Publication in the Diário da República: Despacho n.º 15239/2016 - 19/12/2016
5 ECTS; 2º Ano, 2º Semestre, 30,0 T + 30,0 PL , Cód. 814223.
- Maria Teresa da Luz Silveira (1)(2)
(1) Docente Responsável
(2) Docente que lecciona
Students should be able to identify the instrumental methods involving absorption, dispersion and emission of energy, as well as use them in quantitative analysis.
They should be able to apply IV and NMR spectroscopies and chromatography techniques.
1. Visible and ultraviolet spectrophotometry
1.1.2-Law of Lambert and Beer
1.1.3-Chemical Deviations from Beer's Law
1.2-Nomenclature in spectrophotometry. Order of magnitude of concentrations and other quantities. Graphical presentation of data
1.3-Origin of spectrophotometric errors
1.4.1-Types of spectrophotometers.
1.4.2-Instrument components and their functions.
1.5-Instrumental deviations from the Beers Law.
1.6-Accuracy in spectrophotometric analysis: 1.6.1-Colorimetry; Spectrophotometry.
1.6.2-Increased accuracy by differential spectrophotometry
1.7-Applications of ultraviolet and visible spectrophotometry
1.7.1-Qualitative analysis. Identification of electronic spectra
-Conditions of the solution; selection of appropriate solvent and selection of appropriate wavelength or wavelengths
-Calculation Methods - Calibration Curve and Absolute Method
-Interference Elimination - Standard Addition Method
-Analysis of mixtures of absorbing substances
2. Radiant energy dispersion (turbidimetry and nephelometry)
3. Flame photometry.
3.1-Theoretical principles: Emission spectra; Dissociation mechanism; Intensity of atomic spectral stripes
3.2-Instrumental systems: components of an emission flame photometer and their functions.
3.3-Different types of emission flame photometry
3.3.1-Direct Flame Photometry
3.3.2-Indirect flame photometry by: difference; replacement, side effects-banding and radiation depression.
3.4-Types of interference: Spectral; Background emission; Self-absorption; Ionization; Chemical; Matrix
3.5-Flame photometry in Analytical Chemistry: precision, accuracy, detection limit and sensitivity in emission flame photometry.
3.6-Calculation Methods: Calibration Curve; Standard Addition; Internal Standard Method - Characteristics of an Internal Default Standard.
4. Atomic absorption spectroscopy.
4.1-Theoretical foundations: absorption mechanism; atomization; atomic population; Lambert-Beer Law;
4.2-Equipment: sources for atomic absorption; types of flames; atomization systems and burners.
4.3 Accuracy, precision, sensitivity and limit of detection in atomic absorption.
4.5-Quantitative analysis: Methods of calculation-calibration curve; addition of standard and internal standard
5. Infrared Spectrometry
5.3-IR spectra: band nomenclature; printing region and typical absorption zones; spectrum identification
6. Nuclear magnetic resonance spectroscopy
6.2-Instrumentation for NMR: continuous wave apparatus; Fourier pulse and transform technique apparatus.
6.3-NMR spectra and molecular structure.
6.4-Interpretation of NMR spectra
7.2-Chromatography analysis classification
7.3 Chromatographic methods and techniques
7.3.3-Ion exchange chromatography
7.3.7-Liquid column chromatography
7.3.8-High performance liquid chromatography
7.3.9-Hyphenated techniques: GC-MS; HPLC-MS
-Spectrophotometric determination of pKa of green bromocresol indicator
-Turbidimetric determination of sulfate content in water
-Determination of sodium and potassium in water by Emission Flame Photometry
Approval in the practical component (P) depends on the experimental execution of all practical works, delivery of a report of each work.
The practical assessment is valid only in the academic year in which it is performed.
The theoretical component (T) will be evaluated with a written test and a projet with a final value minimum of 9.5v.
The final assessment consists of a written test on the theoretical subject (T) with a minimum of 9.5v.
The final classification of both the continuous evaluation and the final evaluation will be the weighted average of the two components: CF=0.2P + 0.8T
- Gonçalves, M. (2001). Métodos Instrumentais para Análise de Soluções. Análise Quantitativa.. Lisboa: Fundação Caloute Gulbenkian
- Grouch, S. e Holler, F. e Skoog, A. (2006). Principles of Instrumentation Analysis. New York: Brooks/Cole
- Rouessac, A. e Rouessac, F. (2007). Chemical Analysis: Modern Instrumentation Methods and Techniques. New York: Wiley
Lectures exploring subject matter, theoretical-practical classes and laboratory sessions to apply the acquired skills.
Software used in class