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Thermogravimetric analysis

Thermogravimetric analysis (TGA), also known as thermogravimetry, is a technique that measures the change in mass of a sample—either loss or gain—as it is subjected to a controlled program, often in a specific atmosphere, to characterize its thermal behavior and composition. This method plots mass versus or time, generating a thermogram that reveals key processes such as , oxidation, , or . In TGA, a small sample (typically in the milligram range) is placed in a on a high-precision within a capable of reaching temperatures from ambient to over 1500°C, with heating rates ranging from 0.1 to 500°C/min or higher in specialized modes. The detects minute mass changes (down to 0.1 µg), while the system maintains precise control over the atmosphere—such as inert gases like or reactive ones like oxygen—to isolate specific reactions. This null- design ensures accurate tracking of kinetic processes without mechanical interference, often coupled with evolved gas analysis (EGA) for identifying gaseous byproducts via techniques like FTIR or . TGA finds broad applications across , , pharmaceuticals, and for assessing and oxidative , determining moisture or volatile content, analyzing multi-component compositions, and studying kinetics. For instance, it evaluates temperatures, pharmaceutical (e.g., quantifying loss in formulations), residue analysis in ceramics or metals, and lifetime predictions for materials under stress. Its minimal sample preparation, high sensitivity, and versatility make it indispensable for , , and industrial process optimization in sectors like , , and .

Introduction

Definition and principles

Thermogravimetric analysis (TGA) is a thermal analysis technique that measures the change in mass of a sample as a function of temperature or time under a controlled atmosphere, typically involving heating or cooling at a constant rate. This method continuously monitors the sample's weight using a precision balance while exposing it to a programmed temperature profile, allowing detection of mass variations down to fractions of a microgram. The fundamental principles of TGA revolve around thermal events that cause mass loss or gain in the sample, such as , , oxidation, , desorption, or . These changes occur as the sample is subjected to a program, often a linear ramp (e.g., 0.1 to 500°C/min), which influences the rate and extent of the processes observed. The technique relies on sensitive balance mechanisms to record these microgram-level alterations accurately, providing insights into the material's thermal stability and . Mass changes are quantified using the percentage mass change formula: \% \text{ mass change} = \frac{m_i - m_f}{m_i} \times 100 where m_i is the initial mass and m_f is the final mass at a given temperature or time point. TGA experiments are conducted under controlled atmospheres to simulate specific conditions and prevent unwanted reactions. Inert gases like nitrogen (N₂), helium (He), or argon (Ar) are commonly used to avoid oxidation, while oxidative atmospheres such as air or oxygen (O₂) promote reactions like combustion. Reactive gases can also be employed for targeted studies. The method offers high sensitivity with resolutions up to 0.1 µg, a wide temperature range typically from -150°C to 1600°C, and versatility for analyzing solids, liquids, and powders.

Historical development

The roots of thermogravimetric analysis (TGA) can be traced to ancient precedents, such as the Roman architect Vitruvius's description in of mass changes during the of to produce , an early empirical gravimetric . In the , foundational gravimetric methods emerged with the development of precise chemical balances by scientists like , enabling quantitative assessment of weight variations after thermal treatments, though these were static and manual. A pivotal advancement occurred in 1915 when Japanese physicist Kôtaro Honda invented the thermobalance, a recording device that continuously monitored mass changes with temperature, bridging manual gravimetry to dynamic thermal analysis. This innovation allowed for the observation of physical and chemical transformations in substances under heating, emphasizing the influence of procedural variables like heating rate on results. During the 1940s and 1950s, the technique progressed with automated recording balances, notably those developed by Pierre Chevenard in , which facilitated systematic studies of thermal weight losses in inorganic materials. The methodology was formalized in 1953 through Clément Duval's seminal book Inorganic Thermogravimetric Analysis, which provided a comprehensive framework for applying to precipitation and processes in . Commercialization accelerated in 1959 with the launch of the NETZSCH TG 409, the first modern instrument equipped with a top-loading capable of up to 1550°C, making the technique accessible for routine laboratory use. In the , integration with (DTA) began, allowing simultaneous measurement of mass and heat flow changes, as exemplified by early combined systems that evolved into NETZSCH's STA 429 model by 1970. The 1970s saw the introduction of high-resolution TGA instruments, such as the NETZSCH TGA/STA 409 in 1976, which incorporated advanced electronics for improved data recording and multi-channel output. Microbalance innovations in the further enhanced sensitivity, with the NETZSCH TG 439 achieving 0.1 µg resolution and low long-term drift (0.13 µg/h at 1000°C), enabling detection of minute mass changes in trace-level analyses. In the , evolved through couplings with evolved gas analysis (EGA) techniques, such as TGA-mass spectrometry (MS) and TGA-Fourier transform (FTIR) , which identify gaseous products in and provide deeper insights into reaction mechanisms. Overall, 's development was propelled by the transition from manual balances to computerized , yielding greater , , and with complementary analytical methods.

