TAGS: Biobased Solutions
Researchers at the Leibniz Institute for Catalysis, LIKAT, in Rostock have developed a catalytic process to produce HMF. HMF is the building blocks of the plastic PEF, a sustainable alternative to PET beverage packaging.
The production of PEF building blocks does not require petroleum, but instead cellulose and essentially only alcohol and air. The process can be transferred into practice immediately. The PEF process manages with a maximum of 60 degrees Celsius, operates at normal atmospheric pressure and can increase its productivity 15 times over under continuous flow conditions.
HMF – The Starting Material for PEF
The starting material for the PEF building blocks is a so-called platform chemical, a furan derivative called HMF, which is produced from cellulose, a polysaccharide from waste products such as agricultural waste.
Dr. Meija, the head of the research project, partnered with Nguyen Trung Thanh, a professor at Hanoi University of Technology. Meija's junior research group offered him the opportunity to develop a simplified process for the production of HMF from rice straw in his habilitation thesis. In parallel, Meija assigned a student from Venezuela, Abel Salazar, the task of improving the PEF process based on HMF.
The Reaction Process – How It Works?
In principle, in this process, a mixture of HMF and alcohol reacts with oxygen and in the presence of a catalyst to form an ester, or more precisely a diester, which can be polymerized to PEF in a further step. Compared to the previous process, the new process at the LIKAT manages with a fractional amount of heat and pressure.
On top of that, the researchers do not supply the required oxygen to the reaction in concentrated form, but rather from the air – which simplified the process considerably and apparently also increased the fun factor of the experiments.
At first, they simply took balloons, blew them up in the laboratory and put them over the apparatus. With three or four reactions at the same time, it made for a nice party scene in the lab. But the use of room air had a disadvantage for the reaction: it ran too slowly.
The product could only be examined the next morning. Meija and his team solved the problem in two places. First, they slightly increased the pressure and found an optimum at 20 bar. Secondly, they replaced the reaction vessel with a microflow reactor.
The starting materials, essentially a mixture of HMF and alcohol, are pressed through a system of fine tubes with oxygen or air. Due to the capillary forced guidance, the oxygen molecules come into contact with the starting mix in a well-dosed manner. The reaction mixture then passes through a cartridge.
There the catalyst is located, which starts the reaction, in this case particles of cobalt oxide and ruthenium, applied to the surface of small beads. This arrangement enables the "oxidative esterification", as chemists call this reaction, and above all it allows a continuous process.
The catalyst is not consumed, it can be used again and again. The product, the esterified PEF component, leaves the cartridge as a liquid and can now be polymerized. The reaction now runs 15 times faster than when the experiments began. The chemist is convinced that the result will interest many people.
Source: Leibniz Institute for Catalysis