1) Pure diffusion equation
.Concepts and definitions
.Dimensional analysis and Pi-theorem
.Fickian diffusion
.Formal derivation of the pure diffusion equation
.Self-similar solution of the 1d pure diffusion equation.

2) Advection diffusion equation (ADE)
.Concepts and definitions
.Heuristic derivation of the ADE
.Formal derivation of the ADE
.Analytical solutions for the advection diffusion equation
.Definition and physical meaning of the main non-dimensional governing parameters

3) Turbulent diffusion and advection dispersion equation
.Turbulence: main concepts
.Derivation of the turbulent ADE
. Turbulent diffusion coefficients: longitudinal, vertical e transversal
.Derivation of the advection dispersion equation (Taylor approach)

4) Advection diffusion equation with reactions
.Concepts and definitions
.Chemical kinetics: concepts
. First order reactions
.Second and higher order reactions
.Derivation of the advection diffusion reaction equation (homogeneous and heterogeneous reactions)

5) Atmospheric mixing
.Concepts and definitions
.Turbulence in the atmospheric boundary layer
. Turbulent ADE in 3D
. Derivation of the solution for the steady Gaussian plume

6) Mixing in estuaries
.Concepts and definitions
.Taylor-Aris dispersion: Asymptotic analysis derivation
.Turbulent flows in estuaries
.The turbulent kinetic energy equation for estuarine flows
.Stratification: Brunt-Vaisala frequency and Richardson number

8) Numerical solution to the ADE with applications
.Concepts and definitions
.Finite difference method
. Accuracy of a numerical scheme with the modified wavenumber approach
. Taylor table method
.Stability, accuracy and consistency
. FTCS scheme for ADE
.Von Neumann analysis
.Upwind schemes

1) Special topics in Mixing and Transport Processes in the Environment, S. Socolofsky and G. Jirka
2) Chemical fate and transport in the environment, HF Hemond, EJ Fechner
3) Mechanics of coastal sediment transport, J. Fredsoe and R. Deigaard

- Turbulence in Ocean: an introduction

- Stratification and the Brunt Vaisala frequency

- Turbulence characteristics

-Kolmogorov Theory

- The turbulent kinetic energy equation

- Turublence in the oceanic boundary layers

- Turbulence in the pycnocline : K-H instabilities

- Turbulent jets in ocean

- A. Cenedese, 2006, Meccanica dei fluidi ambientale, Mc Graw-Hill.
- B. Cushman-Roisin, 1994, Introduction to Geophysical Fluid Dynamics, Prentice Hall.

Governing equations for viscous and turbulent flows
Viscous flows and Navier-Stokes equations, turbulent flows and Reynolds equations.

Governing equations for rotating flows
Rotating framework of reference, Unimportance of the centrifugal force, Acceleration on a three-dimensional rotating planet, Equations of Fluid Motion (Mass budget , Momentum budget, Equation of state, Energy budget, Salt and moisture budgets) Boussinesq approximation, Scales of motion, Important dimensionless numbers, Boundary conditions.

Rotation effects
Geostrophic flows and vorticity dynamics, cyclonic and anticyclonic flows, the bottom Ekman layer and the surface Ekman layer.

Ocean
Oceanic General Circulation; What drives the oceanic circulation; Large-scale ocean dynamics (Sverdrup dynamics). Western boundary currents. Thermohaline circulation; Abyssal circulation;

Atmosphere: generalities (structure and physical characteristics), definition of standard atmosphere and standard lapse rate. Atmospheric stability: dry and wet adiabatic lapse rate and atmospheric stability, conditional stability. Planetary Heat Budget.

Large scale Dynamics in atmosphere: Generalities(main sources of global scale circulation, effects of the Coriolis forces, direct and indirect cells, prevailing winds). Governing equations for large scale dynamics in atmosphere. Thermal wind relation, large-scale circulation in Hadley and Ferrel cells (theoretical analysis).

