ENVIROMENTAL MATHEMATICAL MODELS

Single discipline educational activity

Course Sheet

Course code:

GE216

Academic Year of enrolment:

2019

Year of supply:

2020/2021

Type of Course:

Elective Course

Degree:

Course of 2nd Cycle Degree in GEOLOGICAL SCIENCES AND TECHNOLOGIES OF EARTH AND PLANETS

Disciplinary Sector:

Applied Geology

Location:

CHIETI

Credits:

Programme Year:

Professor and Collaborators:

PASCULLI Antonio

Cycle:

First semester

Hours of classroom activity:

Individual study hours:

Prerequisites:

Prerequisites: Knowledge of basic mathematics and physics applied to
Geology and the Environment System; propaedeutic are not foreseen.

Objectives

Educational goals:
The course provides the formal tools necessary to interact with different
operators, such as engineers and geologists involved both in the field of
research and in the professional field. The preparation achieved with this
course will allow graduates to work in different fields of geological
activities for which, in addition to basic geological skills, the use of
mathematical, numerical and computer techniques is also required. In
particular, the course prepares, among others, for the following activities:
-the use of Finite Element Method (F.E.M.) and Finite Difference Method
(F.D.M.) computer codes; -characterization of aquifers and modeling of
underground drainage problems, propagation of contaminants, infiltration
and filtration; -consolidation analysis; -analysis, prevention and mitigation
of geological, hydrogeological and environmental risks, such as
landslides, debris flow, floods; -data analysis through numerical filters,
Fourier Analysis and Transform; -exploration of hydrocarbons and
production support; -geognostic and geophysical surveys for the
exploration of the subsoil and geological studies applied to civil
engineering works; -sismology and study of earthquakes; -Science of
materials, by means of quantum mechanics.

Contents

Content: Computer programs are fundamental tools in all activities that
require quantitative responses, particularly for the environment system.
Their use presupposes the knowledge of all the characteristics of the
system and of the phenomena to be studied (Physics, Chemistry,
Geology, Mechanics). However, the implemented models are only an
interpretation of reality. Therefore, for their correct use, it is necessary to
know the characteristics of the main exploited mathematical models,
their numerical realization and the conditions under which they can
provide useful informations. The course describes the fundamental bases
on which the main used models have been developed to study
environmental phenomena, such as seismic, geophysics, transport and
diffusion of substances, fluvial dynamics, filtration, debris-flow,
consolidation and other. Therefore matrix algebra, the main differential
equations based on mass conservation, momentum (Navier-Stokes Eq.),
Energy, the main methods of numerical modeling (Finite Element
Method), Fourier Expansion and Fourier Transform are studied and more.
Introduction to the use of the RiverFlow2D code.

