Institute of Fundamental Technological Research
Polish Academy of Sciences

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Ming Qu


Recent publications
1.  Liu X., Jani R., Orisakwe E., Johnston C., Chudziński P., Qu M., Norton B., Holmes N., Kohanoff J., Stella L., Yin H., Yazawa K., State of the art in composition, fabrication, characterization, and modeling methods of cement-based thermoelectric materials for low-temperature applications, Renewable and Sustainable Energy Reviews, ISSN: 1364-0321, DOI: 10.1016/j.rser.2020.110361, Vol.137, pp.110361-1-30, 2021

Abstract:
The worldwide energy crisis and environmental deterioration are probably humanity’s greatest challenges. Thermoelectricity, which allows for the mutual conversion between thermal and electrical energy, has become a promising technology to alleviate this challenge. Increasingly more research focuses on how to fabricate and apply thermoelectric materials for harvesting energy and regulating the indoor thermal environment. However, only a few studies have focused on cementitious materials with thermoelectric potential. Thermoelectric cement is a composite material in which particular additives can enhance the thermoelectric performance of ordinary cement. By potentially replacing traditional construction materials with thermoelectric cement in building ap-plications, electricity could be generated from waste heat, reducing the use of fossil fuels, and supplementing other renewable energy sources like solar and wind. This article presents a review of fundamentals, fabrication, characterization, composition, and performance, as well as modeling methods and opportunities for thermo-electric cement composites. The literature reviewed covers the period from 1998 to 2020 related to thermo-electric cement. It also presents the challenges and problems to overcome for further development and provide future research directions of thermoelectric cement.

Keywords:
thermoelectric cement composites, additives, thermoelectric generator, thermoelectric cooler, seebeck coefficient, figure of merit

Affiliations:
Liu X. - Imperial College London (GB)
Jani R. - other affiliation
Orisakwe E. - other affiliation
Johnston C. - other affiliation
Chudziński P. - IPPT PAN
Qu M. - other affiliation
Norton B. - other affiliation
Holmes N. - other affiliation
Kohanoff J. - Queen’s University Belfast (IE)
Stella L. - other affiliation
Yin H. - other affiliation
Yazawa K. - other affiliation

Conference papers
1.  Stella L., Johnston C., Troncoso J.F., Chudziński P., Orisakwe E., Kohanoff J., Jani R., Holmes N., Norton B., Liu X., Qu M., Yin H., Yazawa K., Modelling the thermoelectric properties of cement-based materials using finite element method and effective medium theory , CERI 2022, Civil Engineering Research in Ireland 2022, 2022-08-25/08-26, Dublin (IE), pp.1-7, 2022

Abstract:
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). KEY WORDS: Cement composites; Thermoelectrics; Seebeck C

Keywords:
Cement composites; Thermoelectrics; Seebeck Coefficient; Electrical Conductivity; Thermal Conductivity

Affiliations:
Stella L. - other affiliation
Johnston C. - other affiliation
Troncoso J.F. - Queen’s University Belfast (IE)
Chudziński P. - IPPT PAN
Orisakwe E. - other affiliation
Kohanoff J. - Queen’s University Belfast (IE)
Jani R. - other affiliation
Holmes N. - other affiliation
Norton B. - other affiliation
Liu X. - Imperial College London (GB)
Qu M. - other affiliation
Yin H. - other affiliation
Yazawa K. - other affiliation

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