SSCAE-25 2025 - 33rd BALI Global Congress on Sustainable Solutions in Civil & Architectural Engineering (SSCAE-25) scheduled on Dec. 25-27, 2025 Bali (Indonesia)

Website https://urcae.urst.org/conference/147 | Edit Freely

Category ENGINEERING, TECHNOLOGY, AI, Automobile, Bioinformatics, Biomedical, Chemical, Computer, Computing, Electrical, Energy, Image Processing, IT, Manufacturing, Mechanical, Metallurgical, Military, Mining, Nanotechnology, Aviation Architecture, Building Materials, Civil Engineering, Landscape, Pollution, Transportation.

Deadline: December 01, 2025 | Date: December 25, 2025-December 27, 2025

Venue/Country: Bali, Indonesia

Updated: 2025-07-09 17:12:40 (GMT+9)

Call For Papers - CFP

Topics of Interest for Submission include, but are Not Limited to:

I. Sustainable Materials & Technologies

Green Building Materials:

Low-carbon concrete (e.g., geopolymers, carbon-cured concrete).

Sustainable timber and mass timber construction.

Recycled and upcycled materials (e.g., recycled aggregates, plastic waste in asphalt).

Bio-based materials (e.g., hempcrete, straw bale, mycelium composites).

Smart materials (self-healing concrete, phase-change materials, responsive facades).

Advanced insulation materials (aerogels, vacuum insulation panels).

Novel Construction Methods:

Prefabrication and modular construction for reduced waste and improved efficiency.

3D printing/Additive manufacturing in construction (concrete, metal, polymers).

Robotics and automation for precision and waste reduction.

Digital fabrication and mass customization.

Sustainable Pavement & Road Materials:

Porous pavements and permeable surfaces for stormwater management.

Recycled asphalt and concrete in road construction.

Cool pavements to mitigate urban heat island effect.

II. Energy Efficiency & Renewable Energy in Buildings

Net-Zero Energy Buildings (NZEBs) & Net-Zero Carbon Buildings:

Design strategies for ultra-low energy consumption.

Integration of on-site renewable energy systems (solar PV, solar thermal, small wind).

Energy modeling and simulation for performance optimization.

Case studies and challenges in achieving NZEB.

Passive Design Strategies:

Optimizing building orientation, daylighting, and natural ventilation.

Thermal mass and insulation techniques.

Facade design for solar control and thermal performance.

Advanced HVAC Systems:

High-efficiency heating, ventilation, and air conditioning.

Geothermal heat pumps and district heating/cooling.

Smart controls and building management systems (BMS).

Building Envelope Performance:

Innovations in windows, glazing, and shading devices.

Air tightness and thermal bridging mitigation.

Dynamic facades and adaptive building skins.

Renewable Energy Integration:

Building-integrated photovoltaics (BIPV).

Micro-wind turbines and micro-hydropower for buildings.

Battery energy storage systems for building resilience and grid interaction.

III. Water Management & Urban Hydrology

Sustainable Urban Drainage Systems (SUDS) / Green Infrastructure:

Rainwater harvesting and reuse.

Green roofs, permeable pavements, and bioretention systems for stormwater management.

Wastewater reuse and greywater recycling at building and urban scales.

Nature-based solutions for flood mitigation.

Water Efficiency in Buildings:

Low-flow fixtures and water-efficient landscaping.

Smart water metering and leak detection.

Urban Water Cycle Management:

Integrated urban water management strategies.

Climate change impacts on urban water resources and adaptation strategies.

Pollutant removal from urban runoff.

IV. Resilient Infrastructure & Climate Change Adaptation

Climate-Resilient Design:

Designing infrastructure to withstand extreme weather events (floods, storms, heatwaves).

Coastal resilience and sea-level rise adaptation.

Seismic retrofitting and earthquake-resistant structures.

Disaster Risk Reduction (DRR) in the Built Environment:

Vulnerability assessment and risk mapping.

Early warning systems for civil infrastructure.

Post-disaster reconstruction with "Build Back Better" principles.

Infrastructure Asset Management for Sustainability:

Life cycle assessment and costing for long-term resilience.

Predictive maintenance and structural health monitoring.

Urban Heat Island Mitigation:

Cool roofs, cool pavements, and urban greening strategies.

Urban ventilation and microclimate optimization.

V. Circular Economy in Construction

Design for Disassembly & Adaptability:

Creating buildings and components that can be easily deconstructed and reused.

Flexible designs for future functional changes.

Construction & Demolition Waste Management:

Strategies for waste reduction, reuse, and recycling on construction sites.

Upcycling of construction and demolition waste into new products.

Material Passports & Digital Logbooks:

Tracking materials and components for future reuse and recycling.

Blockchain applications for transparent material supply chains.

Industrial Symbiosis in Construction:

Waste products from one industry becoming inputs for another in the construction sector.

Product-as-a-Service Models:

Exploring new business models for building components and systems.

VI. Digital Transformation for Sustainable Solutions

Building Information Modeling (BIM) for Sustainability:

Integrating sustainability metrics, energy performance, and LCA into BIM workflows.

BIM for waste reduction and material management.

Digital Twins & Smart Infrastructure:

Creating virtual replicas of buildings and infrastructure for real-time monitoring and optimization.

AI and machine learning for predictive performance and adaptive control.

Sensors & IoT in Smart Buildings/Cities:

Real-time monitoring of energy, water, air quality, and structural health.

Occupant behavior sensing and optimization.

Computational Design & Optimization:

Generative design for sustainable architectural forms and structural systems.

Parametric design for performance-driven optimization.

Geographic Information Systems (GIS) for Urban Sustainability:

Spatial analysis for site selection, environmental impact assessment, and urban planning.

Mapping urban resources and vulnerabilities.

VII. Policy, Economics & Social Aspects

Green Building Certifications & Standards:

LEED, BREEAM, WELL, Passivhaus, and other rating systems.

Development of new performance-based standards.

Sustainable Urban Planning & Policy:

Integration of sustainable principles into urban master plans and zoning regulations.

Incentives and regulatory frameworks for green building and infrastructure.

Life Cycle Assessment (LCA) & Life Cycle Costing (LCC):

Methodologies for evaluating environmental and economic impacts over the entire lifespan of a project.

Socio-Economic Impacts of Sustainable Construction:

Job creation, local economic benefits, and community engagement.

Affordable green housing and equitable access to sustainable infrastructure.

Education & Training for Sustainable Practices:

Curriculum development for civil and architectural engineers in sustainability.

Workforce development for green construction jobs.

Financing Green Projects:

Green bonds, sustainable investment, and public-private partnerships.