COURSE DESCRIPTION:

Physics course outline: (First Semester, First Year)

Introduction to Environmental Studies. The relationship between physics and environmental studies (basic understanding of the phenomena - pollutant monitoring). Modern perceptions of the Universe ('Big Bang' Theory). Basic concepts (system-environment, biosphere (ecological and social systems), energy mass, evolution rates, environmental degradation). Principles of the nuclear theory (electromagnetic nature of matter, Thomson, Millikan, Rutherford experiments, nucleus nature, size, form, mass & division, Rutherford atom theory). Principles of Quantum mechanics (quanta, photoelectrical phenomena, emission and absorption spectra, wave particles, Heisenberg Principle of Uncertainty, Schroedinger equation, quantum numbers). Thermodynamics - Statistical mechanics (laws of thermodynamics, temperature, heat and work, thermodynamic processes, rates of heat transfer, gas kinetic theory, molecular explanation of temperature and pressure, molecular thermal capacity of noble gases, molecular speed distribution, entropy in reversible and irreversible processes, environmental applications).

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Introduction to Environmental Engineering

Historical Overview - Mass balances with conservative and non-conservative chemical species - Energy balances - Combined energy and mass balances - Heat transport - Population prediction models - Depletion of non-renewable natural resources - Microbial population growth models - Human population pyramids - Hazardous substances, risk assessment. Air pollution. Pollutant dispersion in the atmosphere. Water pollution (surface waters, groundwater). Soil contamination, types of soils, soil erosion, fertilizers, pesticides. Water and wastewater management, drinking water quality and wastewater treatment systems. Solid waste management, classification of waste, treatment and final disposal techniques.

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Environmental Physics: Radiation

Electromagnetic radiation (nature, sources, emission spectrum, interaction between materials and radiation). Ionizing radiation (Natural and anthropogenic radiation, radon, dosimetry, protection and auditing principles, measurement devices). Ultraviolet, visible and infrared radiation (characteristics, measurement devices, biological effects). Cohesive light (Lasers) Microwaves, radiofrequencies and exceptionally low frequencies (General Principles, measuring units, Sources and Exposure. measurement devices, Risk, Dosimetry).

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Aquatic Chemistry

Structure and properties of water. Composition of various types of water. Chemical balances (kinetic and thermodynamic methods). Aquatic solutions, Ionic strength of solutions. Concentration and activity of solutions. Mathematic modeling of aquatic systems. Graphical techniques for problem-solving (pC-pH diagrams). Types of acids and bases. neutralization of acid-bases. Titration Curves. Buffering solutions. Water - Gas partitioning systems. Alkalinity and acidity. Water - solid partitioning systems. Solid - water - gas partitioning systems. Carbonic systems (closed and open). Complex chemical species, Distribution diagrams for complex chemical species. Solubility constants. Redox reactions and equations (pC-pε and pε-pH diagrams).

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Solid and Hazardous Waste Management

Waste management systems (WMS) - strategies in integrated waste management. Waste generation. Storage, collection and waste transportation. Treatment Processes. Material and energy recovery. Final disposal of solid and hazardous wastes. Landfill Design (siting, design, construction). Leachate collection and treatment. Biogas management. Landfill Operation monitoring, Remediation of old Landfill Sites and final uses. Post-closure monitoring, WMS design. Legislation and management authorities.

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Environmental Hydrogeology

Fundamental concepts of the hydrologic cycle. Natural materials and processes, types of aquifers, groundwater storage and transportation parameters, Darcy's Law, hydraulic conductivity, transmissivity and storativity, mean linear velocity and specific discharge, hydraulic conductivity, aquifer vulnerability, pumping methods used to estimate aquifer properties, main sources of ground water contamination, laws of pollutant transport in porous media, advection and diffusion/dispersion laws, geological and hydrogeological parameters accounted for during landfill siting, modeling of groundwater and contaminant movement, remediation and monitoring of contaminated groundwater.

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Environmental Geology 

Fundamental concepts, earth materials and processes (geologic cycle, minerals, rocks, soils, water, wind and ice), river flooding, landslides and related phenomena, earthquakes and related phenomena, volcanic activity, land waste disposal, mineral resources and environment.

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Resource management and Waste I

Fundamental resource (air, water, soil, energy) and waste (gas, water, solids, energy) characteristics, Management strategies (prevention, recycling, treatment, disposal), Integrated management systems, Quantitative and qualitative characteristics of resources and waste, System monitoring programs, Data collection and processing, Problem specification/definition in existing resource and waste management systems (gases, sewage, refuse etc.) Resource and waste management case studies in islands of the Aegean Sea.

Methods for Eco-efficiency

Fundamental concepts: "Integrated Management", "Cleaner Technology", "Cleaner Production", "Organic and 'Eco' Products", "Eco-efficiency" and "Eco-performance". Methodological tools: Environmental Management Systems (EMS), Life cycle analysis (LCA). European Union Certification institutions: (EMAS) Environmental Management and Auditing System) for production plants, EU Eco-labeling for various products, ISO 14000 (International certification for production plants and products).

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