Instrumentation

Components of a TGA system

A thermogravimetric analysis (TGA) system comprises several interconnected hardware elements designed to precisely measure mass changes in a sample as a function of or time under controlled conditions. The core components include a high-precision balance, a controlled furnace, a sample holder, a gas supply and purge system, data acquisition interface, and safety features, each contributing to accurate and reliable thermal analysis. These elements work together to isolate mass variations from environmental interferences, such as buoyancy or convection, ensuring measurements reflect true sample behavior. The balance mechanism is the heart of the TGA system, typically a high-precision electrobalance such as a null-type or beam-type design that continuously records sample with exceptional sensitivity. It offers resolutions of 0.1 to 1 µg and capacities ranging from 100 mg to 1 g (or up to 5 g in advanced models), allowing detection of minute mass losses or gains during events. This component is often housed in a separate chamber to shield it from furnace , maintaining against temperature fluctuations that could otherwise introduce drift. The furnace provides the thermal environment for the analysis, electrically heated to achieve uniform up to 1600°C, with heating rates from 0.1 to 100°C/min depending on the model. Temperature uniformity is ensured by multiple thermocouples or sensors placed near the sample, preventing gradients that could skew mass readings. Furnaces vary in size and material—such as small-volume (16 mL) or large-volume (47 mL) designs with alumina or linings—to accommodate different sample types while minimizing thermal lag. The sample holder, often a crucible suspended from the balance arm into the furnace, supports the under study and facilitates gas . Common s include alumina for general use or platinum-rhodium for high-temperature and corrosive environments, with volumes ranging from 50 µL to 900 µL to suit sample sizes. Designs allow for open or enclosed configurations, enabling control over or reaction products without compromising balance integrity. The gas supply and purge system regulates the atmosphere around the sample to replicate specific conditions, such as inert (e.g., or ) or oxidizing (e.g., oxygen) environments, using flow controllers for precise delivery up to 200 mL/min. Purge gases through separate inlets to the and balance chamber, removing decomposition byproducts and countering effects from changes. This setup, operating at pressures of 1-3 , ensures reproducible results by maintaining a stable gaseous medium. Data acquisition integrates these components via a computer that records and data in , often using dedicated software for and initial . Systems like those from TA Instruments or employ Ethernet-connected controllers and touch-screen terminals to log parameters with high temporal resolution, enabling immediate visualization of trends. Calibration routines for the balance and thermocouples are typically built into the software to uphold measurement accuracy. Safety features are integral to handle the hazards of high temperatures and potentially reactive gases, including protective enclosures around the and to contain heat and fumes. Instruments incorporate warnings for hot surfaces (up to 1600°C), electrical hazards, and restrictions on explosive mixtures like , often requiring operation in fume hoods with . Replaceable fuses and automated shutdowns further mitigate risks during operation or maintenance.