The Atmospheric Boundary Layer (ABL): generalities and definitions. Turbulent phenomena in the ABL: Mechanical and thermal turbulence, the turbulent cascade, statistical approach to turbulence in ABL (turbulence intensity and turbulent fluxes). The Turbulent kinetic equation, analysis of atmospheric stability from the vertical turbulent flux of temperature. Closure relations: local closures and K-theory, zeroth order closures based on similarity theory. Definition of the main length, time and velocity scales in ABL flows. Vertical structure of the boundary layer. Derivation of the potential temperature from the 1st law of thermodynamics. Day-night cycles of ABL in fair weather conditions. Dynamical Evolution of the ABL: entrainment zone, daily variation of the entrainment zone. Cloud-topped boundary layer overland.

Anabatic and katabatic winds. Hydrodynamic phenomena in presence of synoptic scale forcing.

Cloud physics: Generalities and definitions on cloud and rain droplets. Main Mechanisms for rain formation. Effect of curvature on condensation and evaporation (Kelvin theory). Solute effect on rain formation (Raoult's Law). Köhler theory and formation conditions for a rain droplet. Vapor deposition and early-stage growth of cloud condensation nuclei.

- A. Cenedese, 2006, Meccanica dei fluidi ambientale, Mc Graw-Hill.
- B. Cushman-Roisin, 1994, Introduction to Geophysical Fluid Dynamics, Prentice Hall.

1-Introduction to programming in Matlab
2-Ordinary differential equations
3-Partial differential equations
4-CFD for maritime hydraulics

-Lecture notes
-Chapra S., 2018. Applied Numerical Methods with MATLAB for Engineers and Scientists, 4th Edition, McGrawHill Education.
-Chapra S., Canale R., 2015. Numerical Methods for Engineers 7th Edition, McGrawHill Education.

Ordinary Differential Equations: Initial Values (ODE IV)
Ordinary Differential Equations: Boundary Values (ODE BV)
Partial Differential Equations (PDE)
Elements of computational fluid dynamics (CFD): OpenFOAM

1: Hydrology and global water cycle
2: Precipitation
3: Evapotranspiration
4: Runoff generation
5: Rainfall-runoff modeling
6: Flood routing
7: Estuaries and estuarine physics
8: Tidal analysis

Dingman, S.L. (2015). Physical Hydrology, Third Edition. Waveland Press, Long Grove, Illinois
Kovalik Z., Luick J.L. (2019). MODERN THEORY AND PRACTICE OF TIDE ANALYSIS AND TIDAL POWER. Austides Consulting, Australia.
Parker, B. B. (2007). Tidal analysis and prediction. NOAA

1. Water flow in saturated media; saturated and unsaturated media; conceptual model; types of aquifers; fundamental equations, solutions; scale problem; Dupuit approximation; regional scale equations
2. Water flow in saturated media: Regional-scale equations; boundary conditions; modeling protocol; Wells
3. Supply from wells; well hydraulics; Methods of estimating hydrogeological parameters; groundwater pumping tests; flow in unsaturated media: flow equations; pedofunctions;
4. Flow in unsaturated media: loss analysis; calculation of infiltration
5. Introduction to MODFLOW and MODELMUSE: installation, basic operation
6. Examples: coastal aquifer, boundary conditions: constant head, general head Boundary, packages: lateral recharge, rain, wells, river

Handsout by the lecturer

Tide and tidal analysis.
Sea level measurements systems.
Equilibrium theory of the tides.
Dynamical theory of the tides.
Harmonic analysis of the tides.

Lecture notes.
Book Kowalik & Luick "MODERN THEORY AND PRACTICE OF TIDE ANALYSIS AND TIDAL POWER"

1. Introduction to the contamination problem, Contaminant Classification
2. Basic transport mechanisms in GW - ADE
3. Introduction to reactive transport, Sorbing solutes
4. Multi-Phase Flow, NAPL
5. Remediation techniques

6. Coastal GW systems, seawater intrusion
7. Governing equation (variable density flow)
8. SWI approach, analytical solution, application examples
9. Land reclamation introduction and application example with SWI solutions

Contaminant Hydrogeology
C.W. Fetter, Prentice Hall, Upper Saddle River, N.J., 1999.
ISBN 10: 0137512155 / ISBN 13: 9780137512157


