Zhijia Han scite author profile

Harvesting heat from the environment into electricity has the potential to power Internet-of-things (IoT) sensors, freeing them from cables or batteries and thus making them especially useful for wearable devices. We demonstrate a giant positive thermopower of 17.0 millivolts per degree Kelvin in a flexible, quasi-solid-state, ionic thermoelectric material using synergistic thermodiffusion and thermogalvanic effects. The ionic thermoelectric material is a gelatin matrix modulated with ion providers (KCl, NaCl, and KNO3) for thermodiffusion effect and a redox couple [Fe(CN)64–/Fe(CN)63–] for thermogalvanic effect. A proof-of-concept wearable device consisting of 25 unipolar elements generated more than 2 volts and a peak power of 5 microwatts using body heat. This ionic gelatin shows promise for environmental heat-to-electric energy conversion using ions as energy carriers.

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Mg₃₊_δSb_xBi₂₋_x Family: A Promising Substitute for the State‐of‐the‐Art n‐Type Thermoelectric Materials near Room Temperature

Shu

Zhou

Wang

et al. 2018

Adv Funct Materials

108

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The Bi2Te3−xSex family has constituted n‐type state‐of‐the‐art thermoelectric materials near room temperature (RT) for more than half a century, which dominates the active cooling and novel heat harvesting application near RT. However, the drawbacks of a brittle nature and Te‐content restricts the possibility for exploring potential applications. Here, it is shown that the Mg3+δSbxBi2−x family ((ZT)avg = 1.05) could be a promising substitute for the Bi2Te3−xSex family ((ZT)avg = 0.9–1.0) in the temperature range of 50–250 °C based on the comparable thermoelectric performance through a synergistic effect from the tunable bandgap using the alloy effect and the suppressible Mg‐vacancy formation using an interstitial Mn dopant. The former is to shift the optimal thermoelectric performance to near RT, and the latter is helpful to partially decouple the electrical transport and thermal transport in order to get an optimal RT power factor. The positive temperature dependence of the bandgap suggests this family is also a superior medium‐temperature thermoelectric material for the significantly suppressed bipolar effect. Furthermore, a two times higher mechanical toughness, compared with the Bi2Te3−xSex family, allows for a promising substitute for state‐of‐the‐art n‐type thermoelectric materials near RT.

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Thermodynamic criterions of the thermoelectric performance enhancement in Mg2Sn through the self-compensation vacancy

Zhu

Han

Jiang

et al. 2021

Materials Today Physics

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A general design strategy for thermoelectric interface materials in n-type Mg3Sb1.5Bi0.5 single leg used in TEGs

Han

Zhu

et al. 2022

Acta Materialia

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Zhijia Han

Giant thermopower of ionic gelatin near room temperature

Mg₃₊_δSb_xBi₂₋_x Family: A Promising Substitute for the State‐of‐the‐Art n‐Type Thermoelectric Materials near Room Temperature

Thermodynamic criterions of the thermoelectric performance enhancement in Mg2Sn through the self-compensation vacancy

A general design strategy for thermoelectric interface materials in n-type Mg3Sb1.5Bi0.5 single leg used in TEGs

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Zhijia Han

Giant thermopower of ionic gelatin near room temperature

Mg3+δSbxBi2−x Family: A Promising Substitute for the State‐of‐the‐Art n‐Type Thermoelectric Materials near Room Temperature

Thermodynamic criterions of the thermoelectric performance enhancement in Mg2Sn through the self-compensation vacancy

A general design strategy for thermoelectric interface materials in n-type Mg3Sb1.5Bi0.5 single leg used in TEGs

Contact Info

Product

Resources

About

Mg₃₊_δSb_xBi₂₋_x Family: A Promising Substitute for the State‐of‐the‐Art n‐Type Thermoelectric Materials near Room Temperature