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Experimental methods in chemical engineering: Thermogravimetric analysis—TGA

Nooshin SaadatkhahDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec CanadaAdrián Carillo GarciaDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec CanadaSarah L. G. AckermannC‐Therm Technologies, Thermal Analysis Labs Division, Thermal Analysis Labs Ltd. Fredericton New Brunswick CanadaPhilippe LeclercDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec CanadaMohammad LatifiDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec CanadaSaid SamihDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec CanadaGregory S. PatienceDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec CanadaJamal ChaoukiDepartment of Chemical Engineering Polytechnique Montréal Montréal Québec Canada
2019en
ABI

Аннотация

Abstract Thermogravimetric analysis (TGA) is a quantitative analytical technique that monitors the mass of a sample from 1 mg to several g as a furnace ramps temperature to as high as 1600°C under a stable or changing gas flow. The first gravimetric test was in 27 BC when Vitruvius measured limestone's change of mass as it calcined to lime. In modern chemical engineering, researchers apply the technique to derive conversions, kinetics, and mechanisms for any process with a change of mass by isothermal, non‐isothermal, and quasi‐isothermal methods. The mass drops as the sample decomposes, volatile compounds evaporate, or the oxidation state decreases, while in reactive environments (with O 2 , for example), the mass of transition metals may increase. TGA is incapable of detecting phase transitions, polymorphic transformations, or reactions for which mass is invariant. DSC or DTA couple with TGA to help deconvolute a DSC plot by separating physical changes from chemical changes. Evolved gas analysis techniques monitor the gaseous products exiting the TGA furnace on‐line as the temperature ramps. A bibliometric map of keywords from articles citing TGA indexed by Web of Science in 2016 and 2017 identified five research clusters: nanoparticles, performance, and films; crystal structures, acid, and oxidation; composites, nanocomposites, and mechanical properties; kinetics, pyrolysis, and temperature; and adsorption, water and wastewater, and aqueous solutions. This review provides an overview of the basic principles of modern TGA.

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