International Conference on Advances in Engineering & Technology AENGGT on January 25-27, 2027 in Bangkok, Thailand

Call for Papers

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

1. Independent Core Engineering & Technology Domains

These fields possess standalone theoretical frameworks, specialized bodies of knowledge, and direct primary applications.

A. Advanced Computing & Information Tech

Quantum Computing: Quantum bit (qubit) scaling, fault-tolerant quantum error correction, and post-quantum cryptographic algorithms.

Cloud 3.0 & Distributed Infrastructure: Hyper-converged infrastructure, sovereign regional clouds (geopatriation), and edge computing nodes.

Next-Generation Wireless Communications: 6G network architectures, terahertz frequency allocation, and direct-to-satellite mobile connectivity.

Cybersecurity Engineering: Zero-trust architecture, AI-driven preemptive threat hunting, and digital provenance verification systems.

B. Materials Science & Nanotechnology

Smart & Adaptive Materials: Shape-memory alloys, piezoelectric sensors, and self-healing polymers.

Advanced Composites: Lightweight carbon-fiber matrices, biocomposites, and aerogels for extreme thermal management.

Nanomaterials: Graphene scaling, 2D transition metal dichalcogenides, and quantum dots.

C. Mechanical & Advanced Manufacturing Systems

Additive Manufacturing: High-speed metal 3D printing, multi-material deposition, and micro-scale bioprinting.

Precision Robotics: Kinematics of multi-axis robotic arms, soft robotics, and micro-electromechanical systems (MEMS).

Generative Mechanical Design: Stress and thermal load optimization via algorithmic CAD iteration.

D. Sustainable Energy & Environmental Engineering

Next-Gen Energy Storage: Sodium-ion chemistries, solid-state batteries, and grid-scale hydrogen storage.

Nuclear Innovations: Small Modular Reactors (SMRs) and commercial nuclear fusion confinement.

Decarbonization Technologies: Direct Lithium Extraction (DLE), passive radiative cooling materials, and PFAS ("forever chemical") UV/thermal degradation systems.

E. Civil & Structural Infrastructure

Resilient Infrastructure: Seismic-isolated skyscraper design, self-healing concrete, and climate-adaptive coastal barriers.

Civil Information Modeling (CIM): Macro-scale horizontal infrastructure modeling and parametric terrain integration.

F. Biomedical Engineering

Bioelectronics: Implantable neural interfaces, wireless pacemakers, and soft-tissue bionics.

Targeted Therapeutics: Nano-scale drug delivery vehicles and synthetic cellular scaffolds.

2. Interrelated & Convergent Technology Domains

These multidisciplinary fields emerge exclusively at the intersection of two or more independent domains.

A. Cyber-Physical Systems (CPS) & Automation

Intersects: Advanced Computing + Mechanical Systems + Wireless Communications

Physical AI & Embodied Robotics: Industrial humanoid robots trained on spatial intelligence models and reinforcement learning.

Autonomous Mobility Networks: Driverless fleet orchestration, vehicle-to-everything (V2X) communication protocols, and drone delivery logistics.

Smart Factories (Industry 4.0): Industrial IoT (IIOT) sensor fusion, closed-loop automated assembly, and wireless power transfer (WPT) for roaming factory floor robots.

B. Intelligent Civil & Urban Systems

Intersects: Civil Engineering + Computing + Sustainable Energy

Smart Cities: Interconnected urban sensor grids, dynamic traffic management, and automated municipal waste systems.

Everything-to-Grid (E2G) Systems: Mobilizing idle EV batteries and data center reserves back into local electrical grids during peak demand hours.

C. Digital Lifecycle & Simulation Architecture

Intersects: Computing + Mechanical + Civil + Materials Science

Digital Twins: Real-time virtual mirroring of physical assets (factories, wind turbines, bridges) using continuous IoT data feeds for predictive maintenance.

Building Information Modeling (BIM) Ecosystems: Cloud-based common data environments (CDE) for multi-disciplinary architectural simulation.

D. Cognition & Software Automation

Intersects: Advanced Computing + Cognitive Science

Agentic AI & Multi-Agent Systems: Autonomous "digital workers" capable of reasoning, negotiation, procurement, and code self-healing without human prompts.

Brain-Computer Interfaces (BCIs): Direct computational input processing bypassing mechanical peripherals.

3. Core Cross-Cutting Interdependencies

The entire landscape is bound together by specific, critical dependencies:

The Energy-Computing Loop: The massive scale of AI inference demands unprecedented data center energy. This forces computing engineers to rely on Sustainable Energy advancements (like SMRs), while energy engineers rely on AI and Advanced Computing to optimize microgrids and everything-to-grid distribution.

The Materials-Hardware Pipeline: Advances in robotics, bioelectronics, aerospace engineering, and battery tech are completely rate-limited by Materials Science. A lighter drone or a safer medical implant is fundamentally an achievement in advanced composites or biocompatible polymers.

The Simulation-to-Real (Sim-to-Real) Paradigm: Physical AI and mechanical automation can no longer scale via real-world trial and error. They depend entirely on Cloud computing power to run billions of physics-accurate simulations via Digital Twins before deploying a single script onto physical hardware.

Name: URENG
Website: http://ureng.urst.org/