Akademik Dersler - İçerik

Explains Fundamental Analysis Principles and Concepts.
Explains the fundamental physical and chemical principles of microscopic methods (SEM, TEM, AFM), thermal analysis techniques (TG, DTA, DSC), surface characterization (BET, Zetameter), and X-ray methods (XRD, XRF, XPS). Defines sample characteristics appropriate for each technique (morphology, thermal stability, surface area, zeta potential, etc.). Defines key concepts such as the Electrical Double Layer and the Isoelectric Point for Zeta potential, and explains the stability of colloidal systems.
Classifies Components and Mechanisms of Characterization Instruments.
Classifies the basic components and functions of SEM, TEM, and AFM instruments (electron gun, vacuum system, lenses, probes). Explains the features of thermal analysis instruments like TG, DTA, and DSC in creating different atmospheres and temperature programs. Classifies the types of adsorption isotherms (Type I-VI) used in BET surface analysis and the corresponding pore structures. Explains fundamental working mechanisms such as Bragg's Law in XRD and the Photoelectric Effect in XPS.
Executes Experimental Procedures and Data Processing by Selecting the Appropriate Method.
Classifies the basic components and functions of SEM, TEM, and AFM instruments (electron gun, vacuum system, lenses, probes). Explains the features of thermal analysis instruments like TG, DTA, and DSC in creating different atmospheres and temperature programs. Classifies the types of adsorption isotherms (Type I-VI) used in BET surface analysis and the corresponding pore structures. Explains fundamental working mechanisms such as Bragg's Law in XRD and the Photoelectric Effect in XPS.
Interprets Results, Performs Calculations, and Synthesizes the Characterization Report.
Interprets morphological images, surface topography, and structural details obtained from SEM, TEM, and AFM. Calculates phase transitions, glass transition temperature (Tg), thermal decomposition temperature, and reaction enthalpies using TG/DTA/DSC results. Interprets specific surface area and pore size distribution data obtained from BET analysis. Qualitatively/quantitatively elucidates material phases, crystal structures, and crystallite sizes using XRD data; makes inferences about chemical composition and elemental bonding states using XRF and XPS. Evaluates all analysis results comparatively and prepares a comprehensive material characterization report.