Chemical and biomass processing systems release volatile matter compounds into the environment daily. Catalytic reforming can convert these compounds into valuable fuels, but developing stable and efficient catalysts is challenging. Machine learning can handle complex relationships in big data and optimize reaction conditions, making it an effective solution for addressing the mentioned issues. This study is the first to develop a machine-learning-based research framework for modeling, understanding, and optimizing the catalytic steam reforming of volatile matter compounds. Toluene catalytic steam reforming is used as a case study to show how chemical/textural analyses (e.g., X-ray diffraction analysis) can be used to obtain input features ...
This work focuses on the removal of the tar derived from biomass gasification by catalytic steam ref...
Over the past two decades, the use of machine learning (ML) methods to model biomass and waste gasif...
Steam reforming of natural gas over a noble-metal based catalyst is studied experimentally and numer...
Chemical and biomass processing systems release volatile matter compounds into the environment daily...
Biomass gasification is a promising process for producing syngas, which is widely used in various in...
To overcome limitations of conventional H2 production approaches such as steam methane reforming (SM...
Hydrogen has diverse industrial applications namely in ammonia synthesis, petroleum refining and met...
Hydrogen (H2) is a clean fuel that can be produced from various resources including biomass. Optimiz...
Biofuels have been widely recognized as potential solutions to addressing the climate crisis and str...
Lignocellulosic biomass is widely recognized as an effective energy carrier capable of fulfilling th...
Chemical processes can benefit tremendously from fast and accurate effluent composition prediction f...
The catalytic dry reforming (DR) process is a clean approach to transform CO2 into H2 and CO-rich sy...
The hydrothermal liquefaction process has recently attracted more attention in biorefinery design an...
This work focuses on the removal of the tar derived from biomass gasification by catalytic steam ref...
Over the past two decades, the use of machine learning (ML) methods to model biomass and waste gasif...
Steam reforming of natural gas over a noble-metal based catalyst is studied experimentally and numer...
Chemical and biomass processing systems release volatile matter compounds into the environment daily...
Biomass gasification is a promising process for producing syngas, which is widely used in various in...
To overcome limitations of conventional H2 production approaches such as steam methane reforming (SM...
Hydrogen has diverse industrial applications namely in ammonia synthesis, petroleum refining and met...
Hydrogen (H2) is a clean fuel that can be produced from various resources including biomass. Optimiz...
Biofuels have been widely recognized as potential solutions to addressing the climate crisis and str...
Lignocellulosic biomass is widely recognized as an effective energy carrier capable of fulfilling th...
Chemical processes can benefit tremendously from fast and accurate effluent composition prediction f...
The catalytic dry reforming (DR) process is a clean approach to transform CO2 into H2 and CO-rich sy...
The hydrothermal liquefaction process has recently attracted more attention in biorefinery design an...
This work focuses on the removal of the tar derived from biomass gasification by catalytic steam ref...
Over the past two decades, the use of machine learning (ML) methods to model biomass and waste gasif...
Steam reforming of natural gas over a noble-metal based catalyst is studied experimentally and numer...