Coastal Hydrogeology
J. Jiao, V. Post, Cambridge University Press, New York, NY, 2019
ISBN: 978-1-107-03059-6

Topics covered in the course

Basics of thermodynamics, heat transmission, acoustics and lighting.
Sustainable movement, population and prosperity, climate change, comparison between energy efficiency and renewable energy, renewable and non-renewable energy resources, basic theory of the atmosphere, adiabatic temperature gradient.
Introduction to the concept of sustainability: history of sustainability and sustainable development, the pillars of sustainability and the 2030 Agenda.
Environmental sustainability indicators: general information, PSR and DPISR models, common European indicators, Global Warming Potential and CO2 equivalent. Ecological Footprint, Carbon Footprint, Life Cycle Analysis, Water Footprint.
Environmental impact of energy systems: types of polluting emissions, main smoke treatment techniques and environmental impacts of renewable energy technologies.
Global pollution phenomena: acid rain, ozone and the greenhouse effect.
Environmental impact assessment: legislation, procedures, methodologies, contents and phases.
Air pollution, noise pollution, thermal pollution, light pollution and pollution of the seas.
Green Buildings.
Sustainable energy: energy from the sun, energy from the wind, energy from the sea, energy from the earth and biomass.

Educational material provided by the professor

Introduction of the Course
History of Coastal Engineering
Basic concepts of maritime hydraulics and coastal structures
Design of maritime structures
Wave theories (Stokes theory, long wave theory, etc.)
Results of the linear theory
Exercise: Meteocen study (regime)
Exercise: Meteocen study (extremes)
Exercise: Design of maritime structures
Exercise: Numerical modelling of wave propagation (SWAN)
Design of wave energy conversion (WEC)
Coastal hydrodynamics and morphodynamics

Lecture notes.
Book Svendsen "Introduction to nearshore hydrodynamics"
Book Holthuijsen "Waves in Oceanic and Coastal Waters"

Introduction of the Course
History of Coastal Engineering
Basic concepts of maritime hydraulics and coastal structures
Design of maritime structures
Wave theories (Stokes theory, long wave theory, etc.)
Results of the linear theory
Exercise: Meteocean study (regime)
Exercise: Meteocean study (extremes)
Exercise: Design of maritime structures
Exercise: Numerical modelling of wave propagation (SWAN)
Design of wave energy conversion (WEC)
Coastal hydrodynamics and morphodynamics

Lecture notes by prof.Noli and prof.Franco

Introduction of the Course
History of Coastal Engineering
Basic concepts of maritime hydraulics and coastal structures
Design of maritime structures
Wave theories (Stokes theory, long wave theory, etc.)
Results of the linear theory
Exercise: Meteocen study (regime)
Exercise: Meteocen study (extremes)
Exercise: Design of maritime structures
Exercise: Numerical modelling of wave propagation (SWAN)
Design of wave energy conversion (WEC)
Coastal hydrodynamics and morphodynamics

Overview of transportation engineering with an in-depth analysis on maritime transportation
- Transportation supply models
o Study area
o Zoning
o Graph
- Transportation demand models
o Generation model
o Attraction model
o Distribution model and matrix squaring
- Interaction models of supply and demand
o Assignment models
- Transportation system of access to maritime infrastructure
o Passenger and freight accessibility
- Logistics
o Logistics system
o Logistics platforms
- Types of maritime transport vehicles
o Vessel classification
o Vessel characteristics
o Vessel descriptions
- Types of shipping services:
o Active subjects
o Scheduled or on-demand services
o Hub & spoke - Point-to-Point
o Transhipment models
o Costs
- Intermodal Transportation
o Road-Rail / Road-Sea / Sea-Sea
o Containers and other types of cargo units for intermodal transportation
- Constituent Elements and Modes of Operation of Ports
o Layout of ports
o Elements of ports
o Vehicular movements in ports
o Types of handling equipment
o Port terminals
o Focus on container/ro-ro/ro-pax terminals
- Maritime routes
o Routes and navigation
o Highways of the sea
- Gigantism
o Ships and ports
o Italian ports
- Environmental impact of shipping
o Emissions by vessel type in port and during navigation
- Port infrastructure performance
o KPIs by Port, Terminal and Vessel
- Information technology tools for transport data analysis

