Characterization and Performance Enhancement of Cement-Based Thermoelectric Materials

Ruchita Jani; Niall Holmes; Roger West; Kevin Gaughan; Xiaoli Liu; Ming Qu; Esther Orisakwe; Lorenzo Stella; Jorge Kohanoff; Hongxi Yin; Bartlomiej Wojciechowski

doi:10.3390/polym14122311

Characterization and Performance Enhancement of Cement-Based Thermoelectric Materials

Ruchita Jani, Niall Holmes, Roger West, Kevin Gaughan, Xiaoli Liu, Ming Qu, Esther Orisakwe, Lorenzo Stella, Jorge Kohanoff, Hongxi Yin, Bartlomiej Wojciechowski

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Thermoelectric materials enable the direct conversion of thermal to electrical energy. One application of this is ambient heat energy harvesting where relatively stable temperature gradients existing between the inside and outside of a building could be utilized to produce electricity. Buildings can thus change from energy consumers to energy generators. This could ultimately help reduce the surface temperatures and energy consumption of buildings, especially in urban areas. In this paper, research work carried out on developing and characterizing a cement-based thermoelectric material is presented. Cement-based samples are doped with different metal oxides (Bi₂O₃ and Fe₂O₃ ) to enhance their thermoelectric properties, which are defined through their Seebeck coefficient, electrical conductivity and thermal conductivity. The study also discusses the positive impact of moisture content on the electrical conductivity.

Original language	English
Article number	2311
Journal	Polymers
Volume	14
Issue number	12
DOIs	https://doi.org/10.3390/polym14122311
State	Published - Jun 1 2022

Keywords

cement composites
electrical conductivity
Seebeck coefficient
thermal conductivity
thermoelectrics

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10.3390/polym14122311

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title = "Characterization and Performance Enhancement of Cement-Based Thermoelectric Materials",

abstract = "Thermoelectric materials enable the direct conversion of thermal to electrical energy. One application of this is ambient heat energy harvesting where relatively stable temperature gradients existing between the inside and outside of a building could be utilized to produce electricity. Buildings can thus change from energy consumers to energy generators. This could ultimately help reduce the surface temperatures and energy consumption of buildings, especially in urban areas. In this paper, research work carried out on developing and characterizing a cement-based thermoelectric material is presented. Cement-based samples are doped with different metal oxides (Bi2O3 and Fe2O3 ) to enhance their thermoelectric properties, which are defined through their Seebeck coefficient, electrical conductivity and thermal conductivity. The study also discusses the positive impact of moisture content on the electrical conductivity.",

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AU - Jani, Ruchita

AU - Holmes, Niall

AU - West, Roger

AU - Gaughan, Kevin

AU - Liu, Xiaoli

AU - Qu, Ming

AU - Orisakwe, Esther

AU - Stella, Lorenzo

AU - Kohanoff, Jorge

AU - Yin, Hongxi

AU - Wojciechowski, Bartlomiej

PY - 2022/6/1

Y1 - 2022/6/1

N2 - Thermoelectric materials enable the direct conversion of thermal to electrical energy. One application of this is ambient heat energy harvesting where relatively stable temperature gradients existing between the inside and outside of a building could be utilized to produce electricity. Buildings can thus change from energy consumers to energy generators. This could ultimately help reduce the surface temperatures and energy consumption of buildings, especially in urban areas. In this paper, research work carried out on developing and characterizing a cement-based thermoelectric material is presented. Cement-based samples are doped with different metal oxides (Bi2O3 and Fe2O3 ) to enhance their thermoelectric properties, which are defined through their Seebeck coefficient, electrical conductivity and thermal conductivity. The study also discusses the positive impact of moisture content on the electrical conductivity.

AB - Thermoelectric materials enable the direct conversion of thermal to electrical energy. One application of this is ambient heat energy harvesting where relatively stable temperature gradients existing between the inside and outside of a building could be utilized to produce electricity. Buildings can thus change from energy consumers to energy generators. This could ultimately help reduce the surface temperatures and energy consumption of buildings, especially in urban areas. In this paper, research work carried out on developing and characterizing a cement-based thermoelectric material is presented. Cement-based samples are doped with different metal oxides (Bi2O3 and Fe2O3 ) to enhance their thermoelectric properties, which are defined through their Seebeck coefficient, electrical conductivity and thermal conductivity. The study also discusses the positive impact of moisture content on the electrical conductivity.

KW - cement composites

KW - electrical conductivity

KW - Seebeck coefficient

KW - thermal conductivity

KW - thermoelectrics

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ER -

Characterization and Performance Enhancement of Cement-Based Thermoelectric Materials

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Keywords

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