Product Code Database
Thermogravimetric analysis or thermal gravimetric analysis ( TGA) is a method of thermal analysis in which the mass of a sample is measurement over time as the temperature changes. This measurement provides information about physical phenomena, such as , absorption, adsorption and desorption; as well as chemical phenomena including , thermal decomposition, and solid-gas reactions (e.g., oxidation or redox).
A typical thermogravimetric analyzer consists of a precision balance with a sample pan located inside a furnace with a programmable control temperature. The temperature is generally increased at constant rate (or for some applications the temperature is controlled for a constant mass loss) to incur a thermal reaction. The thermal reaction may occur under a variety of atmospheres including: air, vacuum, inert gas, oxidizing/reducing gases, corrosive gases, carburizing gases, vapors of liquids or "self-generated atmosphere"; as well as a variety of including: a high vacuum, high pressure, constant pressure, or a controlled pressure.
The thermogravimetric data collected from a thermal reaction is compiled into a plot of mass or percentage of initial mass on the y axis versus either temperature or time on the x-axis. This plot, which is often Smoothing, is referred to as a TGA curve. The first derivative of the TGA curve (the DTG curve) may be plotted to determine inflection points useful for in-depth interpretations as well as differential thermal analysis.
A TGA can be used for materials characterization through analysis of characteristic decomposition patterns. It is an especially useful technique for the study of materials, including thermoplastics, thermosets, elastomers, composites, , fibers, coatings, paints, and fuels.
TGA is used in the analysis of polymers. Polymer usually melt before they decompose, thus TGA is mainly used to investigate the thermal stability of polymers. Most polymers melt or degrade before 200 °C. However, there is a class of thermally stable polymers that are able to withstand temperatures of at least 300 °C in air and 500 °C in inert gases without structural changes or strength loss, which can be analyzed by TGA.
Oxidative mass losses are the most common observable losses in TGA.
Studying the resistance to oxidation in copper alloys is very important. For example, NASA (National Aeronautics and Space Administration) is conducting research on advanced copper alloys for their possible use in combustion engines. However, oxidative degradation can occur in these alloys as Copper oxide form in atmospheres that are rich in oxygen. Resistance to oxidation is significant because NASA wants to be able to reuse shuttle materials. TGA can be used to study the static oxidation of materials such as these for practical use.
Combustion during TG analysis is identifiable by distinct traces made in the TGA thermograms produced. One interesting example occurs with samples of as-produced unpurified carbon nanotubes that have a large amount of metal catalyst present. Due to combustion, a TGA trace can deviate from the normal form of a well-behaved function. This phenomenon arises from a rapid temperature change. When the weight and temperature are plotted versus time, a dramatic slope change in the first derivative plot is concurrent with the mass loss of the sample and the sudden increase in temperature seen by the thermocouple. The mass loss could result from particles of smoke released from burning caused by inconsistencies in the material itself, beyond the oxidation of carbon due to poorly controlled weight loss.
Different weight losses on the same sample at different points can also be used as a diagnosis of the sample's anisotropy. For instance, sampling the top side and the bottom side of a sample with dispersed particles inside can be useful to detect sedimentation, as thermograms will not overlap but will show a gap between them if the particle distribution is different from side to side.
Activation energies of the decomposition process can be calculated using Kissinger method.
Though a constant heating rate is more common, a constant mass loss rate can illuminate specific reaction kinetics. For example, the kinetic parameters of the carbonization of polyvinyl butyral were found using a constant mass loss rate of 0.2 wt %/min.
For example, the TGA instrument continuously weighs a sample as it is heated to temperatures of up to 2000 °C for coupling with Fourier-transform infrared spectroscopy (FTIR) and mass spectrometry gas analysis. As the temperature increases, various components of the sample are decomposed and the weight percentage of each resulting mass change can be measured.
| + Comparison of Thermal gravimetric analysis and Differential thermal analysis techniques: ! Sr.No. ! Thermal gravimetric analysis (TGA) ! Differential thermal analysis (DTA) | ||
| 1 | In TGA the weight loss or gain is measured as a function of temperature or time. | In DTA the temperature difference between a sample and reference is measured as a function of temperature. |
| 2 | The TGA curve appears as steps involving horizontal and curved portions. | The DTA curve shows upward and downward peaks. |
| 3 | Instrument used in TGA is a thermobalance. | Instrument used in DTA is a DTA Apparatus. |
| 4 | TGA gives information only for substances which show a change in mass on heating or cooling. | DTA does not require a change in mass of the sample in order to obtain meaningful information. DTA can be used to study any process in which heat is absorbed or liberated. |
| 5 | The upper temperature used for TGA is normally 1000 °C. | The upper temperature used for DTA is often higher than TGA (As high as 1600 °C). |
| 6 | Quantitative analysis is done from the thermal curve by measuring the loss in mass m. | Quantitative analysis is done by measuring the peak areas and peak heights. |
| 7 | The data obtained in TGA is useful in determining purity and composition of materials, drying and ignition temperatures of materials and knowing the stability temperatures of compounds. | The data obtained in DTA is used to determine temperatures of transitions, reactions and melting points of substances. |
|
|