Types of TGA instruments

Thermogravimetric analysis (TGA) instruments are primarily classified by their operational modes, which dictate how is controlled during , and by their physical designs, which influence sample handling and environmental interaction. These classifications enable tailored analyses for diverse material properties, such as decomposition kinetics or phase transitions. Dynamic TGA employs a continuous linear ramp, typically at rates of 1–100°C/min, while continuously recording sample mass changes. This mode is the standard for most routine analyses, effectively revealing temperature-dependent transitions like moisture evaporation, , or oxidative stability in materials such as or . Isothermal TGA maintains the sample at a fixed temperature over time, monitoring mass variations to study steady-state processes. It is particularly suited for evaluating reaction rates under constant conditions, such as oxidation in vegetable oils at 137°C or residue formation in hydrated salts like NaCl-water mixtures at 60°C. Quasi-static TGA involves stepwise temperature increases interspersed with isothermal holds, often until mass stabilizes at each step. This configuration minimizes kinetic complications from rapid heating, allowing separation of overlapping events like sequential release and volatile in complex samples such as or composites. Modulated TGA superimposes sinusoidal temperature oscillations (amplitudes of 5–10 , periods of 60–300 s) on a linear ramp, enhancing resolution of overlapping thermal events through of mass loss signals. It excels in kinetic studies, such as determining energies for polystyrene decomposition (around 185 kJ/mol across 5–95% conversion), by isolating reversible and non-reversible contributions. Instrument designs vary to optimize , accessibility, and . designs position the sample beam perpendicular to the purge , reducing effects and improving for precise measurements. Vertical or top-loading designs facilitate easy sample access and direct sensing, making them ideal for simultaneous TGA-DTA or TGA-DSC setups, as in systems like the DTG-60. Suspension systems, where the sample hangs from the balance, offer high across a wide sample volume range but are less suited for coupled techniques. Microbalance systems, featuring ultra-sensitive balances with resolutions down to 0.025 μg, are essential for analyzing small samples under 1 mg, enabling high-resolution studies with minimal material. Specialized variants extend TGA to extreme conditions. High-temperature TGA utilizes tungsten or graphite furnaces to reach up to 2400°C under inert, reducing, or atmospheres (down to 10⁻⁵ mbar), supporting analyses of materials like ceramics or metals. Cryogenic TGA incorporates cooling systems to operate down to -150°C, accommodating studies of low-temperature phase changes or adsorption in polymers and pharmaceuticals.

Experimental Procedures

Sample preparation and handling

Sample preparation and handling are critical in thermogravimetric analysis (TGA) to ensure accurate measurement of mass changes, minimize artifacts, and achieve reproducible results. Proper preparation prevents , ensures uniform heating, and avoids issues such as uneven or sample loss. Best practices emphasize using small, representative samples that maintain their integrity throughout the process. TGA accommodates various sample types, including solids such as powders and films, liquids in droplet form, and gels. For solids, powders are preferred for their high surface area, while films or fibers should be cut into small pieces or wound into coils to promote even gas exposure. Liquids and gels require careful placement to cover the pan bottom without spilling over edges. Typical sample masses range from 1 to 10 mg, with 5-10 mg ideal for most materials like polymers to balance sensitivity and avoid overloading the balance; smaller amounts (as low as 0.5 mg) may be used for limited samples but demand high-precision instruments. Preparation steps begin with drying the sample in a to remove adsorbed moisture, particularly for hygroscopic materials, ensuring no unintended mass loss during analysis. Coarse solids should be ground into a fine, uniform powder to enhance and gas , followed by sieving to achieve particle sizes below 100 µm for homogeneity and to reduce temperature gradients. Avoid introducing volatile additives or contaminants during grinding; instead, use clean, inert tools. For , samples should be representative of the bulk material, achieved through methods like coning and quartering. Crucible selection depends on the sample's thermal behavior, atmosphere, and maximum temperature. Platinum crucibles are suitable for oxidizing environments up to 1600°C due to their chemical inertness and resistance to oxidation, while alumina (Al₂O₃) crucibles are preferred for inert atmospheres and high-temperature applications up to 2000°C, especially with reactive samples. Aluminum pans are cost-effective for lower temperatures (up to 600°C) but are typically single-use. Cleaning protocols vary by material: alumina crucibles can be brushed with a soft , soaked in mild soap or (5-24 hours for stains), rinsed with , and preheated to 800°C for 6 hours to burn off residues; platinum crucibles are cleaned by immersion and rotation. Always verify cleanliness by checking weight stability (difference <30 µg) and discard deformed or discolored pans. Handling precautions include using anti-static spatulas or tweezers to prevent powder adhesion or electrostatic losses, and minimizing exposure to ambient air or humidity by preparing samples in a controlled environment like a glovebox or desiccator. Before loading, tare the empty crucible on a microbalance for precise mass determination, then gently spread the sample evenly across the pan bottom without overfilling or packing too densely to allow gas diffusion. For air-sensitive or volatile samples, employ pinhole or fully sealed pans to contain the material during transfer and initial heating. Common issues include mass loss from volatility during transfer, addressed by rapid loading into sealed pans, and agglomeration of fine particles, mitigated by thorough grinding and uniform distribution. Overly large particles or uneven packing can cause delayed decomposition due to poor gas access, so maintaining fine particle sizes and gentle tapping for a thin layer is essential. Foaming or explosive samples require smaller masses (1-5 mg) and pierced lids to vent pressure safely.

