INSTRUMENTAL ANALYSIS APPLICATIONS

Back

Learning Outcomes

Will explain spectroscopic methods.
Explains the wave properties of electromagnetic radiation.
Explains the wave parameters.
Explains electromagnetic spectra.
Explains the transmission, refraction, scattering, and polarization of light.
Will explain the components of optical instruments.
Explains the types and general designs of optical devices.
Explains light sources.
Distinguishs wavelength selectors.
Will explain optical atomic spectroscopy.
Explains the general characteristics of optical atomic spectra.
Explains atomization methods.
Explains sample preparation and introduction methods.
Will explain atomic absorption and atomic fluorescence spectrometry.
Explains atomic absorption.
Explains sample atomization techniques.
Explains the structure and components of atomic absorption instruments.
Distinguishs interferences in atomic absorption spectroscopy.
Describes the analytical applications of atomic absorption.
Will explain atomic emission spectrometry.
Explains atomic emission.
Explains arc and spark-source emission spectroscopy.
Explains plasma-source emission spectroscopy.
Illustrates applications of optical emission spectroscopy.
Will explain atomic mass spectrometry.
Explains the general characteristics of atomic mass spectrometry.
Explains mass spectrometers.
Explains inductively coupled plasma mass spectrometry (ICP-MS).
Illustrates ICP-MS applications.
Explains spark-source and thermal-emission mass spectrometry.
Will explain atomic X-ray spectrometry.
Explains the basic principles of atomic X-ray spectroscopy.
Defines the components of atomic X-ray spectroscopy devices.
Atomik X-ışını spektrometrisinin uygulamalarını örneklendirir.
Will explain transmittance and absorbance measurements.
Explains beam power and beam intensity.
Explains transmittance, absorptivity, and molar absorptivity.
Performs transmittance-to-absorptivity conversion calculations.
Will explain the Lambert-Beer law.
Explains the Beer-Lambert law and performs related calculations.
Explains the causes of chemical and instrumental deviations in the Beer-Lambert law.
Will explain the effect of instrumental noise on spectrophotometric analysis.
Identifies the sources of instrumental noise.
Explains the effect of slit width on absorbance measurements.
Will explain the instrument used in molecular absorption spectroscopy.
Explains instrument types and their components.
Explains the characteristics of light sources.
Distinguishes the characteristics of photometers and spectrophotometers.
Will explain absorbing species.
Defines the types of absorbing electrons and their transitions.
Explains the absorption characteristics of chromophores.
Will explain basic qualitative applications in absorption measurements.
Explains how spectral data should be properly represented in graphs.
Explains the effect of solvents on analyses.
Will explain basic quantitative applications in absorption measurements.
Explains the selection of an appropriate wavelength.
Determines the relationship between absorbance and concentration.
Calculates concentration using the standard addition method.
Performs calculations related to mixtures of absorbing substances.
Explains derivative and dual-wavelength spectrophotometry.
Will explain photometric titrations.
Explains the photometric titration curve.
Demonstrates knowledge of photometric titration instruments.
Performs photometric titration applications.
Will explain the theory of fluorescence and phosphorescence.
Defines fluorescence and phosphorescence.
Explains the excited states that generate fluorescence and phosphorescence.
Explains quenching pathways.
Identifies variables affecting fluorescence and phosphorescence.
Explains emission and excitation spectra.
Will explain the instruments used for fluorescence and phosphorescence measurements.
Explains the components of fluorometers and spectrofluorometers.
Explains the design of instruments.
Explains the functions of instrument components.
Explains the functions of instrument components.
Will explain applications and photoluminescence methods.
Explains fluorometric determination of inorganic species.
Explains fluorometric determination of organic species.
Illustrates applications of phosphorimetric methods.
Will explain chemiluminescence.
Defines the chemiluminescence phenomenon.
Explains the measurement of chemiluminescence.
Illustrates analytical applications of chemiluminescence.
Will explain infrared spectroscopy.
Explains the theory of infrared absorption spectrometry.
Explains infrared radiation–matter interactions.
Will explain vibrations in infrared spectroscopy.
Explains Hooke’s law and equation.
Performs calculations based on Hooke’s law.
Distinguishes vibration types.
Will explain infrared spectrometers.
Defines the infrared spectrometer.
Explains the components of the instrument.
Explains infrared radiation sources.
Explains Fourier transform and its significance.
Will explain basic applications in infrared spectroscopy.
Explains the basic steps of qualitative applications.
Explains sample preparation.
Explains the fundamental elements of infrared spectra.
Illustrates basic qualitative analyses.
Will explain the fundamentals of NMR spectroscopy.
Explains the fundamentals of NMR spectroscopy.
Explains the fundamental principles of NMR spectroscopy.
Will explain NMR spectroscopy.
Explains nuclear resonance state and relaxation.
Explains chemical shift.
Explains spin-spin coupling.
Will explain NMR spectrometers.
Explains the working principle of an NMR spectrometer.
Explains the components of an NMR spectrometer.
Explains sample preparation techniques.
Explains key considerations in evaluating an NMR spectrum.
Will explain the mass spectrometry.
Defines mass spectrometry.
Explains the theoretical principles of mass spectrometry.
Will explain ion sources.
Distinguishes ionization techniques.
Classifies ion sources according to their intended use.
Will explain mass spectrometers.
Explains the components of instrument.
Explains the structure of a mass analyzer.
Will explain applications of molecular mass spectrometry.
Explains key parameters used in molecular identification.
Explains the fundamental components and characteristics of a mass spectrum.
Will explain CHNS analysis.
Explains elemental CHNS analysis.
Explains the fundamental principles of CHNS analysis.
Explains the applications of CHNS analysis.
Will explain elemental analysis instrument.
Explains the components of a CHNS analyzer.
Explains sample preparation techniques for CHNS analysis.
Explains the matrix effect in CHNS analysis.
Illustrates examples of CHNS analyses.
Will explain refractometry.
Refraktometriyi tanımlar.
Explains the applications of refractometry.
Explains the refractive index and influencing factors.
Explains the terms: angle of incidence, angle of refraction, normal, specific refractive index, critical angle, and molecular refractive index.
Describes the operation of an Abbe refractometer.
Illustrates examples of refractometry applications.
Will explain polarimetry.
Defines polarimetry.
Explains polarized light and its properties.
Explains the components and functions of a polarimeter.
Illustrates applications of polarimetry.
Will explain saccharimetry.
Defines saccharimetry.
Explains the applications of saccharimetry.
Explains factors affecting polarization.
Explains quantitative and qualitative analysis using specific rotation.
Will explain excitation signals in voltammetry and types of voltammetry.
Defines voltammetry.
Draws a voltammetric cell schematic and explains its fundamental characteristics.
Explains forces in an electrochemical cell.
Draws a voltammogram and explains its fundamental components.
Distinguishes excitation signals used in voltammetry and their effects.
Will explain voltammetric devices.
Draws a voltammetry instrument.
Distinguishes solid electrodes and their working ranges.
Explains voltammetric methods.
Explains qualitative and quantitative analysis in voltammetry.
Explains qualitative and quantitative analysis.
Will explain polarography.
Explains polarography and the characteristics of the dropping mercury electrode.
Explains the applications of polarography.