Where Does The Huge Amount Of Propylene Come From? New Catalysts To Help Or Alleviate Global Propylene Shortage

Apr 15, 2021

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Propylene is one of the basic organic chemical raw materials with the highest output in the world. In industry, the traditional preparation method is "to ask for propylene from petroleum". Propylene is derived from the catalytic cracking of petroleum. To put it vividly, the long-chain carbon-based molecules in the petroleum are "cut" into shorter propylene molecules.


"The limitation of this route lies in the dependence on petroleum." Professor Xiao Fengshou's team has been committed to the efficient use of carbon-based energy. He introduced that propylene can not only be obtained from petroleum, but also "propane from propane"-propane The technical route of dehydrogenation to propylene is emerging. "This technology directly allows propane to ‘remove’ two hydrogens and turn it into propylene. It is a technical route to get rid of oil dependence."


Propane is abundant in nature, and it is the main component of shale gas. Before better use of technology, the "destiny" of propane was burning. Until the emergence of the technology of propane dehydrogenation to propylene, propane has the possibility of exerting greater value.


It is worth noting that this type of technology is also divided into two routes: anaerobic dehydrogenation and aerobic dehydrogenation. At present, the former is applied. It uses expensive noble metal catalysts or toxic chromium catalysts. At the same time, it has the inevitable problems of carbon deposition and deactivation. Frequent regeneration is required to ensure the progress of the reaction.


The other is aerobic dehydrogenation route, which is expected to show advantages in terms of energy consumption and anti-carbon deposition. The scientific community has been studying it for decades, but has not "found" a catalyst that meets the actual industrial production, so it has not yet been used in the industry.上achieved.


In 2016, the I. Hermans team of the University of Wisconsin and Lu Anhui's team of Dalian University of Technology successively discovered the excellent selectivity of boron nitride in the aerobic dehydrogenation of propane. The research aroused the research enthusiasm of the academic circle, but this wave of research enthusiasm quickly "extinguished".


The academic circles have successively pointed out that although boron nitride has good selectivity, its catalytic activity and water resistance stability are still difficult to meet actual needs, and a consistent negative judgment has been formed: the catalytic activity of boron catalysts comes from multiple boron centers. Isolated boron does not work.


But the joint R&D team decided to return to the "dead end" to find out.


Years of catalyst research and development experience tells them that there are still many scientific questions that need to be ascertained. For example, where are the active sites of the boron-based catalyst? How does it exert its catalytic activity? To this end, the research team designed a way to isolate The boron-centered zeolite molecular sieve catalyst material. Zeolite molecular sieves are a common type of porous material. The pore diameter is usually less than one nanometer, so it can be used to "sieve molecules."


Wang Liang said that in addition to focusing on the active site itself, the "environment" in which the catalyst is designed is also the key. "In other words, who is the'neighbor' and how to arrange it is equally important." In the structure of the zeolite molecular sieve material used by the R&D team, there are siliceous and oxygen species around the boron to coordinate with it. Boron is an isolated boron, not a lot. Poly boron.


What surprised the research team was that this catalyst with a specific coordination environment boron center showed excellent catalytic performance in the aerobic dehydrogenation of propane, far exceeding the traditional supported boron oxide catalytic materials. In the continuous 220-hour "endurance" test, the aerobic dehydrogenation process catalyzed by this new type of zeolite molecular sieve maintained a selectivity of up to 83%, with a conversion rate of 32.9% to 43.7%, and various performances were stable.


The paper review experts believe that this research breaks the traditional cognition that isolated boron centers cannot catalyze the dehydrogenation of propane, and further deepens the understanding of propane dehydrogenation and its active centers, and is a step toward industrially realizing propane aerobic dehydrogenation to propylene. An important step has been taken.


Source: Chemical Network

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