Handouts and Slides provided by the Professor

- Overview of transportation engineering with an in-depth analysis on maritime transportation
- Transportation supply models
o Study area
o Zoning
o Graph
- Transportation demand models
o Generation model
o Attraction model
o Distribution model and matrix squaring
- Interaction models of supply and demand
o Assignment models
- Transportation system of access to maritime infrastructure
o Passenger and freight accessibility
- Logistics
o Logistics system
o Logistics platforms
- Types of maritime transport vehicles
o Vessel classification
o Vessel characteristics
o Vessel descriptions
- Types of shipping services:
o Active subjects
o Scheduled or on-demand services
o Hub & spoke - Point-to-Point
o Transhipment models
o Costs
- Intermodal Transportation:
o Road-Rail / Road-Sea / Sea-Sea
o Containers and other types of cargo units for intermodal transportation
- Constituent Elements and Modes of Operation of Ports
o Layout of ports
o Elements of ports
o Vehicular movements in ports
o Types of handling equipment
o Port terminals
o Focus on container/ro-ro/ro-pax terminals
- Maritime routes
o Routes and navigation
o Highways of the sea
- Gigantism
o Ships and ports
o Italian ports
- Environmental impact of shipping
o Emissions by vessel type in port and during navigation
- Port infrastructure performance
o KPIs by Port, Terminal and Vessel
- Information technology tools for transport data analysis

Lecture notes provided by the professor.

0 Introduction
1 Course content
2 Transportation supply model
3 Transportation demand model
4 & 5 Models based on regression analysis - Calibration of Regression Models + Ex
6 Distributional models
7 Transportation assignment model
8 & 9 Logistic system
10 Accessibility to maritime infrastructures
2 Sea-land transportation
3 & 4 Roads & Railways
5 Equations of motion
6 Applcation of motion eqq.
7 & 8 H and V alignment & project examples 1/2
9 project examples 2/2
10 lateral dynamic equilibrium
11 & 12 curve in railway
11 Maritime transport vehicles
12 Maritime transport services
13 & 14 Intermodal transport of goods by sea with description of loading units and handling units
15 Main characteristics, components and modes of operation of ports and cargo terminals
16 Container/ro-ro/ro-pax terminal
17 & 18 Advanced data collection and utilization techniques for transportation engineering
19 Port Infrastructure Performance: KPIs for Port, Terminal, and Ship
20 Tools for transport data analysis: (exercise with GPS data)
21 & 22 Discrete event simulation for port handling representation
23 Maritime routes and navigation
24 Gigantism - Italian ports
25 & 26 Environmental impact of maritime transportation
27 Italian and European projects - Masterplan example
13 layout of ports, masterplan and infrastructures
14 & 15 special areas & intersections
16 pavement
17 railway superstructure
18 & 19 soil stabilization & examples

20 summary, discussion and questions
21 & 22 seminar on Port of Genoa
23 seminar on remote sensing and applications
24 seminar on data fusion and application
25 & 26 seminar on BIM

papers and documents given by professors

TOPIC 1 - DESIGN: SUSTAINABILITY IN CIVIL ENGINEERING
Part 1 - SUSTAINABILITY IN CIVIL ENGINEERING
- Introduction sustainability in Civil Engineering
- The Triple Bottom Line: Environmental, social and economic pillars
o Brief introduction
o Economic Pillar
o Social Pillar
o Environmental pillar
 Ecological footprint
 Planet Boundary
 Life cycle assessment
- Sustainable strategies
o Recycled content
o Local sourcing and local manufacturing
o Durability and reduced maintenance
o Design for adaptability and deconstruction
o Reuse of buildings, structural components, and non-building structures
o Structural Materials and Toxicity
o Life cycle assessment (in brief)
Part 2 - LIFE CYCLE ASSESSMENT (LCA)
- Theory
- Applications
- Exercises
Part 3 - SUSTAINABILITY OF BUILDING MATERIALS
- Materials introduction
- Masonry
- Steel
- Wood
- Natural building materials and systems
- Concrete

