R&D Leader | Combustion, Reactive & Thermochemical Processes | Scale-Up & Sustainable Industrial Innovation
I work at the interface of applied physical chemistry, thermodynamics, chemical kinetics, heat and mass transfer, combustion science, reactive systems, thermochemical conversion, process modeling, CFD simulation, and industrial technology development.
My professional focus is the translation of scientific and engineering knowledge into practical technologies, scalable processes, and industrially relevant solutions. This includes combustion and reactive systems, thermochemical conversion, biomass and waste conversion, syngas and reforming concepts, fuel and oil upgrading, desulfurization, wastewater treatment, advanced oxidation processes, hydrodynamic cavitation, recycling, resource recovery, and circular industrial innovation.
- Applied physical chemistry, thermodynamics, heat and mass transfer, and transport phenomena
- Chemical kinetics, detailed chemistry, mechanism analysis, reduction, construction, and implementation
- Reactive, thermochemical, energetic, and thermodynamic system development
- Combustion, ignition, emissions, soot formation, and combustion nanoparticle inception
- Transient nano-dense molecular state hypothesis and persistence-stabilization closure for nanoparticle inception
- Thermochemical conversion of biomass, waste, and alternative feedstocks
- Pyrolysis, gasification, reforming, syngas, biochar, and heat-recovery concepts
- Fuel, oil, and hydrocarbon stream upgrading and conditioning
- Fuel blending, homogenization, viscosity reduction, desulfurization, diesel, biodiesel, heavy fuel oil, and waste pyrolysis oil treatment
- Wastewater treatment, advanced oxidation processes, hydrodynamic cavitation, and process intensification
- Waste-to-X, circular economy, resource recovery, and sustainable industrial process development
- Process modeling, simulation, validation, optimization, pilot-plant concepts, and scale-up
- 0D-3D modeling, CFD, chemical-kinetic modeling, process analysis, and engineering diagnostics
These repositories demonstrate how scientific principles from physical chemistry, thermodynamics, chemical kinetics, combustion, reactive systems, fluid dynamics, heat and mass transfer, computational fluid dynamics, and process engineering can be translated into practical engineering tools for modeling, simulation, optimization, validation, scale-up, and industrial decision support.
This GitHub profile is intended to share selected open technical resources, simplified models, educational notebooks, reproducible calculation workflows, engineering frameworks, and companion materials related to applied physical-chemical sciences, thermochemical process development, detailed chemistry, CFD, and sustainable industrial innovation.
The materials shared here are intended for scientific communication, technical transparency, education, reproducibility, and professional collaboration.
No confidential industrial data, proprietary client information, restricted project material, or sensitive operational know-how is included.
-
ndms-combustion-nanoparticle-inception
Companion materials for the transient nano-dense molecular state hypothesis and persistence-stabilization closure for combustion nanoparticle inception. -
biomass-thermochemical-conversion-modeling
Simplified engineering models, curated simulation data, and technical notes on biomass thermochemical conversion, biochar production, heat generation, syngas formation, exhaust-gas composition, residence-time effects, and screening-level carbon-management assessment.
-
detailed-chemistry-cfd-framework
Detailed chemical-mechanism analysis, construction, reduction, validation, and adaptive implementation for CFD simulation, including selected Fortran and Python workflows. -
aop-kinetic-process-framework
A unified kinetic-process framework for advanced oxidation processes, connecting radical chemistry, operating conditions, reactor-scale performance, and wastewater-treatment effectiveness. -
cavitation-process-intensification-metrics
Energy-normalized metrics and engineering interpretation for hydrodynamic cavitation and related process-intensification technologies. -
desulfurization-reaction-transport-regimes
Reaction-transport regime analysis for desulfurization of gas and petroleum streams, supporting engineering diagnosis, technology selection, and operating-window definition. -
fuel-oil-upgrading-conditioning
Simplified engineering models and technical notes related to fuel and oil upgrading, blending, homogenization, viscosity reduction, desulfurization, and conditioning of hydrocarbon streams. -
reactive-systems-scale-up
Engineering notes and simplified models for translating laboratory reactive-system data toward pilot and industrial scale. -
waste-to-x-process-analysis
Open technical resources on waste valorization, circular process routes, and waste-to-energy / waste-to-material concepts. -
publications-companion-materials
Companion calculations, figures, notebooks, and reproducibility materials related to selected public scientific and technical work.
- Python
- MATLAB
- Fortran
- C / C++
- Jupyter Notebook
- CFD and reactive-flow modeling
- Chemical-kinetic modeling
- Detailed and reduced reaction mechanisms
- Heat and mass transfer analysis
- Process calculation and engineering analysis
- Data visualization and technical documentation
- Experimental validation and process-performance interpretation
I am interested in applied R&D collaboration, technology development, process validation, scientific consulting, industrial innovation, and sustainable process engineering.
Relevant collaboration areas include combustion, soot and nanoparticle formation, detailed chemistry and CFD implementation, thermochemical conversion, biomass and waste valorization, fuel and oil upgrading, desulfurization, hydrodynamic cavitation, advanced oxidation processes, wastewater treatment, resource recovery, energy efficiency, emissions reduction, pilot-plant development, and circular industrial technologies.