Decomposition kinetics of Al- and Fe-doped calcium carbonate particles with improved solar absorbance and cycle stability

Chao Song; Xianglei Liu; Hangbin Zheng; Chuang Bao; Liang Teng; Yun Da; Feng Jiang; Chuan Li; Yongliang Li; Yimin Xuan; Yulong Ding

doi:10.1016/j.cej.2020.126282

Decomposition kinetics of Al- and Fe-doped calcium carbonate particles with improved solar absorbance and cycle stability

Chao Song, Xianglei Liu^*, Hangbin Zheng, Chuang Bao, Liang Teng, Yun Da, Feng Jiang, Chuan Li, Yongliang Li, Yimin Xuan, Yulong Ding

^*Corresponding author for this work

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

2 Citations (Scopus)

Abstract

Calcium-based materials are considered to be promising heat storage methods for the upcoming 3rd generation concentrated solar power systems (CSP) due to their high operation temperatures and energy storage densities. However, pure calcium carbonate (CaCO₃) particles suffer from poor solar absorptance and stability. In this work, we successfully enhance solar absorptance, cycle stability, and decrease decomposition temperature, simultaneously, based on proposed doped CaCO₃ particles. A fabrication method, which is cheap and suitable for large scale applications, is proposed based on doping Al and Fe elements into CaCO₃ powders via sol–gel processes. The average solar absorptance is enhanced by about 560%, and the energy storage density decay rate after 50 cycles is prominently reduced to be as low as 4.5% from 35.5%. The decomposition temperature is reduced by 15 to 24 K depending on the atmospheres, and the decomposition kinetics of both doped and pure CaCO₃ particles is found to follow the equation of phase boundary controlled reaction. The activation energy increases only slightly after doping, but will have a sharp increase when switching the atmosphere from N₂ to pure CO₂. This work paves the way to the design of high-performance calcium-based materials for next-generation high temperature thermal energy storage system.

Original language	English
Article number	126282
Number of pages	13
Journal	Chemical Engineering Journal
Volume	406
Early online date	17 Jul 2020
DOIs	https://doi.org/10.1016/j.cej.2020.126282
Publication status	Published - 15 Feb 2021

Bibliographical note

Funding Information:
This work was supported by the National Natural Science Foundation of China [No. 51820105010 ]. XL and YM also wants to thank the support from the Basic Science Center Program for Ordered Energy Conversion of the National Natural Science Foundation of China [No. 51888103 ].

Publisher Copyright:
© 2020 Elsevier B.V.

Keywords

Calcium carbonate
Cycle stability
Kinetics analysis
Solar absorptance
Thermochemical energy storage

ASJC Scopus subject areas

Chemistry(all)
Environmental Chemistry
Chemical Engineering(all)
Industrial and Manufacturing Engineering

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Cite this

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title = "Decomposition kinetics of Al- and Fe-doped calcium carbonate particles with improved solar absorbance and cycle stability",

abstract = "Calcium-based materials are considered to be promising heat storage methods for the upcoming 3rd generation concentrated solar power systems (CSP) due to their high operation temperatures and energy storage densities. However, pure calcium carbonate (CaCO3) particles suffer from poor solar absorptance and stability. In this work, we successfully enhance solar absorptance, cycle stability, and decrease decomposition temperature, simultaneously, based on proposed doped CaCO3 particles. A fabrication method, which is cheap and suitable for large scale applications, is proposed based on doping Al and Fe elements into CaCO3 powders via sol–gel processes. The average solar absorptance is enhanced by about 560%, and the energy storage density decay rate after 50 cycles is prominently reduced to be as low as 4.5% from 35.5%. The decomposition temperature is reduced by 15 to 24 K depending on the atmospheres, and the decomposition kinetics of both doped and pure CaCO3 particles is found to follow the equation of phase boundary controlled reaction. The activation energy increases only slightly after doping, but will have a sharp increase when switching the atmosphere from N2 to pure CO2. This work paves the way to the design of high-performance calcium-based materials for next-generation high temperature thermal energy storage system.",

keywords = "Calcium carbonate, Cycle stability, Kinetics analysis, Solar absorptance, Thermochemical energy storage",

author = "Chao Song and Xianglei Liu and Hangbin Zheng and Chuang Bao and Liang Teng and Yun Da and Feng Jiang and Chuan Li and Yongliang Li and Yimin Xuan and Yulong Ding",

note = "Funding Information: This work was supported by the National Natural Science Foundation of China [No. 51820105010 ]. XL and YM also wants to thank the support from the Basic Science Center Program for Ordered Energy Conversion of the National Natural Science Foundation of China [No. 51888103 ]. Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",

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AU - Song, Chao

AU - Liu, Xianglei

AU - Zheng, Hangbin

AU - Bao, Chuang

AU - Teng, Liang

AU - Da, Yun

AU - Jiang, Feng

AU - Li, Chuan

AU - Li, Yongliang

AU - Xuan, Yimin

AU - Ding, Yulong

N1 - Funding Information: This work was supported by the National Natural Science Foundation of China [No. 51820105010 ]. XL and YM also wants to thank the support from the Basic Science Center Program for Ordered Energy Conversion of the National Natural Science Foundation of China [No. 51888103 ]. Publisher Copyright: © 2020 Elsevier B.V.

PY - 2021/2/15

Y1 - 2021/2/15

N2 - Calcium-based materials are considered to be promising heat storage methods for the upcoming 3rd generation concentrated solar power systems (CSP) due to their high operation temperatures and energy storage densities. However, pure calcium carbonate (CaCO3) particles suffer from poor solar absorptance and stability. In this work, we successfully enhance solar absorptance, cycle stability, and decrease decomposition temperature, simultaneously, based on proposed doped CaCO3 particles. A fabrication method, which is cheap and suitable for large scale applications, is proposed based on doping Al and Fe elements into CaCO3 powders via sol–gel processes. The average solar absorptance is enhanced by about 560%, and the energy storage density decay rate after 50 cycles is prominently reduced to be as low as 4.5% from 35.5%. The decomposition temperature is reduced by 15 to 24 K depending on the atmospheres, and the decomposition kinetics of both doped and pure CaCO3 particles is found to follow the equation of phase boundary controlled reaction. The activation energy increases only slightly after doping, but will have a sharp increase when switching the atmosphere from N2 to pure CO2. This work paves the way to the design of high-performance calcium-based materials for next-generation high temperature thermal energy storage system.

AB - Calcium-based materials are considered to be promising heat storage methods for the upcoming 3rd generation concentrated solar power systems (CSP) due to their high operation temperatures and energy storage densities. However, pure calcium carbonate (CaCO3) particles suffer from poor solar absorptance and stability. In this work, we successfully enhance solar absorptance, cycle stability, and decrease decomposition temperature, simultaneously, based on proposed doped CaCO3 particles. A fabrication method, which is cheap and suitable for large scale applications, is proposed based on doping Al and Fe elements into CaCO3 powders via sol–gel processes. The average solar absorptance is enhanced by about 560%, and the energy storage density decay rate after 50 cycles is prominently reduced to be as low as 4.5% from 35.5%. The decomposition temperature is reduced by 15 to 24 K depending on the atmospheres, and the decomposition kinetics of both doped and pure CaCO3 particles is found to follow the equation of phase boundary controlled reaction. The activation energy increases only slightly after doping, but will have a sharp increase when switching the atmosphere from N2 to pure CO2. This work paves the way to the design of high-performance calcium-based materials for next-generation high temperature thermal energy storage system.

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Decomposition kinetics of Al- and Fe-doped calcium carbonate particles with improved solar absorbance and cycle stability

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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