International Conference on Disaster Management, Architecture and Civil Engineering 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 Topics

These topics represent the foundational knowledge bases of each individual discipline before they are integrated with the others.

Disaster Management Foundations

The Disaster Cycle: Mitigation, preparedness, response, and recovery.

Hazard Identification and Risk Assessment (HIRA): Quantifying the probability and impact of natural and human-induced hazards.

Emergency Response Logistics: Resource allocation, evacuation routing, and temporary shelter deployment.

Crisis Communication Frameworks: Public warning systems and inter-agency coordination protocols.

Architectural Foundations

Spatial Planning and Typology: Functional zoning, building layout, and human circulation patterns.

Vernacular and Cultural Architecture: Adapting traditional, localized building methods to modern design.

Building Envelope and Aesthetics: Material selection for facades, energy efficiency, and visual integration with the environment.

Universal Design and Accessibility: Ensuring structures are usable by all people, including those with disabilities.

Civil Engineering Foundations

Structural Mechanics and Analysis: Calculating shear, moment, axial forces, and structural load paths.

Geotechnical Engineering: Soil mechanics, slope stability, and foundation design (shallow vs. deep foundations).

Fluid Mechanics and Hydraulics: Open channel flow, pipe networks, and pressurized fluid behavior.

Materials Science: The chemical and physical properties of concrete, steel, timber, and advanced composites.

2. Interrelated Topics

These topics exist at the intersection where two of the three fields collaborate directly.

Architecture + Civil Engineering (Built Environment Design)

Structural Expressionism: Aligning the aesthetic vision of architecture with the load-bearing requirements of structural engineering.

Building Information Modeling (BIM): Shared digital workflows for spatial layout, structural integrity, and MEP (Mechanical, Electrical, Plumbing) integration.

High-Rise and Large-Span Engineering: Balancing aerodynamic architectural forms with structural wind-bracing systems.

Foundation-Structure Interaction: How the architectural massing of a building dictates the civil engineering requirements of its foundation based on site soil conditions.

Disaster Management + Civil Engineering (Structural Resilience)

Structural Forensic Engineering: Investigating structural failures post-disaster to determine root causes (e.g., progressive collapse, material fatigue).

Retrofitting and Rehabilitation: Strengthening existing civil infrastructure (bridges, dams, highways) to withstand future hazards.

Lifeline Infrastructure Engineering: Designing resilient water, power, and transportation networks that must remain functional during a crisis.

Blast-Resistant Design: Engineering defense and critical infrastructure to survive explosions and impact loads.

Disaster Management + Architecture (Spatial Mitigation)

Defensive and Hardened Architecture: Designing buildings to naturally repel or mitigate threats, such as flood-barrier integration or blast-deflecting geometries.

Evacuation-Optimized Spatial Layouts: Designing corridors, stairwells, and egress points based on human behavioral psychology during panics.

Post-Disaster Transitional Housing: Modular, scalable, and rapidly deployable architectural structures for displaced populations.

Urban Fire-Spread Mitigation: Spatial zoning and building-separation distances designed to prevent urban conflagrations.

3. Tri-Interrelated Topics

These complex, highly integrated topics require the simultaneous application of Disaster Management principles, Architectural design, and Civil Engineering execution.

Resilient Urbanism and Smart Cities

Subtopics:

Macro-level urban zoning that keeps high-density architectural developments away from geotechnically unstable civil zones.

Integration of blue-green infrastructure (civil stormwater management combined with architectural public parks) to absorb flash floods.

Decentralized micro-grids built into communities to ensure survival when centralized infrastructure fails.

Multi-Hazard Performance-Based Design

Subtopics:

Moving beyond standard building codes to engineer and architect structures for specific performance levels (e.g., "Immediate Occupancy" vs. "Life Safety") after a major earthquake or hurricane.

Seismic isolation and damping systems (civil mechanisms) integrated into the spatial voids and structural expressions of buildings (architecture) to reduce disaster risk.

Wind-tunnel testing of architectural models to shape skyscrapers in ways that minimize wind loads on structural steel frames.

Coastal and Waterfront Climate Adaptation

Subtopics:

Amphibious and floating architecture designed to rise with sea levels or storm surges.

Civil maritime engineering (seawalls, breakwaters, revetments) integrated with waterfront public promenades and commercial spaces.

Managed retreat planning, determining when infrastructure must be engineered to resist vs. when architecture must be relocated out of harm's way.

Post-Disaster Reconstruction and Sustainable Recovery

Subtopics:

Build Back Better (BBB) methodologies ensuring that repaired infrastructure is stronger than its pre-disaster state.

Debris management and the recycling of demolished architectural materials into new civil engineering aggregates.

Rapid structural damage assessment protocols using AI and UAVs to deem buildings safe or unsafe for re-entry immediately following a catastrophe.

Name: Kate
Website: http://urebe.urst.org/
Address: Lisbon

UREBE stands for Universal Researchers in Environmental & Biological Engineering that is primarily dedicated to the research in Environmental & Biological Engineering.