Advanced Methods for Structural and Morphological Analysis

Code:

Q4084

Acronym:

Q4084

Level:

400

Keywords
Classification	Keyword
OFICIAL	Chemistry

Instance: 2019/2020 - 1S

Active?	No
Web Page:	https://moodle.up.pt/course/view.php?id=2322
Responsible unit:	Department of Chemistry and Biochemistry
Course/CS Responsible:	Master in Applications in Biotechnology and Synthetic Biology

Cycles of Study/Courses

Acronym	No. of Students	Study Plan	Curricular Years	Credits UCN	Credits ECTS	Contact hours	Total Time
M:ABBS	0	The study plan from 2019/20	1	-	6	42	162

Teaching language

Suitable for English-speaking students

Objectives

- Recognize the role of structural analysis methods in a wide range of applications, from Pure&Applied Chemistry or (Nano)Materials Science to Biomedicine

- Learn the most relevant morphological and structural analysis techniques and their adequacy according to the desired applications

- Identify the scope and limitations that characterize each of the relevant structural analysis methods

- Read/interpret scientific papers related to the course area

- Elaborate a monograph on a selected subject related to the course area

- Present an oral communication on a given subject related to the course area

Learning outcomes and competences

The course’s main goal is to provide advanced training in morphological and structural analysis methods, allowing the students to understand the fundamentals and main applications of the most relevant techniques presently used for the characterization of molecules, (nano)materials and biological systems. Consequently, the program starts by the revision of the fundamentals of each of the techniques to be addressed, followed by an in-depth study of each one of them and of their main current applications. Several case studies will be chosen on the basis of their interdisciplinarity and inclusion of one or more relevant techniques. These case studies will be analyzed and discussed with the students, aiming at consolidating their training, allowing them to develop their own ability to analyze more complex situations.

Working method

Presencial

Pre-requirements (prior knowledge) and co-requirements (common knowledge)

Not applicable

Program

1. Vibrational spectroscopy: Infra-red and Raman. Theoretical principles, instrumentation and spectral interpretation.


2. Magnetic resonance techniques: nuclear magnetic resonance (2D solution and solid state) and electron paramagnetic resonance. Theoretical principles, instrumentation and spectra interpretation.


3. X-Ray Photoelectron Spectroscopy (XPS). Theoretical principles. Chemical analysis and high resolution spectra interpretation.


4. Scanning probe microscopy (SPM – atomic force microscopy and Scanning Tunnelling Microscopy). Theoretical principles and examples.


5. Electronic microscopy (electron scanning (SEM), electron transmission (TEM) and high resolution electron transmission (HRTEM). Theoretical principles and examples.


6. 6. X-ray diffraction: single-crystal crystallography and powder diffraction. Theoretical principles and diffractogram interpretation.


7. Case studies

Mandatory literature

E. de Hoffman, V. Stroobant; Mass Spectrometry: Principles and Applications – 3rd ed, Wiley-VCH, 2007. ISBN: ISBN-10: 0470033118
B. H. Stuart; Infrared Spectroscopy: Fundamentals and Applications (Analytical Techniques in the Sciences, John Wiley , 2011. ISBN: ISBN-10: 0470854286
Yang Leng,; Materials Characterization: Introduction to Microscopic and Spectroscopic Methods, Wiley-VCH, 2010. ISBN: ISBN-13: 9780470823002
M. Birkholz; Thin Film Analysis by X-Ray Scattering. , WILEY-VCH , 2006. ISBN: ISBN: 3-527-31052-5

Complementary Bibliography

M. Hesse, H. Meier, B. Zeeh, Thieme; Spectroscopic Methods in Organic Chemistry, 199. ISBN: ISBN-10: 3131060417

Teaching methods and learning activities

- Lectures: Presentation of syllabus topics using multimedia tools; specialized topics will be presented by invited guests. The UC management will be made using the Moodle platform.

- Tutorial sessions: Analysis of scientific papers; flash presentations on scientific papers; resolution of case studies involving morphological and structural analysis techniques; summary reports on lectures by invited guests; application of concepts learnt in the elaboration of original scientific materials, e.g., monographs and oral presentations on topics related to the course.

- Evaluation: Distributed with final exam

Distributed evaluation component: based on the quality of the tasks attributed within tutorial sessions (discussion of scientific papers and case studies, oral presentations, reports on lectures by guests, monographs, etc.).

Final Mark = 40% Exam + 25% Monography + 35% Tutorial classes

keywords

Technological sciences > Technology > Nanotechonology
Physical sciences > Chemistry > Organic chemistry
Natural sciences > Biological sciences
Physical sciences > Chemistry > Biochemistry
Physical sciences > Chemistry
Physical sciences > Chemistry > Inorganic chemistry
Physical sciences > Chemistry > Molecular chemistry
Physical sciences > Chemistry > Structural chemistry

Evaluation Type

Distributed evaluation with final exam

Assessment Components

designation	Weight (%)
Exame	40,00
Participação presencial	35,00
Trabalho escrito	25,00
Total:	100,00

Amount of time allocated to each course unit

designation	Time (hours)
Apresentação/discussão de um trabalho científico	40,00
Estudo autónomo	93,00
Frequência das aulas	50,00
Trabalho escrito	40,00
Trabalho laboratorial	20,00
Total:	243,00

Eligibility for exams

The number of the missed tutorials classes must obey the estatutodos da FCUP

The final mark of Tutorial classes have to be equal or higher than 10

Calculation formula of final grade

Final Mark= 40% Exam + 25% Monography + 35% Works developed on TP/P classes

Examinations or Special Assignments

Not applicable

Internship work/project

Not applicable

Special assessment (TE, DA, ...)

Final Mark= 70% Exam + 30% Monography

Classification improvement

Final Exam