Reactivity of silver oxide in the absorption of carbon dioxide

P. A. Barnes, M. O'connor, F. Stone
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引用次数: 11

Abstract

Silver carbonate prepared by precipitation from very dilute solutions of AgNO3 and NaHCO3 decomposes at 170 °C to yield Ag2O which is particularly active for the uptake of CO2. In contrast to other oxide adsorbents prepared from carbonates, the high activity is not a consequence of the development of a high surface area. The decomposition of Ag2CO3 leads to only a small increase in surface area, the oxide product having an area less than 1 m2 g–1. The activity in this system is linked instead with the presence of water. Co2 absorption depends upon the continuing availability of water at the reacting interface. Ag2O rapidly loses activity towards CO2 uptake in absorption–regeneration cycles if dry CO2 is employed. There is, in addition, a slow loss of activity during cycling which is independent of the presence of water. The results are discussed by use of a model in which water is considered to be incorporated in the oxide as OH– and in the carbonated solid as OH– and HCO3– ions.
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氧化银吸收二氧化碳的反应性
从非常稀的AgNO3和NaHCO3溶液中沉淀制备的碳酸银在170°C下分解生成Ag2O, Ag2O对吸收CO2特别活跃。与其他由碳酸盐制备的氧化物吸附剂相比,高活性不是高表面积发展的结果。Ag2CO3的分解只导致表面面积的小幅增加,氧化产物的面积小于1 m2 g-1。相反,这个系统的活动与水的存在有关。二氧化碳的吸收取决于反应界面上水的持续可用性。如果采用干CO2, Ag2O在吸收-再生循环中迅速失去对CO2吸收的活性。此外,在循环过程中,活动的缓慢丧失与水的存在无关。结果是通过使用一个模型来讨论的,在这个模型中,水被认为是作为OH -离子加入氧化物中,作为OH -离子和HCO3 -离子加入碳酸固体中。
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