On the Genesis of a Catalyst: A Brief Review with an Experimental Case Study

Simón Yunes, Jeffrey Kenvin, Antonio Gil
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Abstract

The science of catalysis has a direct impact on the world economy and the energy environment that positively affects the environmental ecosystem of our universe. Any catalyst, before being tested in a reaction, must undergo a specific characterization protocol to simulate its behavior under reaction conditions. In this work, these steps that must be carried out are presented, both generically and with examples, to the support and to the catalyst itself before and after the reaction. The first stage consists of knowing the textural and structural properties of the support used for the preparation of the catalysts. The specific surface area and the pore volume are fundamental properties, measured by N2 adsorption at −196 °C when preparing the catalyst, dispersing the active phase, and allowing the diffusion and reaction of the reactants and products on its surface. If knowing the structure of the catalyst is important to control its behavior against a reaction, being able to analyze the catalyst used under the reaction conditions is essential to have knowledge about what has happened inside the catalytic reactor. The most common characterization techniques in heterogeneous catalysis laboratories are those described in this work. As an application example, the catalytic conversion of CO2 to CH4 has been selected and summarized in this work. In this case, the synthesis and characterization of Cu and Ni catalysts supported on two Al2O3 with different textural properties, 92 and 310 m2/g, that allow for obtaining various metallic dispersions, between 3.3 and 25.5%, is described. The catalytic behavior of these materials is evaluated from the CO2 methanation reaction, as well as their stability from the properties they present before and after the reaction.
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催化剂的起源:一个实验案例的简要回顾
催化科学对世界经济和能源环境有着直接的影响,对我们宇宙的环境生态系统有着积极的影响。任何催化剂在进行反应测试之前,都必须经过特定的表征方案来模拟其在反应条件下的行为。在这项工作中,必须执行的这些步骤,无论是一般的还是举例,都是在反应前后对载体和催化剂本身提出的。第一阶段包括了解用于制备催化剂的载体的结构和结构性质。比表面积和孔体积是制备催化剂时的基本性质,在- 196℃下通过N2吸附来测量,使活性相分散,并允许反应物和生成物在其表面扩散和反应。如果了解催化剂的结构对控制其对反应的行为很重要,那么能够分析反应条件下使用的催化剂对于了解催化反应器内部发生的情况是必不可少的。在多相催化实验室中最常见的表征技术是在这项工作中描述的。作为应用实例,本文选取并总结了CO2催化转化为CH4的方法。在这种情况下,描述了Cu和Ni催化剂的合成和表征,这两种催化剂具有不同的结构性质,92和310 m2/g,允许获得不同的金属分散度,在3.3和25.5%之间。这些材料的催化行为是通过CO2甲烷化反应来评估的,以及它们在反应前后表现出的性能的稳定性。
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