Highly anisotropic P3HT films with enhanced thermoelectric performance via organic small molecule epitaxy

Abstract: Conducting polymers are potential candidates for thermoelectric (TE) applications owing to their low thermal conductivity, non-toxicity and low cost. However, the coil conformation and random aggregation of polymer chains usually degrade electrical transport properties, thus deteriorating TE performance. In this work, we fabricated poly(3-hexylthiophene) (P3HT) films with highly oriented morphology using 1,3,5-trichlorobenzene (TCB), an organic small-molecule, as a template for polymer epitaxy under a temperat… Show more

“…A decreased d can result in lower transport resistivity and boost σ. Stretched microstructures can also be achieved by mechanical stretching or organic small‐molecule epitaxy . Although their obtained electrical properties are still inferior to those treated by secondary doping engineering, these strategies still hold promise and should inspire future studies.…”

“…Organic small‐molecule epitaxy is also an effective strategy to enhance the structural ordering in microstructures. This process is different from the aforementioned secondary doping or mechanical stretching, because interfacial ordering effect is utilized, in which small molecules are introduced as epitaxial templates for polymer‐chain attachments . By orientating these small molecules, polymer chains are expected to be well‐oriented, resulting in an improved µ and, in turn, an improved σ .…”

“…This process is different from the aforementioned secondary doping or mechanical stretching, because interfacial ordering effect is utilized, in which small molecules are introduced as epitaxial templates for polymer‐chain attachments . By orientating these small molecules, polymer chains are expected to be well‐oriented, resulting in an improved µ and, in turn, an improved σ . Figure a shows an example of P3HT chains grown on 1,3,5‐trichlorobenzene (TCB) small‐molecular templates .…”

“…By orientating these small molecules, polymer chains are expected to be well‐oriented, resulting in an improved µ and, in turn, an improved σ . Figure a shows an example of P3HT chains grown on 1,3,5‐trichlorobenzene (TCB) small‐molecular templates . TCB powders are deposited onto the P3HT film and then melted at 348 K. By moving the glass substrate unidirectionally toward the cooling plate, a unidirectional temperature gradient is applied and the TCB is cooled down to form TCB molecular crystals.…”

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“…A decreased d can result in lower transport resistivity and boost σ. Stretched microstructures can also be achieved by mechanical stretching or organic small‐molecule epitaxy . Although their obtained electrical properties are still inferior to those treated by secondary doping engineering, these strategies still hold promise and should inspire future studies.…”

“…Organic small‐molecule epitaxy is also an effective strategy to enhance the structural ordering in microstructures. This process is different from the aforementioned secondary doping or mechanical stretching, because interfacial ordering effect is utilized, in which small molecules are introduced as epitaxial templates for polymer‐chain attachments . By orientating these small molecules, polymer chains are expected to be well‐oriented, resulting in an improved µ and, in turn, an improved σ .…”

“…This process is different from the aforementioned secondary doping or mechanical stretching, because interfacial ordering effect is utilized, in which small molecules are introduced as epitaxial templates for polymer‐chain attachments . By orientating these small molecules, polymer chains are expected to be well‐oriented, resulting in an improved µ and, in turn, an improved σ . Figure a shows an example of P3HT chains grown on 1,3,5‐trichlorobenzene (TCB) small‐molecular templates .…”

“…By orientating these small molecules, polymer chains are expected to be well‐oriented, resulting in an improved µ and, in turn, an improved σ . Figure a shows an example of P3HT chains grown on 1,3,5‐trichlorobenzene (TCB) small‐molecular templates . TCB powders are deposited onto the P3HT film and then melted at 348 K. By moving the glass substrate unidirectionally toward the cooling plate, a unidirectional temperature gradient is applied and the TCB is cooled down to form TCB molecular crystals.…”

Flexible Thermoelectric Materials and Generators: Challenges and Innovations

“…The thermoelectric conversion efficiency of TE device dominates by the dimensionless figure of merit zT = σS 2 T / κ , where σ is the electrical conductivity, S is the Seebeck coefficient, κ is the thermal conductivity, T is the absolute temperature, and S 2 σ is the power factor, respectively. In past decades, conventional inorganic bulk‐based TE generators (TEGs) consisting of inorganic TE alloys, such as Bi 2 Te 3 , PbTe, and CoSb 3 , and thin film‐based TEGs made of inorganic TE materials, conducting polymers and derivatives, including poly(3,4‐ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), polyaniline (PANI), polypyrrole (PPy), and poly(3‐hexylthiophene) (P3HT), have been intensively investigated . However, their applications in Internet of Things and wearable electronics are still vague, because inorganic bulk‐based TEGs are rigid with inferior flexibility, while thin film‐based TEGs can only be bent in one direction.…”

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