ENVIRONMENTAL GEOCHEMISTRY AND HEALTH

This course aims to provide the basic knowledge of Geochemistry necessary to understand the environment.

Geochemistry studies the chemical composition of the Earth and examines the chemical processes exchanging matter and energy between the different geochemical spheres: rocks and soils (lithosphere), surface and underground waters (hydrosphere), gases (atmosphere) and the biotic component (biosphere). The Geochemistry course provides the basis for understanding many geological and environmental processes such as (i) the chemical and chemical-physical processes that generated and shaped the Earth's crust, (ii) the processes leading to the current spatial distribution of the elements and nuclides in the different geochemical spheres; (iii) the current composition of the atmosphere and hydrosphere, (iv) the biogeochemical cycles and their interactions, and (v) the anthropic forcing and its impact on biogeochemical cycles. Knowing Geochemistry improves our understanding of the Earth, allowing us to reconstruct the past and to understand the present. In addition, human activities have a strong impact on the climate and geochemical cycles regulating the functioning of ecosystems. The application of geochemical concepts also allows understanding and predicting the behavior of the elements in an anthropized environment (a fifth sphere -the anthroposphere- has recently emerged).

Environmental Geochemistry and Health explores the relationships between the geochemical behavior and cycling of natural or anthropic compounds at the Earth’s surface and the health of all living organisms, including humans. This discipline focuses on the interface of all overlapping and interacting Earth’s spheres: atmosphere, lithosphere, pedosphere, hydrosphere, cryosphere, biosphere, and anthroposphere.
Thus, Environmental Geochemistry and Health encompasses current research at the intersection of many disciplines, such as geology, chemistry, biology, ecology, environmental studies, statistics, exposure science, epidemiology, and social sciences. Consequently, this discipline has a strong multidisciplinary perspective aiming to answer current questions about the sources, distribution, transformations, transports, cycling, interactions, removal processes, and health effects of relevant harmful natural substances and anthropogenic contaminants in the rock–soil–water–air–life systems.

The Earth’s surface is the place where we live, we breathe and where we found most of the exploitable resources of everyday use, such as water, food, and sources of energy. Nowadays, we are facing environmental issues caused in large part by growing populations, overcrowding, and the consequent depletion of natural resources, energy sources and forcing on climate. These serious problems require prompt, firm, and creative solutions that may be taken at the National and even international level. Maintaining the sustainability of these resources is mandatory to also maintain high-quality life expectations and geopolitical equilibria. Under this scenario, future scientists will be asked to investigate increasingly challenging environmental problems and to address policymakers to better legislation for a healthier environment.

With these expectations in mind, future generations of scientists should excel in identifying and predicting the effects of natural and anthropogenic compounds on the Earth’s surface. They should be also able to discriminate natural and anthropogenic sources, quantify their relative contributions to the environment and predict their biogeochemical interplays. Solving these challenges will be largely facilitated by scientists with robust expertise in Environmental Geochemistry.

While a robust preparation in Environmental Geochemistry provides answers to the composition, structure, properties, and behavior of the matter at the Earth’s surface, Exposure Science and Epidemiology offer the opportunity to find possible causal links between the natural or disturbed geochemical environment, health diseases, and the quality of life. This latter topic is covered by the Health Sciences concepts acquired within the course.

In particular, the attendance to this course will allow the student to:

1. Knowing the main concepts of Geochemistry and knowing correct geochemical terminology;
2. Understanding the processes that shaped the Earth to the current form, composition;
3. Understanding the mechanisms regulating the geochemical spheres;
4. Understanding the fluxes of matter and energy and the anthropic pressures that have (and will increasingly have) important impacts on the environment and on the climate;
5. Knowing how to identify and discriminate the geochemical processes between natural and anthropized environments;
6. Knowing how to apply geochemical knowledge and tools to explain natural phenomena and to solve environmental problems;
7. Knowing how to apply a critical and multidisciplinary approach to the assessment of complex environmental problems.

Basics of Chemistry and Physics.

The teaching is divided into 8 sections.

Section 1 (basic concepts) briefly introduces and summarizes key concepts for the remaining parts of the course, i.e. the atom structure, isotopes, periodic properties, atom stability, radioactivity and radioactive decays.

Section 2 (cosmochemistry and origin, evolution and structure of Planet Earth) describes the nucleosynthesis, the origin and evolution of the solar system and terrestrial planets with an introduction on the composition of meteorites. The origin of the Earth, the processes of condensation, homogeneous /heterogeneous accretion, the internal structure of the Earth, and the genesis and evolution of the Earth's crust. Key concepts of Geochemistry are presented, such as the geochemical differentiation of the Earth and the origin of its oceans and atmosphere.

