UTSA researcher’s new study describes new way to reduce energy in plastics manufacturing
(May 23, 2016) -- Plastic manufacturing is an energy-intensive process. Now, research performed in part by Banglin Chen, Dean’s Distinguished Professor of Chemistry at The University of Texas at San Antonio (UTSA) has revealed a way to reduce the energy demand in one key step of plastic manufacturing by using a class of materials that can filter impurities more efficiently than the conventional manufacturing process.
Chen’s top-tier research, published in the journal Science, show that materials called metal-organic frameworks (MOFs) can effectively remove the contaminant acetylene from ethylene, the material from which much of the world’s plastic is made. The research suggests that filtering out acetylene using MOFs would produce ethylene at the high purity that industry demands while sidestepping the current need to convert acetylene to ethylene via a costly catalytic process.
The chemical name for the plastic you see every day – from water bottles and grocery bags to household appliances – is polyethylene, a pliable material made by stringing together long chains of a simpler molecule called ethylene. Worldwide demand for plastic makes ethylene the most widely produced organic compound in the world, with well over 100 million tons manufactured each year, largely by refining crude oil.
Newly made ethylene is not pure enough to become plastic because the refinement process also creates a substantial amount of acetylene, which can ruin the catalysts that enable ethylene molecules to be strung together. The conventional industrial solution is to convert this undesirable acetylene into ethylene as well, but this step requires the use of palladium, an expensive and rare metal, as a catalyst and consumes a significant amount of energy.
Chen and his fellow researchers found that a family of MOF materials called SIFSIX, discovered in the 1990s, might provide a better alternative for removing the acetylene. MOFs are porous crystals that under a microscope look a bit like a building under construction – lots of girders with space in between. The SIFSIX group gets its name from some of its girders, which are formed from silicon (Si) and six atoms of fluorine (F6).
The team found that when they passed ethylene through the MOFs, the fluorine attracted and captured most of the acetylene contaminant, letting the now-purified ethylene to pass unhindered. Varying the size of the pores by changing the length of the girders allowed the MOFs to filter ethylene-containing acetylene in concentrations of anywhere from 1 percent to 50 percent, which are typical in industry.
The SIFSIX MOFs set records among adsorbent materials for both selectivity (the ability to attract the acetylene only while allowing the ethylene to pass) and adsorption capacity. According to the research team, the results show that the SIFSIX group offers a viable alternative to standard industrial practice.
----------------------------
Learn more about Banglin Chen.
Learn more about the UTSA Department of Chemistry.
Connect online at Facebook, Twitter, YouTube, Instagram and UTSA Today.
Events
This event will acknowledge graduating seniors from the McNair Scholars program at UTSA before inducting the new cohort of scholars into the program.
North Paseo Building (NPB 5.140), Main CampusAt this memorable celebration, UTSA graduates will be introduced one-by-one to cross the stage and accept their doctoral degrees.
Arts Building Recital Hall, Main CampusRoadrunner Walk is an event for graduating students to have a memorable walk on campus to celebrate an important milestone and their achievements. Graduates will walk along the Paseo while being celebrated by the UTSA community, friends, and family members.
Student Union Paseo, Main CampusCelebrate the accomplishments of College of Education and Human Development, College for Health, Community and Policy, College of Sciences and University College.
Alamodome, 100 Montana St.Celebrate the accomplishments of Alvarez College of Business, College of Liberal and Fine Arts and Klesse College of Engineering and Integrated Design.
Alamodome, 100 Montana St.