- Docente: Margherita Venturi
- Credits: 6
- SSD: CHIM/03
- Language: Italian
- Teaching Mode: Traditional lectures
- Campus: Bologna
- Corso: Second cycle degree programme (LM) in Photochemistry and molecular materials (cod. 8026)
Learning outcomes
At the end of the course the student acquires the basic principles to understand the chemical effects induced in matter by the absorption of ionizing (high energy) radiations. He is also capable of analyzing in a critical way the potential of the technologies that utilize such kind of radiations in several applicative fields (industry, medicine, food, biotechnologies, environment, and cultural heritage).
Course contents
Prerequisites: basic knowledge of inorganic and organic chemistry, physical chemistry and photochemistry
Attendance: the course has no compulsory attendance
Course contents: the course is divided in two parts; the first one concerns the general principles of the radiation-matter interaction and illustrates the most important results obtained by this discipline in the field of basic research, while the second part is dedicated to the applicative aspects. The addressed topics can be summarized as follows.
1. The types (electromagnetic waves and particles) of high energy radiation
1.1. Peculiar features of the interaction of the high energy radiation with matter pointing out the main differences between radiation chemistry and photochemistry, the other discipline concerning the interaction of radiation with matter
2. High energy sources
2.1. Radioactive-based sources
2.2. Accelerator machines (particularly electron accelerators) capable of providing high intense radiation pulses and related time-resolved detection systems necessary to carry out kinetic studies
3. Water and aqueous solution radiolysis
3.1. Use of scavengers to select reducing or oxidizing conditions
3.2. Case studies performed in the field of inorganic and organic chemistry
3.3. Enzyme and DNA case studies
4. Radiolysis in solvents different from water (brief mention)
5. Radiolysis in the solid state and comparison with the liquid state pointing out the main differences
6. Radiolysis in the gas state and comparison with the liquid state pointing out the main differences
7. Dosimetry and dosimeters
7.1. Dose and dose-rate
7.2. Examples of primary dosimeters
7.3. Examples of secondary dosimeters, in particular chemical dosimeters
7.4. Examples of solid dosimeters
8. Applications of high energy radiations in medicine
8.1. The mean in which the dose in medical field is measured
8.2. Medical diagnosis: X-ray (two- and three-dimensional) radiography; PET; nuclear imaging
8.3. Radiation therapy for tumors: gammatherapy, tomotherapy, boron neutron capture therapy, and adrotherapy
9. Applications of high energy radiations in the industrial field
9.1. Sterilization with particular focus on medical devices
9.2. Production, cross-linking, and degradation of polymers; production of composites
9.3. Production of devices for electronics
9.4. Production of materials interesting from the biotechnological viewpoint
10. Environmental applications of high energy radiations
10.1. Treatment of urban and agriculture waste; treatment of industrial water to reduce the pollutants
10.2. Treatment of fuel gases to reduce pollutants
11. Applications of high energy radiations in cultural heritage
11.1. Actions to establish the conservation state, authenticity verification, dating, and origin: X-ray radiography, X-ray fluorescence, neutron activation analysis
11.2. Actions aimed at preserving artworks: disinfestation and reinforcement of wood, pottery, and bone artworks
12. Food treatment with high energy radiations
12.1. Treatment aimed at extending the shelf life of vegetables, fruit, cereals, white and red meat, and fish
12.2. Treatment aimed at reducing food-related health hazards
Readings/Bibliography
Lecture notes and handbooks will be handed in by the person in charge of the course
Teaching methods
Radiation Chemistry is an optional course aimed at showing the potential of this relatively young discipline as far as basic research and applicative aspects are concerned. The course comprises lectures and one or two visits to the laboratories of the CNR-ISOF Institute in Bologna where two gamma radiation sources are available.
Assessment methods
The learning assessment takes the form of an oral exam of average duration of 30-40 minutes. The exam consists of three questions on the topics dealt with in the course. A presentation of one of the applications illustrated in the course and selected by the student is also requested.
Teaching tools
Blackboard, overhead, personal computer, projector, power point presentations
Office hours
See the website of Margherita Venturi