BICFET-25 2025 - 38th BANGKOK International Conference on “Futuristic Engineering Technologies” (BICFET-25)

Website https://iceeat.heaig.org/conference/351 | Edit Freely

Category ENGINEERING, TECHNOLOGY, AI, Automobile, Bioinformatics, Biomedical, Chemical, Computer, Computing, Electrical, Energy, Image Processing, IT, Manufacturing, Mechanical, Metallurgical, Military, Mining, Nanotechnology, Aviation

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

Venue/Country: Bangkok, Thailand

Updated: 2025-07-19 18:48:59 (GMT+9)

Call For Papers - CFP

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

Track 1: Advanced Materials & Manufacturing

Additive Manufacturing & 4D/5D Printing:

Multi-material and functional additive manufacturing.

Self-assembly and reconfigurable materials for 4D/5D printing.

Direct printing of electronics, sensors, and integrated systems.

Additive manufacturing for aerospace, biomedical, and construction.

Smart & Adaptive Materials:

Self-healing and self-sensing materials.

Responsive materials (thermochromic, electroactive, photoactive).

Metamaterials for novel optical, acoustic, and electromagnetic properties.

Bio-inspired and biomimetic materials.

Nanomaterials & Nanotechnology in Engineering:

Graphene, carbon nanotubes, and 2D materials for enhanced properties.

Nanocomposites and nanocoatings.

Applications in energy, electronics, and biomedicine.

Sustainable Manufacturing:

Circular economy principles in material design and production.

Green chemistry and sustainable process engineering.

Resource efficiency and waste valorization in industrial processes.

Track 2: Artificial Intelligence & Autonomous Systems

AI for Engineering Design & Optimization:

Generative design and AI-driven concept generation.

Topology optimization and material-aware AI design.

AI for multi-objective optimization and complex system synthesis.

Robotics & Autonomous Systems:

Collaborative robotics (cobots) and human-robot interaction.

Soft robotics and bio-inspired robotics.

Swarm intelligence and multi-robot systems.

Autonomous vehicles, drones, and unmanned systems (perception, navigation, control).

Robotics for extreme environments (space, deep sea, disaster response).

Predictive Maintenance & Digital Twins:

AI-powered prognostics and health management (PHM).

Real-time digital replicas for simulation, monitoring, and proactive intervention.

Digital twin applications in smart cities, manufacturing, and infrastructure.

Explainable AI (XAI) in Engineering:

Developing transparent and interpretable AI models for engineering decisions.

Trust and reliability in AI-driven autonomous systems.

AI for Materials Discovery:

Accelerated design and discovery of novel materials using AI and machine learning.

Track 3: Sustainable Energy & Environmental Engineering

Next-Generation Renewable Energy:

Perovskite and quantum dot solar cells.

Advanced wind turbine aerodynamics and floating offshore platforms.

Green hydrogen production, storage, and fuel cell technologies.

Enhanced geothermal systems and hybrid energy solutions.

Sustainable energy storage (solid-state batteries, flow batteries, grid-scale solutions).

Carbon Capture, Utilization & Storage (CCUS):

Direct air capture (DAC) technologies.

Innovative sorbents and membranes for CO2 separation.

Conversion of captured CO2 into valuable products.

Water & Wastewater Management:

Advanced water purification and desalination technologies.

Resource recovery from wastewater (nutrients, energy).

Removal of emerging contaminants (microplastics, pharmaceuticals).

Environmental Remediation & Resource Recovery:

Nanotechnology and biotechnology for pollutant removal.

Waste-to-energy and waste valorization technologies.

Circular economy approaches in water and waste management.

Climate-Resilient Engineering:

Infrastructure design for climate change adaptation and mitigation.

Nature-based solutions for urban and coastal resilience.

Track 4: Biomedical & Bio-Engineering

Bioprinting & Tissue Engineering:

3D bioprinting of organs, tissues, and scaffolds for regenerative medicine.

Personalized implants and prosthetics.

Brain-Computer Interfaces (BCI) & Neuroengineering:

Direct neural interfaces for control, communication, and therapy.

Neural prosthetics and brain-inspired computing.

Synthetic Biology & Genetic Engineering:

Designing biological systems for specific functions (e.g., biosensors, biofuel production).

Gene editing technologies (CRISPR) for therapeutic and industrial applications.

Advanced Medical Devices & Diagnostics:

Wearable health monitoring systems and point-of-care diagnostics.

Miniaturized surgical robots and interventional devices.

Nanomedicine for targeted drug delivery and imaging.

Track 5: Space, Infrastructure & Quantum Engineering

Space Engineering & Exploration:

In-Situ Resource Utilization (ISRU) for lunar and Martian missions.

Advanced propulsion systems (nuclear thermal, electric, breakthrough concepts).

Space habitats and life support systems.

Autonomous space robotics and AI for deep space missions.

Smart Infrastructure & Urban Systems:

IoT-enabled infrastructure monitoring and management.

Resilient and sustainable urban planning with smart technologies.

Future of transportation (hyperloop, aerial mobility, smart traffic management).

Quantum Engineering:

Engineering quantum devices for computing, sensing, and communication.

Quantum-resistant cryptography and secure communication.

Quantum metrology and sensing for ultra-precision measurements.

Track 6: Cross-Cutting Themes & Societal Impact

Cyber-Physical Systems (CPS) & IoT in Engineering:

Security, privacy, and reliability of interconnected engineering systems.

Industry 4.0/5.0 implementation and challenges.

Extended Reality (XR) in Engineering:

VR/AR/MR for design, simulation, training, and remote collaboration.

Ethics & Governance of Futuristic Engineering:

Responsible innovation and societal implications of emerging technologies.

Regulatory frameworks and policy for advanced engineering.

Addressing the environmental footprint of new technologies.

Human-Centered Design in Engineering:

Ergonomics and user experience for complex systems.

Designing for accessibility and inclusivity in future technologies.

Interdisciplinary Engineering Education:

Preparing the next generation of engineers for complex, interdisciplinary challenges.

New pedagogies and tools for teaching futuristic engineering concepts.