Operational parameters

The operational parameters in thermogravimetric analysis (TGA) are carefully controlled to ensure accurate and reproducible measurements of mass changes as a function of temperature or time. These parameters include the temperature program, which defines the thermal profile applied to the sample. Typical heating rates range from 0.1 to 100 °C/min, allowing for slow ramps to capture fine decomposition steps or faster rates for broader surveys, while cooling rates can similarly vary but are less commonly used in standard protocols. The temperature range generally spans from ambient conditions up to 1600 °C, depending on the instrument's furnace capabilities, with programs often incorporating isothermal holds or step-wise changes to isolate specific reaction stages. The atmosphere surrounding the sample is another critical parameter, influencing reaction kinetics and preventing unwanted side reactions. Common gas types include inert atmospheres like nitrogen or argon to suppress oxidation, or reactive ones such as oxygen for combustion studies, selected based on the sample's chemical behavior. Flow rates are typically set between 20 and 100 mL/min to maintain a stable environment and sweep away evolved gases, with balance and sample purge flows balanced to minimize buoyancy effects. Pressure is usually maintained at ambient levels, though some advanced instruments allow controlled pressures down to 10^{-1} mbar for specialized vacuum studies. The sample environment is optimized through choices in crucible configuration and pre-experiment conditioning. Open crucibles permit free gas exchange for oxidative or evaporative processes, while closed or pierced crucibles contain volatile products to study sealed decompositions. A purge time of 10 to 30 minutes with the selected gas is standard to establish a stable baseline by removing residual air or contaminants before initiating the temperature program. Calibration ensures the precision of temperature and mass measurements, typically performed using certified standards. For temperature accuracy, Curie point standards like (Curie temperature 358 °C) or (153 °C) are employed, as their magnetic transitions cause detectable mass changes at known points. serves as a practical standard for verifying both temperature and mass loss profiles due to its well-characterized multi-step dehydration and decomposition, aligning with guidelines for temperature scale calibration. Calibrations are recommended upon instrument installation, after modifications, or periodically—such as weekly in high-use labs—to maintain accuracy within ±1 °C and ±0.1% for mass. Optimization of these parameters involves trade-offs to achieve desired analytical outcomes. Slower heating rates enhance resolution by allowing better separation of overlapping events but may reduce sensitivity to minor mass changes, whereas faster rates improve throughput yet cause peak broadening and shifts in decomposition temperatures due to kinetic limitations. Atmosphere flow rates are adjusted to balance convective heat transfer and gas removal efficiency, with higher flows potentially sharpening peaks but risking sample displacement in light powders. Overall, parameters are tailored iteratively, often starting with standard conditions (e.g., 10 °C/min in at 50 mL/min) and refined based on preliminary scans to optimize signal-to-noise ratios.

