Ionic Thermoelectric Supercapacitors

Solution processed organic thermoelectric generators as energy harvesters for the Internet of Things

Review on PEDOT:PSS-Based Conductive Fabric

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