<p>To realize a wearable power generator, organic thermoelectric materials are desired to exhibit a dimensionless figure-of-merit [<i>zT</i> = <i>α</i><sup>2</sup><i>σT</i>/(<i>κ</i><sub><i>e</i></sub> <i>+ κ</i><sub><i>l</i></sub>)] of more than unity, where <i>T</i>,<i> α</i>, and <i>σ</i> denote the temperature, thermopower, and electrical conductivity, whereas <i>κ</i><sub><i>e</i></sub> and <i>κ</i><sub><i>l</i></sub> are the thermal conductivities mediated by carriers and phonons, respectively. Although conventional materials exhibit a maximum power factor (<i>PF</i><sub>max</sub> = <i>α</i><sup>2</sup><i>σ</i>) in the high-<i>σ</i> region of more than 10 Scm<sup>− 1</sup>, <i>zT</i> is not necessarily maximized at the <i>σ</i> giving <i>PF</i><sub>max</sub> because of a marked increase in <i>κ</i><sub><i>e</i></sub> in the high-<i>σ</i> region, which has been a barrier for boosting the <i>zT</i> of organic materials up to a practical level. Here, we report that an exceedingly large <i>PF</i><sub>max</sub> of 1.1 × 10<sup>− 3</sup> Wm<sup>−1</sup>K<sup>− 2</sup> was realized for the composite film consisting of fullerene molecules and molybdenum trioxide nanoclusters by keeping the giant Seebeck effect at a low <i>σ</i> of less than 10<sup>− 2</sup> Scm<sup>− 1</sup>. Since <i>κ</i><sub><i>e</i></sub> is negligibly small in the low-<i>σ</i> region, <i>zT</i> of 0.81 is expected to be achieved at room temperature, which is the highest value among organic materials to the best of our knowledge.</p>

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Novel strategy for boosting thermoelectric performance of organic materials with low electrical conductivity

  • Masato Nakaya,
  • Shun Yamamoto,
  • Satoshi Ogawa,
  • Toshiaki Nishii,
  • Jun Onoe

摘要

To realize a wearable power generator, organic thermoelectric materials are desired to exhibit a dimensionless figure-of-merit [zT = α2σT/(κe+ κl)] of more than unity, where T, α, and σ denote the temperature, thermopower, and electrical conductivity, whereas κe and κl are the thermal conductivities mediated by carriers and phonons, respectively. Although conventional materials exhibit a maximum power factor (PFmax = α2σ) in the high-σ region of more than 10 Scm− 1, zT is not necessarily maximized at the σ giving PFmax because of a marked increase in κe in the high-σ region, which has been a barrier for boosting the zT of organic materials up to a practical level. Here, we report that an exceedingly large PFmax of 1.1 × 10− 3 Wm−1K− 2 was realized for the composite film consisting of fullerene molecules and molybdenum trioxide nanoclusters by keeping the giant Seebeck effect at a low σ of less than 10− 2 Scm− 1. Since κe is negligibly small in the low-σ region, zT of 0.81 is expected to be achieved at room temperature, which is the highest value among organic materials to the best of our knowledge.