Zeocat Project-3d

Development of a bifunctional hierarchically structured zeolite based nano-catalyst using 3D-technology for direct conversion of methane into aromatic hydrocarbons via methane dehydroaromatization

The goal of the project ZEOCAT-3D is the development of a new bi-functional (two types of active centers) structured catalysts, achieving for the first time a tetramodal pore size distribution (micro-, meso1-, meso2, macro-porous) and high dispersion of metal active sites for the conversion of methane, coming from different sources as natural gas and biogas, into high value chemicals such as aromatics (benzene, naphthalene, among others) via methane dehydroaromatization (MDA).

The main drawbacks associated with this process are: Low methane conversion, low selectivity towards the desired products and the quickly deactivation due to carbon deposition onto catalyst. These problems will be overcome by the use of hierarchical zeolites structures synthetized by 3D-printing and loaded with doped molybdenum nano-oxides. The methodology of the project will go from laboratory to pilot scale demonstration in a real environment. Catalyst design and operation conditions will be optimized for different methane feedstock at lab-scale and then upscaling and construction of a final prototype will be carried out. The optimisation of these catalytic processes will bring enormous advantages for increasing the exploitation of natural gas and biogas, since ZEOCAT-3D is very well in accordance with the programme topic NMBP-24, regarding development industrial process to obtain high value chemicals at the same time that the dependence from the current fossil fuel is reduced.

Official Website:  https://www.zeocat-3d.eu/

CALL / TOPIC: H2020-NMBP-ST-IND-2018 / CE-NMBP-24-2018 – Catalytic transformation of hydrocarbons

Grant agreement ID: 814548

Start – end date: 1 April 2019 – 30 September 2022

Budget and funding: € 6 764 020 / € 6 764 020

This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 814548