Section 3 (lithosphere) analyzes the abundance and distribution of the elements in the Earth's crust. Concepts of mineralogy and petrography are introduced, as well as the classification of minerals (including silicates) and rocks. The weathering, the chemical alteration of minerals and rocks (dissolution, oxidation, hydration and hydrolysis), the solubility of CO2 and formation of H2CO3, and the role of carbonates. Introduction to the properties of clay minerals, introduction to soils.

Section 4 (atmosphere) deals with the origin, evolution, structure and chemical composition of the atmosphere, with particular attention to the troposphere. The main gaseous species present in the atmosphere will be presented, along with the geochemistry of the aerosol system, and the role of atmospheric (aeolian) transports of crustal material in the geochemical cycles. The composition of the atmosphere and on aerosol, urban and regional air pollution, health effects and influence of airborne particles on climate change.

Section 5 (hydrosphere) deals with the structure and properties of water, the geochemistry of oceans, continental and meteoric waters.

Section 6 (biosphere and geochemical cycles) introduces the (bio)geochemical cycles, analyzing the reservoirs and the pathways that chemical elements follow in the surface and crust of the Earth. The main cycles are treated: water, carbon, nitrogen, phosphorus. The interactions between the various geochemical cycles are briefly discussed.

Section 7 (anthroposphere) discusses the anthropic impact on the geochemical cycles with the analysis of some case studies. Some real case studies are presented and are interpreted starting from the geochemical associations of the elements.

Section 8 (health) explores the relationships between the geochemical behavior and cycling of natural or anthropic compounds at the Earth’s surface and the health of all living organisms, including humans.

Slides provided by the teacher. Online resources.
During the course, the methods for carrying out bibliographic research aimed at scientific topics using the resources made available by the BAS - Biblioteca Area Scientifica will be discussed.

The exam consists of an oral test divided into two parts. In the first part, students will present, critically analyze, and discuss a scientific article related to a topic in geochemistry/environmental geochemistry covered during the course. This article will be assigned by the teacher at the end of the lessons or before the exam session; the topic will be chosen based on the students' expressed preferences regarding the subjects covered. The article will generally be in English. The second part of the exam will focus on the concepts presented during the lectures and the case studies analyzed in class. The first part is worth a maximum of 8 points towards the final grade, while the second part is worth a maximum of 22 points. All students, including non-attending students, are required to contact the teacher to receive a scientific article assignment at least 15 days before the scheduled exam date.

oral

Evaluation Grid

28-30L: Confident and comprehensive presentation of the topics covered in the chosen scientific article. Excellent knowledge of all topics discussed in class. Precise and appropriate use of scientific and geochemical terminology. Correct selection of measurement units. Outstanding ability to connect and integrate covered topics. Honors are awarded in the presence of exceptional knowledge and applied understanding across the entire syllabus, combined with excellent judgment and confident presentation.

25-27: Excellent presentation of the topics covered in the chosen scientific article. Good knowledge of the topics discussed in class. Correct use of scientific and geochemical terminology. Good ability to select appropriate measurement units. Strong ability to connect covered topics.

22-24: Good presentation of the topics covered in the chosen scientific article. Sufficient knowledge of the topics covered in class. Inconsistent precision in the use of scientific and geochemical terminology. Occasional inaccuracies in selecting measurement units. Limited but present ability to connect topics.

18-21: Uncertain and superficial presentation of the topics covered in the chosen scientific article. Minimal and barely sufficient knowledge of the topics discussed in class. Sporadic and imprecise use of scientific and geochemical terminology. Uncertainty in selecting measurement units. Limited and fragmented ability to connect topics.

The teaching is structured in classroom lessons with possible seminars of teachers and researchers inside or outside the University. In addition to the lectures, the teaching also includes some discussion sessions where students are strongly encouraged to examine and review the learned concepts, testing their understanding through the critical reading of scientific literature, and the analysis and interpretation of cases study. These discussion sessions bring multiple benefits to the students (i) helping them to better understand the learned concepts, (ii) encouraging them to stay up to date during the entire teaching period, (iii) allowing them to identify misunderstandings or gaps in preparation, (iv) providing them with the tools to face scientific discussions with a high degree of autonomy, (v) helping them to improve communication skills using appropriate terminology, and (vi) preparing them for the second test of the final exam. Some geochemical datasets (various environmental matrices) will also be analyzed during the last lessons; the goal is becoming familiar with geochemical data and their interpretation.

All lessons are provided as PowerPoint presentations and are distributed at weekly-basis to students by using the Moodle teaching platform. In the same way, the case studies discussed during the lessons and the tracks to perform the exercises will also be provided.

Students are invited to periodically consult Moodle to be up to date on lessons.

This subject deals with topics related to the macro-area "Natural capital and environmental quality" and contributes to the achievement of one or more goals of U. N. Agenda for Sustainable Development