Single atom solutions for carbon dioxide capture

Chen Zhang; Chenyang Zhou; Yuan Li; Yunsong Yu; Jingfeng Zhang; Zaoxiao Zhang; Geoff Wang

doi:10.1063/5.0132627

Single atom solutions for carbon dioxide capture

Chen Zhang
, Chenyang Zhou
, Yuan Li
, Yunsong Yu
, Jingfeng Zhang
, Zaoxiao Zhang
, Geoff Wang

化学工程与技术学院

Xi'an Jiaotong University
University of Queensland

科研成果: 期刊稿件 › 文章 › 同行评审

23 引用（Scopus）

摘要

New solvents are considered to be one of the effective methods to facilitate the reaction rate and lower the reaction energy barrier. However, the common method to develop a new solvent has come to a dead end. Thus, a single atom in solvent to produce a single atom solution is designed to create the breakthrough. Eight kinds of single atom solutions are prepared as new absorbents. Experiments prove the single atom in the solutions and their charge-producing effects. A density functional theory model is developed to analyze the microscale characteristics. Meanwhile, it has been applied in carbon dioxide capture. The CO2 desorption rate is intensified in the single atom solution system due to the controlled reaction energy barrier. The results show that single atom solutions produce a maximum voltage of 2.12 V and, thus, contribute to near zero energy consumption by effectively harvesting the substantial waste heat below 373 K.

源语言	英语
文章编号	084309
期刊	Journal of Chemical Physics
卷	158
期	8
DOI	https://doi.org/10.1063/5.0132627
出版状态	已出版 - 28 2月 2023

联合国可持续发展目标

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可持续发展目标 7 经济适用的清洁能源

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10.1063/5.0132627

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引用此

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abstract = "New solvents are considered to be one of the effective methods to facilitate the reaction rate and lower the reaction energy barrier. However, the common method to develop a new solvent has come to a dead end. Thus, a single atom in solvent to produce a single atom solution is designed to create the breakthrough. Eight kinds of single atom solutions are prepared as new absorbents. Experiments prove the single atom in the solutions and their charge-producing effects. A density functional theory model is developed to analyze the microscale characteristics. Meanwhile, it has been applied in carbon dioxide capture. The CO2 desorption rate is intensified in the single atom solution system due to the controlled reaction energy barrier. The results show that single atom solutions produce a maximum voltage of 2.12 V and, thus, contribute to near zero energy consumption by effectively harvesting the substantial waste heat below 373 K.",

author = "Chen Zhang and Chenyang Zhou and Yuan Li and Yunsong Yu and Jingfeng Zhang and Zaoxiao Zhang and Geoff Wang",

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AU - Zhang, Chen

AU - Zhou, Chenyang

AU - Li, Yuan

AU - Yu, Yunsong

AU - Zhang, Jingfeng

AU - Zhang, Zaoxiao

AU - Wang, Geoff

PY - 2023/2/28

Y1 - 2023/2/28

N2 - New solvents are considered to be one of the effective methods to facilitate the reaction rate and lower the reaction energy barrier. However, the common method to develop a new solvent has come to a dead end. Thus, a single atom in solvent to produce a single atom solution is designed to create the breakthrough. Eight kinds of single atom solutions are prepared as new absorbents. Experiments prove the single atom in the solutions and their charge-producing effects. A density functional theory model is developed to analyze the microscale characteristics. Meanwhile, it has been applied in carbon dioxide capture. The CO2 desorption rate is intensified in the single atom solution system due to the controlled reaction energy barrier. The results show that single atom solutions produce a maximum voltage of 2.12 V and, thus, contribute to near zero energy consumption by effectively harvesting the substantial waste heat below 373 K.

AB - New solvents are considered to be one of the effective methods to facilitate the reaction rate and lower the reaction energy barrier. However, the common method to develop a new solvent has come to a dead end. Thus, a single atom in solvent to produce a single atom solution is designed to create the breakthrough. Eight kinds of single atom solutions are prepared as new absorbents. Experiments prove the single atom in the solutions and their charge-producing effects. A density functional theory model is developed to analyze the microscale characteristics. Meanwhile, it has been applied in carbon dioxide capture. The CO2 desorption rate is intensified in the single atom solution system due to the controlled reaction energy barrier. The results show that single atom solutions produce a maximum voltage of 2.12 V and, thus, contribute to near zero energy consumption by effectively harvesting the substantial waste heat below 373 K.

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DO - 10.1063/5.0132627

M3 - 文章

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AN - SCOPUS:85149262880

SN - 0021-9606

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JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

IS - 8

M1 - 084309

ER -

Single atom solutions for carbon dioxide capture

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