CO2 Absorption/Release Properties of Lithium Zirconate Powder Prepared by the Sol-Gel Process

Fei Wang, Y. Yoshimura, S. Hirai, Toshihiro Kuzuya
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引用次数: 2

Abstract

The sol-gel synthesized powder was a single phase Li2ZrO3. This synthesized powder reacted with CO2 at temperatures from the ambient temperature to a high temperature. The reaction products reacted reversibly to form Li2ZrO3 at temperatures above 925 K. The degree of absorption was defined as the value obtained by dividing the fractional mass gain of Li2ZrO3 after absorption by the fractional mass gain corresponding to a 100% reaction. Consequently, the degree of absorption was determined to be 95.2% under the absorption condition of 773 K and 7.2 ks. When CO2 absorption at 773 K and release at 993 K were repeated five times to examine the cyclic behavior, the degree of absorption was almost the same as the initial amount. The degree of absorption of commercial powder prepared by a solid-solid reaction of Li2CO3 and ZrO2 was 10.6% under the same absorption condition. The degrees of absorption with the sol-gel synthesized powder were determined to be 26, 31 and 43% under the absorption conditions of 293, 313 and 333 K for an exposure time of 115.2 ks. The absorption behavior could be best explained by an intraparticle diffusion mechanism. The diffusion of CO2 gas through the reaction product with an apparent activation energy of 24 kJ·mol−1 was a rate-determining step of the absorption reaction.
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溶胶-凝胶法制备锆酸锂粉体的CO2吸收/释放性能
溶胶-凝胶合成的粉体为单相Li2ZrO3。这种合成的粉末与二氧化碳在从环境温度到高温的温度下发生反应。反应产物在925 K以上可逆反应生成Li2ZrO3。吸收度定义为吸收后Li2ZrO3的分数质量增益除以100%反应对应的分数质量增益得到的值。结果表明,在773 K和7.2 K的吸收条件下,该化合物的吸收度为95.2%。在773 K下CO2的吸收和993 K下CO2的释放重复5次,考察循环行为,吸收程度与初始量基本相同。在相同的吸附条件下,用Li2CO3和ZrO2固固反应制备的工业粉末的吸收率为10.6%。在293、313和333 K的吸收条件下,曝光时间为115.2 ks,溶胶-凝胶合成粉体的吸收率分别为26、31和43%。吸收行为可以用粒子内扩散机制来最好地解释。表观活化能为24 kJ·mol−1的反应产物中CO2气体的扩散是吸附反应的一个速率决定步骤。
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