Enhanced Thermoelectric Properties of Poly(3-hexylthiophene) through the Incorporation of Aligned Carbon Nanotube Forest and Chemical Treatments

Mardi, Saeed; Yusupov, Khabib; Martínez, Patricia; Zakhidov, Anvar A.; Vomiero, Alberto; Reale, Andrea

doi:10.1021/acsomega.0c02663

Cited by 9 publications

(5 citation statements)

References 56 publications

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“…Figure S2a,b illustrates that the 40 nm spin-coated P3HT films were less resistant and were able to produce some S values in response to only higher doping levels (5–20 ppm of NO 2 ), but the S trend does not display a clear consistent decrease. In addition, at low doping levels, the S values of spin-coated P3HT could not be easily measured either due to low σ. Mardi et al reported the issue of not being able to measure TE properties of highly resistant pristine P3HT and P3HT doped with low dopant content . We propose that the NO 2 absorption is more efficient on a spin-coated film compared to a drop-cast film due to variation in thickness and morphology that lead to difference in the conditions of doping kinetics.…”

Section: Resultsmentioning

confidence: 89%

NO₂ Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

Chen

Wagner

Katz

2022

ACS Appl. Electron. Mater.

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Alkylthiophene polymers with unique and differing terminally functionalized side chains were investigated by using a vapor analyte/dopant, nitrogen dioxide (NO2), and the thermoelectric properties were examined. We observed that through NO2 absorption on or in the sample that induced charge carrier generation and transport, the conductivities of regioregular poly(3-hexylthiophene-2,5-diyl) (P3HT), poly[3-(ethyl-4-butoanote)thiophene-2,5-diyl] (PT-COOR), poly[3-(3-caboxypropyl)thiophene-2,5-diyl] (PT-COOH), and poly(3-hydroxymethylthiophene) (PT-OH) were increased. Meanwhile, Seebeck coefficients (S) of PT-COOH, PT-COOR, and PT-OH displayed a declining trend with increasing NO2 ppm-level exposure. The lack of S dependence on doping level for P3HT is due to its low conductivity (σ). The correlations of thermoelectric properties of the four polymers were investigated; PT-COOR, PT-COOH, and PT-OH showed good linearity in the logarithmic plots of S and power factor against σ at various doping levels, even with possible contributions of proton transport in PT-COOH and PT-OH. In light of growing interest in conducting polymers being utilized as gas sensors, this method provides as a convenient tool to study the physics associated behind the thermoelectric properties governing the sensing response and mechanism.

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Section: Resultsmentioning

confidence: 89%

NO₂ Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

Chen

Wagner

Katz

2022

ACS Appl. Electron. Mater.

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“…The fillers are usually carbon-based materials or inorganic-based materials. The most common fillers are carbon nanotubes [191] (see figure 16), graphene sheets [185,186], Bi 2 Te 3 nanowires [192], SnSe [193], and tellurium nanowires [194].…”

Section: Solution Processable Organic Thermoelectric Materials and De...mentioning

confidence: 99%

Roadmap on thermoelectricity

Artini

Pennelli

Graziosi³

et al. 2023

Nanotechnology

Self Cite

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The increasing energy demand and the ever more pressing need for clean technologies of energy conversion pose one of the most urgent and complicated issues of our age. Thermoelectricity, namely the direct conversion of waste heat into electricity, is a promising technique based on a long-standing physical phenomenon, which still has not fully developed its potential, mainly due to the low efficiency of the process. In order to improve the thermoelectric performance, a huge effort is being made by physicists, materials scientists and engineers, with the primary aims of better understanding the fundamental issues ruling the improvement of the thermoelectric figure of merit, and finally building the most efficient thermoelectric devices.In this Roadmap an overview is given about the most recent experimental and computational results obtainedwithin the Italian research community on the optimization of composition and morphology of some thermoelectric materials, as well as on the design of thermoelectric and hybrid thermoelectric/photovoltaic devices.

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“…Very recently, Mardi et al 91 prepared nanocomposite films consisting of carbon nanotube forest (CNTF) and poly(3‐hexylithiophene) (P3HT). CNTF acted as a filler and improved the electrical conductivity of P3HT by forming a well‐interconnected network.…”

Section: Carbon‐based Thermoelectrics (Tes)mentioning

confidence: 99%

Advances in carbon‐based thermoelectric materials for high‐performance, flexible thermoelectric devices

Yun

Choi

2021

Carbon Energy

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Waste energy harvesting can contribute to the increase of the efficiency of many industrial processes, which consume energy to produce valuable products. Among all the wasted energy, heat energy is the most abundant, existing in almost any situation. Thermoelectric devices have the capability to harvest and convert the thermal energy into electrical power via the Seebeck effect. With its simple operating principle, thermoelectric devices can be reliable even under the harshest environments, taking advantage of any type of heat source. As a result, various inorganic and organic materials are being explored as thermoelectric materials. Among the reported materials, carbon‐based materials are promising in terms of commericialization, due to their nontoxic and abundant nature, and solution processability. In particular, poly(3,4‐ethylenedioxythiophene):polystyrene sulfonate (PEDOT:PSS), carbon nanotubes, and graphene are extensively studied as thermoelectric materials owing to their remarkable thermoelectric performance. Also, organic–inorganic hybrid halide perovskites show the potential to be used as future high‐performance thermoelectric materials. Here, the progess in carbon materials as thermoelectrics is reviewed in detail, focusing on four base materials (PEDOT:PSS, carbon nanotubes, graphene, and organic–inorganic hybrid halide perovskites). This review illuminates the potential of carbon‐based materials in the field of thermoelectrics and their application to next‐generation energy devices.

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Enhanced Thermoelectric Properties of Poly(3-hexylthiophene) through the Incorporation of Aligned Carbon Nanotube Forest and Chemical Treatments

Cited by 9 publications

References 56 publications

NO₂ Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

NO₂ Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

Roadmap on thermoelectricity

Advances in carbon‐based thermoelectric materials for high‐performance, flexible thermoelectric devices

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Enhanced Thermoelectric Properties of Poly(3-hexylthiophene) through the Incorporation of Aligned Carbon Nanotube Forest and Chemical Treatments

Cited by 9 publications

References 56 publications

NO2 Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

NO2 Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

Roadmap on thermoelectricity

Advances in carbon‐based thermoelectric materials for high‐performance, flexible thermoelectric devices

Contact Info

Product

Resources

About

NO₂ Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers

NO₂ Exposure Effect on Mixed Conductivity and Seebeck Coefficient in Thiophene Polymers