R&D, Process & Systems Development Leader | Scientific & Technical Consultant
Combustion, Reactive & Thermochemical Processes | Process Intensification | 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, process intensification, and industrial process development.
My professional focus is translating scientific and engineering knowledge into practical, scalable, and industrially meaningful solutions for clean energy, resource efficiency, biomass and waste conversion, fuels and oil processing, wastewater treatment, emissions reduction, resource recovery, and circular industrial innovation.
- Applied physical chemistry, thermodynamics, transport phenomena, heat and mass transfer
- Chemical kinetics, detailed and reduced mechanisms, combustion, ignition, emissions, soot formation, and nanoparticle inception
- Reactive, thermochemical, energetic, and thermodynamic system development
- Biomass, waste, and alternative-feedstock conversion, including pyrolysis, gasification, reforming, syngas, biochar, and heat-recovery concepts
- Fuel, oil, and hydrocarbon-stream processing, including blending, homogenization, viscosity reduction, desulfurization support, and conditioning
- Wastewater treatment, advanced oxidation processes, process intensification, and selected hydrodynamic cavitation applications
- Process modeling, CFD, 0D–3D simulation, validation, optimization, engineering diagnostics, pilot concepts, and scale-up
- Waste-to-X, circular economy, resource recovery, and sustainable industrial process development
This GitHub profile shares selected public and non-confidential 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, wastewater treatment, fuels and oil processing, and sustainable industrial innovation.
The materials are intended to support scientific communication, technical transparency, education, reproducibility, engineering interpretation, and professional collaboration.
No confidential industrial data, proprietary client information, restricted project material, company-owned know-how, or sensitive operational information is included.
-
ndms-nanoparticle-inception
Companion materials for the transient nano-dense molecular state hypothesis and persistence-stabilization closure for combustion nanoparticle inception. -
aop-kinetic-process-framework
Python framework for matrix-aware kinetic and process-level evaluation of advanced oxidation processes in wastewater treatment. -
desulfurization-reaction-transport-regimes
Engineering diagnostic framework for desulfurization reaction–transport regimes, process intensification, and scale-up evaluation in gas and petroleum streams. -
biomass-process-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
Chemical-mechanism analysis, construction, reduction, validation, and adaptive implementation for CFD simulation. -
fuel-oil-processing-conditioning
Simplified engineering models and technical notes on fuel and oil processing, blending, homogenization, viscosity reduction, desulfurization support, and hydrocarbon-stream conditioning. -
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. -
cavitation-process-intensification-metrics
Energy-normalized metrics and engineering interpretation for hydrodynamic cavitation and related process-intensification technologies. -
publications-companion-materials
Companion calculations, figures, notebooks, and reproducibility materials related to selected public scientific and technical work.
I am interested in selected scientific and technical consulting, applied R&D collaboration, process-development support, technical evaluation, pilot-validation planning, scale-up strategy, industrial problem solving, non-confidential technology positioning, and sustainable process engineering.
Relevant areas include combustion, nanoparticle formation, detailed chemistry and CFD implementation, thermochemical conversion, biomass and waste valorization, fuel and oil processing, desulfurization support, process intensification, hydrodynamic cavitation, advanced oxidation processes, wastewater treatment, resource recovery, energy efficiency, emissions reduction, pilot development, and circular industrial technologies.
Programming and computation: Python, MATLAB, Fortran, C/C++, Jupyter Notebook
Modeling and simulation: CFD, reactive-flow modeling, chemical-kinetic modeling, detailed and reduced reaction mechanisms, 0D–3D modeling
Engineering analysis: heat and mass transfer, process calculations, validation, optimization, diagnostics, scale-up interpretation, and process-performance evaluation
Communication and reproducibility: data visualization, technical documentation, educational notebooks, application notes, scientific content, and reproducible calculation workflows