12th BUDAPEST International Conference on Science, Engineering, Technology & Natural Resources: SETNR-27a

Call for papers/Topics

All Abstracts, Reviews, short articles, Full articles, Posters are welcomed related with any of the following research fields:

Part 1: Foundational & Independent Pillars

These topics represent the core, traditional branches of each distinct discipline.

1. Pure and Applied Sciences

The systemic study of the structure and behavior of the physical and natural world through observation and experiment.

  • Physical Sciences: Classical mechanics, thermodynamics, electromagnetism, quantum mechanics, and organic/inorganic chemistry.

  • Earth and Space Sciences: Geology, meteorology, oceanography, astronomy, and planetary science.

  • Formal Sciences: Pure mathematics, theoretical statistics, logic, and game theory.

2. Core Engineering Disciplines

The application of scientific and mathematical principles to design, build, and maintain structures, machines, and systems.

  • Civil and Structural Engineering: Mechanics of materials, structural analysis, geotechnical engineering, and transportation systems.

  • Mechanical Engineering: Fluid mechanics, kinematics, machine design, heat transfer, and manufacturing processes.

  • Electrical Engineering: Circuit theory, power systems, signal processing, and electromagnetic fields.

  • Chemical Engineering: Mass transfer, chemical kinetics, separation processes, and thermodynamics.

3. Information and Digital Technology

The development, maintenance, and use of computer systems, software, and networks for processing and distributing data.

  • Software Engineering: Object-oriented programming, software architecture, algorithm design, and database management systems.

  • Network Technology: Routing protocols, wireless communication, cloud architecture, and cybersecurity principles.

  • Hardware Systems: Computer architecture, microprocessors, and embedded systems logic.

4. Natural Resources Management

The stewardship of naturally occurring substances that are valuable to humans.

  • Geological Resources: Mineral exploration, ore extraction methods, and fossil fuel reservoir management.

  • Hydrological Resources: Watershed management, groundwater hydrology, and freshwater supply management.

  • Biological and Land Resources: Forestry management, soil science, agricultural land allocation, and wildlife conservation.

Part 2: Interrelated & Convergent Fields

These multidisciplinary fields occur where science, engineering, technology, and natural resources overlap to drive innovation and sustainability.

1. Materials Science and Nanotechnology

The intersection of chemistry, physics, and mechanical/chemical engineering to manipulate matter at the atomic scale.

  • Advanced Materials: Development of superconductors, smart polymers, and biomimetic materials.

  • Nanomaterials: Synthesis of graphene, carbon nanotubes, and quantum dots for industrial application.

  • Structural Characterization: Electron microscopy, X-ray diffraction, and spectroscopy.

2. Environmental Engineering and Sustainability Science

The integration of ecological science, civil engineering, and natural resource management to protect human health and ecosystems.

  • Waste Management: Wastewater treatment processing, hazardous waste remediation, and solid waste engineering.

  • Renewable Energy Systems: Engineering and scaling solar photovoltaic, wind turbine, geothermal, and hydroelectric energy.

  • Climate Mitigation Technology: Carbon capture and storage (CCS), grid-scale energy storage, and life-cycle sustainability assessments.

3. Automation, Robotics, and Smart Systems

The convergence of mechanical engineering, electrical engineering, and advanced software technology.

  • Robotic Systems: Mechatronics, kinesthesis, autonomous navigation, and computer vision systems.

  • Industrial Automation: Programmable Logic Controllers (PLCs), supervisory control and data acquisition (SCADA), and smart manufacturing.

  • Internet of Things (IoT): Sensor networks, edge computing, and smart infrastructure (smart grids, smart cities).

4. Artificial Intelligence and Data Engineering

The application of formal sciences (math/statistics) and computational technology to process massive datasets and simulate intelligence.

  • Machine Learning and Deep Learning: Neural networks, natural language processing, predictive analytics, and computer vision.

  • Big Data Infrastructure: Distributed computing frameworks, data warehousing, and real-time data streaming pipeline design.

  • Computational Modeling: Simulation of complex natural resource systems, climate projections, and engineering stress tests.

5. Geoinformatics and Resource Technology

The use of digital technology and engineering to map, monitor, and manage the Earth's natural resources.

  • Remote Sensing: Satellite imagery analysis, LiDAR mapping, and drone-based environmental monitoring.

  • Geographic Information Systems (GIS): Spatial data modeling, cartographic visualization, and land-use planning analytics.

  • Precision Extraction: Automated mining technology, smart agriculture (targeted irrigation and fertilization), and digital oilfield management

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