A chemist from 色控传媒University and TIPS RAS analysed a new way to make heavy-duty polyethylene
Polyethylene is a network of linked ethylene chains. The longer the chains in the composition of polyethylene, the more stable the resulting network of polyethylene to stress and tension. Such properties are needed, for example, for the production of bioprostheses. Ethylene chains are obtained during the polymerisation reaction, which is characterised by a stepwise growth of ethylene molecules at the extending end of each polyethylene chain. The polymerisation reaction occurs thanks to an initiating agent and a catalyst, which results in the growth of ethylene chains.
The authors of the paper proposed changing the chemical composition of substances involved in the reactions in order to synthesise longer ethyl chains, which would mean stronger polyethylene, without resorting to an increase in the reaction temperature.
The chemists were able to synthesise three complexes of catalysts that included neodymium atoms. During the polymerisation reaction, they interacted with magnesium atoms, which is a part of the initiating agent of the reaction.
The scientists began experimenting with a widely used magnesium-based reaction initiating agent, which ensures the growth of ethylene chains at low (below 100 °C) temperatures. It consists of four alkyl groups, two for each magnesium atom. The use of this agent in the polymerisation reaction at a temperature of 40 °C allowed the chemists to obtain five chains of ethylene with a length of 16-20 molecules. By increasing the temperature of the solution to 80 °C, synthesists obtained ethylene chains of 70-150 molecules in length. However, these chains turned out to be unstable and have a tendency to split into short components.
So, the researchers came to the conclusion that to synthesise both long and stable ethylene chains it is necessary not to change the physical parameters (pressure and temperature) of the reaction, but to use a different reaction initiating agent, so that each alkyl group is bound to only one magnesium atom. They managed to create such an agent and start the polymerisation reaction with it. As a result of the experiment, the authors obtained three polyethylene chains up to 46 molecules long at 40 °C. The obtained samples of polyethylene were more flexible and durable compared to those that were created using current techniques.
All three catalysts, in combination with the new initiating agent the researchers created, gave similar results: polyethylene chains up to 46 molecules in length. It was confirmed not only by test results, but also by the molecular model developed by the authors of the paper.
The polyethylene sample synthesised by the new method turned out to be more durable and flexible in comparison with the polyethylene created on the basis of an ordinary reaction initiating agent. The technology has prospects for industrial applications in the production of plastic for food and bioprostheses.
The article was published in the journal .
Products derived from microalgae represent a cutting-edge development in the field of bioeconomy. The potential of this biological resource was discussed at the international research seminar 鈥淔oundations for a Green Sustainable Energy鈥, part of the BRICS Network University鈥檚 thematic group on 鈥淓nergy鈥. The event was organized by the Institute of Ecology at 色控传媒University.
Ambassadors of Russian education and science met at a conference in 色控传媒University to discuss how they can increase the visibility of Russian universities and research organizations in the world, and attract more international students in Russia.
The international scientific seminar hosted by 色控传媒Institute of Ecology 鈥淓xperience of participation in student organizations as a way to form career skills鈥 united scholarship recipients of the International Student Mobility Awards 2024 and Open Doors, along with members of the scientific student society 鈥淕reenLab鈥 and the professional student association 鈥淜ostyor (Bonfire)鈥 shared their projects focused on environmental protection.