Extended Syllabus

Full detailed program:
1.0 General principles of mathematical modeling.
1.1 Complex numbers and vector quantities.
1.2 Cartesian, cylindrical and spherical orthogonal coordinates. Change of
coordinates: "Jacobian". Angles of Euler.
1.3 Matrix Calculation; search for main components (eigenvalues,
eigenvectors); notes on the Tensors; rigid roto-translations and
associated matrix, as an operator
1.4 Elements of analytical geometry.
1.5 Taylor series expansion. Notes on differential geometry; concept of
curvature of a line and of a surface (applications to slopes and to
capillary phenomena).
1.6 Introduction to differential Operators: gradient with symbolic
calculation; divergence, rotor and their physical meaning; Theorems of
Green-Gauss and Stokes.
1.7 Gamma, Dirac and Heaviside Functions; derivatives of discontinuous
functions.
1.8 "Material" derivative; physical meaning of partial and total derivative
with respect to time; derivative of a vector with respect to the time:
Poisson formulas; derivative of an integral; notes on fractional
derivatives.
1.9 General definitions of differential equations; Ordinary Differential
Equations; Partial Differential Equations.
1.10 Overview of the Minimum Principles and Elements of Variational
Calculus; Example of a vibrating bar.
1.11 Meaning and usefulness of the expansion in series of functions:
introductory concepts on Hilbert Spaces as formal bases for the use of
orthogonal functions expansion (Fourier).
2.0 Models related to static equilibrium (processes independent of time).
3.0 Dynamic models (processes that evolve over time).
3.1 General form of the balance equation of scalar, vectorial and tensorquantities and equations derived from it, by means of experimental laws
(reasons for which a mathematical model may or may not provide useful
information):
3.1.1 Diffusion of a substance in a non-moving medium (Fick's laws);
3.1.2 Diffusion of a substance in a moving medium: advective equation;
3.1.3 Dynamic equation (Cauchy-Beltrami) for slope stability analysis;
3.1.4 Equations of heat exchange (Fourier Law): conduction and
convection;
3.1.5 Wave equation; discrete model and continuous model;
3.1.6 Navier Stokes equation;
3.1.7 Equations of seismic perturbations propagation.
3.2 Application of the Navier Stokes equation to justify Darcy's law.
3.3 Reynolds dynamic equation.
3.4 Equation of water and air infiltration in unsaturated soil (Richards,
Fokker-Plank)
3.5 Overview of the Law of Consolidation of Biot in 2D and 3D.
3.6 Overview of the "debris flow" equations and of the Shallow Water
model.
3.7 Notes on models pertaining to Geophysics investigation techniques
using geoelectric, geomagnetic and georadar methods; interaction of
electromagnetic waves with matter.
4.0 Dimensional analysis: Reynolds, Froude, Rayleigh, Grashov numbers.
5.0 Overview of Earth's electromagnetism.
6.0 Analytical aspects of a mathematical model expressed by differential
equations.
7.0 General approach on the correct setting of a mathematical model by
means of differential equations; Notes on the stability of differential
equations and on the mathematical theory of the Stability of Dynamical
systems.
8.0 Notes on the methods of analytical solution of the main Ordinary and
Partial differential equations related to Geology and Environmental
Modeling:
8.1 Partial Differential Equations:
8.1.1 Method of the variable separation. Solution of the following
equations:
8.1.1.1 Solution of the diffusion equation;
8.1.1.2 Solution of the equation of forced oscillations of discrete systems;
8.1.1.3 Solution of the wave equation (seismic, electromagnetic);
8.1.1.4 Solution of the Consolidation equation;
8.1.1.5 Solution of the vibration equation of a one-dimensional bar;
8.1.1.6 Solution of the vibration equation of a membrane; Expansion of
solutions into eigenfunctions with their eigenvalues;
8.1.1.7 Solution of the telegraphic equation;
8.1.1.8 Sturm_Liouville problem and expansion in orthogonal Fourier
functions (trigonometric, Bessel, Hankel, Legendre, Chebyshev-Hermite,
Chebyshev-Laguerre);
8.1.1.9 Solution of Schrodinger Equation for the hydrogen atom;
8.1.1.10 Fokker Plank Equation.
9.0 Method of the Transforms: Fourier and Laplace.
10.0 Interpolation of numerical data: Lagrange, Hermite polynomial,
spline, serendipity.
11.0 Elements of statistics and probability calculation in Geology and
Environmental Engineering:
11.1 Inequality of Chebyshev;
11.2 Overview of the theory of errors and the problem of experimental
measurement;
11.3 Basics of Probability Calculation (Binomial or Bernoulli Distribution,
Poisson Distribution, Normal or Gauss Distribution or Error Distribution,
Standard Normal Distribution, Lognormal Probability Distribution, Weibull
probability distribution;
11.4 Multivariate Analysis;
11.5 Verification of a statistical hypothesis;
11.5.1 Example 1: statistical analysis of the belonging of rock samples to
a specific site, based on the measurement of porosity;
11.5.2 Example 2: Membership of a statistical sample at a given
Distribution; analysis of the randomness of the concentration values of a
pollution emitted into the sea by a river.
12.0 Processing of observation data:12.1 Least square methods;
12.2 Fourier analysis with applications;
12.3 Analysis of numerical data using the FFT (Fast Fourier Transform)
method;
13.0 General principles of numerical calculus:
13.1 Evaluation of truncation and rounding errors and their propagation;
13.2 Overview of the numerical analysis of seismic data:
13.2.1 Application of the "Fast Fourier Transform";
13.2.2 Numerical filters;
13.3 Solution of linear and non-linear systems (concepts and general
definitions):
13.3.1 Method of conjugate or Cholesky gradient;
13.3.2 Solution of non-linear systems (Newton Rapshon method);
13.4 Numerical integration of differential equations:
13.4.1 Overview of the Mesh-less Method;
13.4.2 Finite difference method;
13.4.3 Finite element method (F.E.M.);
13.4.4 Numerical solution of time-dependent problems;
13.4.5 Comparison of methods.
13.5 Numerical modeling of pollution of a wetland under stationary
conditions by means of the Finite Element Method;
13.6 Examples of routines in FORTRAN95 language.

Recommended Bibliography

Reference Text: Course-pack, slides, scientific articles indicated and
distributed by the teacher. Furthermore the following texts with advanced
discussion: Gambolati G.-Elementi di Calcolo Numerico – Edizioni Libreria
Cortina – Padova 1992. Tichonov A. N., Samarskij A. A. - Equazioni della
Fisica Matematica - Edizioni Mir 1981. Dettman John W. – Mathematical
Methods in Physics and Engineering – Dover Publications, Inc. 1988. Graffi
Dario - Elementi di Meccanica Razionale - Casa Editrice Patròn Bologna
1970. Kahn Peter B. - Mathematical Methods for Scientists &Engineers
(Linear and Nonlinear Systems) - John Wiley &Sons 1990. Strang Gilbert -
Introduction to Applied Mathematics - Wellesley-Cambridge Press (M.I.T.)
1986.

Teaching Methods

Teaching methods: Classroom lectures, with active involvement of
students in order to encourage curiosity and spirit of investigation;
exercises.

Evaluation methods

Verification of learning:

Modality of learning proof: Written and oral exam. The written test
consists of exercises and open questions. The oral exam consists in the
discussion of the written test with extension on the whole program. The
final grade will include the evaluation of the written test plus the oral
test, but not as an arithmetic average, but as a global vote.

Contacts/More Information

Other information: The days of students reception are fixed. Additional
appointments are foreseen after agreement.

Università degli Studi
"G. d'Annunzio"

Chieti - Pescara

Aree