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1. Independent determination of Peltier coefficient in thermoelectric devices

   https://doi.org/10.1063/5.0093575  

   Dhawan, Ruchika; Panthi, Hari Prasad; Lazaro, Orlando; Blanco, Andres; Edwards, Hal; Lee, Mark (May 2022, Applied Physics Letters)

   Thermoelectric (TE) generators and coolers are one possible solution to energy autonomy for internet-of-things and biomedical electronics and to locally cool high-performance integrated circuits. The development of TE technology requires not only research into TE materials but also advancing TE device physics, which involves determining properties such as the thermopower ( α) and Peltier ( Π) coefficients at the device rather than material level. Although Π governs TE cooler operation, it is rarely measured because of difficulties isolating Π from larger non-Peltier heat effects such as Joule heating and Fourier thermal conduction. Instead, Π is almost always inferred from α via a theoretical Kelvin relation Π =  αT, where T is the absolute temperature. Here, we demonstrate a method for independently measuring Π on any TE device via the difference in heat flows between the thermopile held open-circuit vs short-circuit. This method determines Π solely from conventionally measured device performance parameters, corrects for non-Peltier heat effects, does not require separate knowledge of material property values, and does not assume the Kelvin relation. A measurement of Π is demonstrated on a commercial Bi 2 Te 3 TE generator. By measuring α and Π independently on the same device, the ratio ( Π/ α) is free of parasitic thermal impedances, allowing the Kelvin relation to be empirically verified to reasonable accuracy. 

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2. Empirical test of the Kelvin relation in thermoelectric nanostructures

   https://doi.org/10.1063/5.0197974  

   Panthi, Hari Prasad; Dhawan, Ruchika; Edwards, Hal; Lee, Mark. (March 2024, Applied physics letters)

   Thermoelectric (TE) nanostructures with dimensions of 100 nm can show substantially better TE properties compared to the same material in the bulk form due to charge and heat transport effects specific to the nanometer scale. However, TE physics in nanostructures is still described using the Kelvin relation (KR) P = aT, where P is the Peltier coefficient, a the thermopower, and T the absolute temperature, even though derivation of the KR uses a local equilibrium assumption (LEA) applicable to macroscopic systems. It is unclear whether nanostructures with nanostructures with dimensions on the order of an inelastic mean free path satisfy a LEA under any nonzero temperature gradient. Here, we present an experimental test of the KR on a TE system consisting of doped silicon-based nanostructures with dimensions comparable to the phonon–phonon and electron–phonon mean-free-paths. Such nanostructures are small enough that true local thermodynamic equilibrium may not exist when a thermal gradient is applied. The KR is tested by measuring the ratio P/a under various applied temperature differences and comparing it to the average T. Results show relative deviations from the KR of |(P/a)/T –1| ≤ 2.2%, within measurement uncertainty. This suggests that a complete local equilibrium among all degrees of freedom may be unnecessary for the KR to be valid but could be replaced by a weaker condition of local equilibrium among only charge carriers. 

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3. Paramagnon drag in high thermoelectric figure of merit Li-doped MnTe

   https://doi.org/10.1126/sciadv.aat9461  

   Zheng, Y.; Lu, T.; Polash, Md M.; Rasoulianboroujeni, M.; Liu, N.; Manley, M. E.; Deng, Y.; Sun, P. J.; Chen, X. L.; Hermann, R. P.; et al (September 2019, Science Advances)

   Local thermal magnetization fluctuations in Li-doped MnTe are found to increase its thermopower α strongly at temperatures up to 900 K. Below the Néel temperature ( T N ~ 307 K), MnTe is antiferromagnetic, and magnon drag contributes α md to the thermopower, which scales as ~ T 3 . Magnon drag persists into the paramagnetic state up to >3 × T N because of long-lived, short-range antiferromagnet-like fluctuations (paramagnons) shown by neutron spectroscopy to exist in the paramagnetic state. The paramagnon lifetime is longer than the charge carrier–magnon interaction time; its spin-spin spatial correlation length is larger than the free-carrier effective Bohr radius and de Broglie wavelength. Thus, to itinerant carriers, paramagnons look like magnons and give a paramagnon-drag thermopower. This contribution results in an optimally doped material having a thermoelectric figure of merit ZT > 1 at T > ~900 K, the first material with a technologically meaningful thermoelectric energy conversion efficiency from a spin-caloritronic effect. 

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4. Modelling the thermoelectric properties of cement-based materials using finite element method and effective medium theory

   Stella, L.; Johnston, C.; Troncoso, J.; Chudzinski, P.; Orisakwe, E.; Kohanoff, J.; Jani, R.; Holmes, N.; Norton, B.; Liu, X.; et al (August 2022, CERI/ITRN 2022)

   Because of the thermoelectric (TE) effect (or Seebeck effect), a difference of potential is generated as a consequence of a temperature gradient across a sample. The TE effect has been mostly studied and engineered in semiconducting materials and it already finds several commercial applications. Only recently the TE effect in cement-based materials has been demonstrated and there is a growing interest in its potential. For instance, a temperature gradient across the external walls of a building can be used to generate electricity. By the inverse of the TE effect (or Peltier effect), one can also seek to control the indoor temperature of a building by biasing TE elements embedded in its external walls. In designing possible applications, the TE properties of cement-based materials must be determined as a function of their chemical composition. For instance, the TE properties of cement paste can be enhanced by the addition of metal oxide (e.g., Fe2O3) powder. In this paper, a single thermoelectric leg is studied using the finite element method. Metal oxide additives in the cement paste are modelled as spherical inhomogeneities. The thermoelectric properties of the single components are based on experimental data, while the overall thermoelectric properties of the composites are obtained from the numerical model. The results of this numerical study are interpreted according to the effective medium theory (EMT) and its generalisation (GEMT). 

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5. Strong π-stacking causes unusually large anisotropic thermal expansion and thermochromism

   https://doi.org/10.1073/pnas.2106572118  

   Dharmarwardana, Madushani; Otten, Brooke M.; Ghimire, Mukunda M.; Arimilli, Bhargav S.; Williams, Christopher M.; Boateng, Stephen; Lu, Zhou; McCandless, Gregory T.; Gassensmith, Jeremiah J.; Omary, Mohammad A. (October 2021, Proceedings of the National Academy of Sciences)

   π-stacking in ground-state dimers/trimers/tetramers ofN-butoxyphenyl(naphthalene)diimide (BNDI) exceeds 50 kcal ⋅ mol⁻¹in strength, drastically surpassing that for the^*3[pyrene]₂excimer (∼30 kcal ⋅ mol⁻¹; formal bond order = 1) and similar to other weak-to-moderate classical covalent bonds. Cooperative π-stacking in triclinic (BNDI-T) and monoclinic (BNDI-M) polymorphs effects unusually large linear thermal expansion coefficients (α_a, α_b, α_c, β) of (452, −16.8, −154, 273) × 10⁻⁶⋅ K⁻¹and (70.1, −44.7, 163, 177) × 10⁻⁶⋅ K⁻¹, respectively. BNDI-T exhibits highly reversible thermochromism over a 300-K range, manifest by color changes from orange (ambient temperature) toward red (cryogenic temperatures) or yellow (375 K), with repeated thermal cycling sustained for over at least 2 y. 

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