Methane, a potent greenhouse gas, traps significantly more heat than carbon dioxide, making its mitigation critical for addressing climate change.
MIT chemical engineers in Prof. Michael Strano’s group have developed an innovative hybrid catalyst to convert methane into useful polymeric materials, aiming to reduce greenhouse gas emissions.
Published in Nature Catalysis, the study is led by Daniel Lundberg, PhD ’24, and Dr. Jimin Kim, with contributions from Dr. Cody Ritt and Assistant Professor Yu-Ming Tu, a former MIT postdoc, now in the Chemical Engineering at National Taiwan University.
Hybrid catalyst design and function
The innovative hybrid catalyst operates at room temperature and atmospheric pressure, simplifying its use and lowering costs. It combines two key components: 1. Zeolite (iron-modified aluminum silicate): A cost-effective mineral with catalytic properties, particularly in methane conversion. 2. Alcohol oxidase enzyme: A biological enzyme used by bacteria, fungi, and plants to oxidize alcohols.
This tandem system facilitates a two-step reaction. Initially, the zeolite converts methane into methanol. The enzyme then transforms methanol into formaldehyde, generating hydrogen peroxide as a byproduct. The hydrogen peroxide is recycled within the zeolite, enabling continuous methane-to-methanol conversion.
Potential applications in generating useful polymers
Methane, composed of one carbon atom and four hydrogen atoms, is a valuable raw material for producing polymers. However, traditional methods of methane conversion require high temperatures and pressures, posing significant energy challenges.
The MIT hybrid catalyst’s low-energy requirements and water-suspension design allow it to absorb methane directly from the air. This opens possibilities for applications at methane emission sources, such as power plants and livestock facilities.
The researchers also envision incorporating the catalyst into polymer matrices, creating self-repairing materials that regenerate in the presence of methane emissions. Such systems can extend the lifespan of polymers and enable sustainable manufacturing processes. Additionally, the catalyst can be applied as a film coating on surfaces exposed to methane, facilitating polymer production for industrial use.
“This work marks a step in using tandem catalysis of biological enzymes and artificial catalysts toward innovative carbon-fixing technologies that transform methane emissions into valuable resources and materials,” says Professor Yu-Ming Tu in the Department of Chemical Engineering at National Taiwan University. By enabling efficient methane utilization, the hybrid catalyst paves the way for sustainable solutions to combat climate change.
Prof. Yu-Ming Tu’s email address: [email protected]