BCBEE-25 2025 - 58th BANGKOK International Conference on “Chemical, Biological & Environmental Engineering” (BCBEE-25)

Website https://drabl.org/conference/440 | Edit Freely

Category Agriculture, Aquaculture, Biodiversity, Biology, Biotechnology, Botany, Chemistry, Cellular & Molecular Biology, Ecology, Environment, Food, GIS, Genetics, Microbiology, Oceanography, Physics, Soil, Waste Management, Water

Deadline: December 02, 2025 | Date: December 22, 2025-December 24, 2025

Venue/Country: Pattaya, Thailand

Updated: 2025-07-19 19:08:17 (GMT+9)

Call For Papers - CFP

Full Articles/ Reviews/ Shorts Papers/ Abstracts are welcomed in the following research fields:

I. Chemical Engineering

Process Intensification & Design:

Modular and intensified chemical processes.

Microreactors and lab-on-a-chip systems.

Advanced separation technologies (membranes, adsorption, reactive distillation).

Process modeling, simulation, and optimization (including AI/ML applications).

Sustainable process design and green engineering principles.

Catalysis & Reaction Engineering:

Novel catalyst development (nanocatalysts, biocatalysts, single-atom catalysts).

Catalysis for sustainable energy (e.g., hydrogen production, CO2 conversion).

Advanced reaction kinetics and reactor design.

Photocatalysis and electrocatalysis.

Materials Science & Engineering (Chemical Aspects):

Advanced functional materials (polymers, ceramics, composites).

Nanomaterials synthesis and characterization for specific applications.

Smart materials (self-healing, responsive materials).

Materials for energy storage and conversion.

Bio-based and biodegradable materials.

Thermodynamics & Transport Phenomena:

Advanced thermodynamic modeling and simulation.

Fluid mechanics, heat transfer, and mass transfer in complex systems.

Multiphase flow and interfacial phenomena.

Computational Fluid Dynamics (CFD) for process analysis.

Petroleum & Petrochemical Engineering (Sustainable Aspects):

Cleaner production technologies in the oil and gas industry.

Conversion of CO2 to chemicals and fuels.

Valorization of refinery by-products.

II. Biological Engineering / Biochemical Engineering

Bioprocess Engineering:

Bioreactor design and optimization for microbial and cell cultures.

Upstream and downstream processing in biomanufacturing.

Bioseparations and purification technologies.

Process analytical technology (PAT) for bioprocesses.

Synthetic Biology & Metabolic Engineering:

Designing and engineering biological systems for novel functions.

Metabolic pathway engineering for biosynthesis of chemicals, fuels, and pharmaceuticals.

CRISPR-based technologies for genetic manipulation.

Biosensors and diagnostic tools development.

Biomaterials & Regenerative Medicine:

Design and fabrication of biomaterials for tissue engineering and drug delivery.

Scaffolds for regenerative medicine and organ-on-a-chip systems.

Bio-nanotechnology and nanomedicine.

Biocompatibility and surface modification of materials.

Biofuels & Bioenergy:

Algal biofuels and advanced lignocellulosic biomass conversion.

Biorefineries for integrated production of fuels, chemicals, and materials.

Anaerobic digestion and biohydrogen production.

Techno-economic analysis of bioenergy systems.

Food & Agricultural Engineering (Biochemical aspects):

Bioprocessing for food ingredients and supplements.

Sustainable food production and precision agriculture.

Waste valorization in food processing.

Novel food technologies (e.g., cultivated meat).

Environmental Biotechnology:

Bioremediation of contaminated sites (soil, water, air).

Microbial fuel cells and bioelectrochemical systems.

Biotechnology for waste treatment and resource recovery.

III. Environmental Engineering

Water Resources & Wastewater Treatment:

Advanced water purification technologies (membranes, advanced oxidation processes).

Desalination and water reuse.

Removal of emerging contaminants (pharmaceuticals, microplastics, PFAS).

Resource recovery from wastewater (nutrients, energy).

Smart water networks and real-time monitoring.

Air Pollution Control:

Carbon Capture, Utilization, and Storage (CCUS) technologies.

Emission control for industrial and mobile sources.

Indoor air quality and air pollution modeling.

Technologies for removal of VOCs, NOx, SOx, and particulate matter.

Solid Waste Management & Resource Recovery:

Waste-to-energy technologies (incineration, pyrolysis, gasification).

Sustainable landfill management.

Recycling and recovery of critical raw materials.

Circular economy principles for waste minimization.

Valorization of waste into valuable products.

Environmental Modeling & Risk Assessment:

Pollutant transport and fate modeling in environmental systems.

Climate change modeling and impact assessment.

Life Cycle Assessment (LCA) for products and processes.

Environmental risk assessment and management.

Sustainable Cities & Infrastructure:

Green building materials and energy-efficient building design.

Sustainable urban planning and smart city solutions.

Nature-based solutions for urban water management and climate adaptation.

Environmental impact assessment for infrastructure projects.

Remediation Technologies:

Phytoremediation, bioremediation, and chemical remediation of contaminated soil and groundwater.

Sediment remediation techniques.

IV. Cross-Cutting & Interdisciplinary Themes

Sustainable Development & Circular Economy:

Integration of chemical, biological, and environmental engineering for sustainable development.

Industrial symbiosis and eco-industrial parks.

Policy and economic aspects of green technologies.

Computational & Data-Driven Approaches:

Artificial Intelligence (AI) and Machine Learning (ML) in all sub-disciplines (e.g., process optimization, material design, environmental forecasting).

Big data analytics for complex engineering systems.

Digital Twins for process monitoring and optimization.

Computational chemistry and biology for molecular design.

Nanotechnology in C, B, & E Engineering:

Nanomaterials for catalysis, separation, sensing, and environmental remediation.

Health and environmental implications of nanomaterials.

Safety, Health & Risk Management:

Process safety and inherently safer design.

Occupational health and safety in chemical and biological industries.

Risk assessment for novel technologies and processes.

Education & Professional Development:

Curriculum development for modern chemical, biological, and environmental engineers.

Hands-on learning, simulations, and virtual labs.

Ethics in engineering and sustainable practices.

Training for the future workforce in these evolving fields.

Policy, Regulations & Standards:

Environmental regulations and their impact on technological development.

International collaborations for addressing global environmental issues.

Standardization in green technologies and sustainable practices.