TOPIC 2 - DESIGN: SUSTAINABILITY/DURABILITY OF CONCRETE
Part 1 - CONCRETE MATERIAL
- Concrete: basic theory on composition, mechanical properties of fresh and hardened concrete, classification
- Steel reinforcement in reinforced concrete
Part 2 – SUSTAINABILITY OF CONCRETE
- The sustainability benefits of concrete structures
- Durability and maintenance: general concepts

Part 3 - DURABILITY OF CONCRETE
- Deterioration and durability of reinforced concrete structures
- Degradation phenomena and mechanisms
- Design strategies for durability (part 1): Exposure classes, concrete cover design
- Design strategies for durability (part 2): Mix design of concrete
- Exercises on concrete cover design and concrete mix design
- Inspection, diagnosis and restoration of concrete structures

Part 4 - NEW STRATEGIES FOR CONCRETE DURABILITY
- Coatings and waterproofing, corrosion inhibitors
- Coated steel, stainless steel and FRP reinforcement
- Special concretes:
o (Ultra) High performance concrete (HPC/UHPC)
o Geopolymer concrete
o Fibre-reinforced concrete (FRC)
o Underwater concretes (beSub)
o 3-SC concretes (3-self concrete)
o Self-repairing/self-healing concretes
- Digital concrete (3D printed concrete)
- Concrete structures reinforced with FRP rebars
- Exercises

TOPIC 3 - RETROFITTING: SUSTAINABLE MANAGEMENT OF THE BUILT HERITAGE
Part 1 - FABRIC REINFORCED CEMENTITIOUS MATRIX (FRCM) COMPOSITES
- History
- Brief application examples
- Constituent materials
- Mechanical properties
- Acceptance criteria

Part 2 – FRCM-STRENGTHENED CONCRETE STRUCTURES
- Design of flexural and shear FRCM reinforcement: theory
- Design of flexural and shear FRCM reinforcement: exercises

SUSTAINABLE STRUCTURAL DESIGN: Sustainability
- Fundamentals of Sustainability in Civil Engineering - A. Braham
- Life Cycle Assessment in the Built Environment - R.H. Crawford
- Environmental Life Cycle Assessment -Taylor & Francis Group, 2016
- Sustainable Construction Techniques – Detail Green Books, 2015
SUSTAINABLE STRUCTURAL DESIGN: Sustainability/Durability of Concrete
- Teoria e Tecnica delle Costruzioni Civili – R. Giannini, CittàStudi, 2011
- Il restauro dell’architettura moderna in cemento armato – L. Coppola, A. Buoso, Hoepli, 2015
- Materiali per l’edilizia: Una guida ai materiali strutturali, ausiliari e di rivestimento – G. Frigione, N. Mairo, Hoepli, 2010
- La durabilità del calcestruzzo armato – P. Pedeferri, L. Bertolini, McGraw-Hill, 2000
- Reinforced concrete with FRP bars: mechanics and design – A. Nanni, A. De Luca, H. J. Zadeh, CRC Press, 2014
RETROFITTING
- Consolidamento delle Strutture – M.A. Pisani, S. Cattaneo, T. D’Antino, Hoepli Editore, 2019

Presentation of the Course, Introduction and Definitions
Port design
Meteocean analysis for port design
Port layouts and check-lists
Commercial ships and management
Navigation channels
Nautical cartography
Port silting
Numerical modelling for wave propagation and penetration (SWAN + FIDELL)
Dry bulk terminals
Container terminals
Project tasks (subdivision in groups)
Review activity of the projects

Lecture notes.
Book THORESEN "Port Design Handbook".

Presentation of the Course, Introduction and Definitions
Port design
Meteocean analysis for port design
Port layouts and check-lists
Commercial ships and management
Navigation channels
Nautical cartography
Port silting
Numerical modelling for wave propagation and penetration (SWAN + FIDELL)
Dry bulk terminals
Container terminals
Project tasks (subdivision in groups)
Review activity of the projects

lecture notes prof.Noli and prof.Franco