Data Interpretation

Thermograms and their features

A thermogram in (TGA) is a graphical representation plotting the sample mass, typically expressed as a percentage of the initial mass, against temperature or time under a controlled atmosphere. This plot, known as the TG curve, illustrates changes due to processes such as evaporation, decomposition, or oxidation. The derivative thermogravimetry (DTG) curve, obtained by differentiating the TG curve, shows the rate of mass change (e.g., %/°C or %/min) and highlights peaks corresponding to the maximum rates of these events, aiding in the identification of overlapping thermal processes. Key features of a TG thermogram include an initial baseline where the mass remains stable, indicating no significant thermal events, followed by discrete mass loss steps that correspond to specific decomposition stages. For instance, low-temperature steps below 200°C often represent dehydration or volatile loss, while higher-temperature steps between 200°C and 600°C typically indicate main chain decomposition. The curve concludes with a final plateau representing the residue, such as inert fillers or char, whose percentage provides insight into the sample's inorganic content. In the DTG curve, these steps appear as peaks, with the peak maximum temperature (T_max) marking the highest decomposition rate. Thermograms can exhibit artifacts that distort the true mass changes, such as buoyancy effects from variations in gas density around the sample, leading to apparent mass gains, or diffusion tails from slow volatile release causing prolonged mass loss. Condensation of evolved gases on cooler parts of the apparatus or electrostatic charges on the balance housing may also contribute to noise or baseline drift. These issues are commonly corrected by performing blank runs under identical conditions to subtract instrumental contributions from the sample data. Characteristic patterns in thermograms reveal material-specific behaviors; for example, a single-step mass loss is typical for pure volatile evaporation, showing a sharp TG drop and a symmetric DTG peak. In contrast, multi-step patterns are common in polymers, such as , where an initial dehydrochlorination step around 250–300°C is followed by further decomposition and charring above 400°C, resulting in two distinct DTG peaks and a residual mass of 10–20%. Software tools integrated with TGA instruments facilitate the analysis of thermograms through automated peak integration, which quantifies the area under DTG peaks to determine the extent of each mass loss event and assigns temperatures to thermal transitions for event identification.

Quantitative analysis methods

Quantitative analysis in thermogravimetric analysis (TGA) involves extracting precise numerical values from thermograms to characterize thermal events, such as decomposition temperatures, mass changes, and reaction kinetics. Onset temperature is determined by extrapolating the initial baseline to the tangent at the point of maximum slope on the TGA curve, marking the start of significant mass loss, while the peak temperature corresponds to the inflection point on the derivative thermogravimetric (DTG) curve where the rate of mass loss is maximum. These parameters shift to higher values with increasing heating rates, providing insights into thermal stability thresholds. Mass loss quantification relies on measuring the height of steps in the TGA curve, which represent the percentage of volatile content released during each decomposition stage, and the residual mass at the end of the experiment, indicating the inorganic or ash fraction. The degree of conversion, \alpha, is calculated as \alpha = \frac{W_0 - W_t}{W_0 - W_f}, where W_0 is the initial mass, W_t is the mass at time t, and W_f is the final residue mass, enabling direct compositional analysis. Kinetic parameters are derived using the Arrhenius equation, k = A \exp\left(-\frac{E_a}{RT}\right), where k is the rate constant, A is the pre-exponential factor, E_a is the activation energy, R is the gas constant, and T is the absolute temperature, integrated into the reaction rate expression \frac{d\alpha}{dt} = k(T) f(\alpha). Isoconversional methods, such as the Friedman approach, provide model-free estimates of E_a by plotting \ln\left(\frac{d\alpha}{dt}\right) versus \frac{1}{RT} at constant \alpha, yielding E_a from the slope without assuming a reaction model; this differential method, introduced in 1969, is sensitive to noise but effective for complex processes. Error sources in quantitative TGA include baseline drift, caused by temperature gradients or gas flow variations in the balance chamber, which distorts mass measurements and requires correction through subtraction of blank runs or instrumental calibration. Reproducibility is assessed via multiple experiments, aiming for relative standard deviation (RSD) below 1% in mass loss values, influenced by sample heterogeneity and heating rate consistency. Advanced kinetic analysis contrasts model-fitting methods, which assume a specific reaction mechanism like the g(\alpha) = [-\ln(1-\alpha)]^n (where n is the order), fitting parameters to experimental data for mechanistic insights, against model-free approaches like or , which avoid preconceived models to detect multi-step reactions and varying E_a. Model-free methods are preferred for their reliability in complex systems, as model-fitting can lead to correlated parameters and overestimation of simplicity.

Applications

Thermal stability and decomposition studies

Thermogravimetric analysis (TGA) is widely employed to assess the thermal stability of materials by monitoring mass loss as a function of temperature, providing critical insights into the temperatures at which degradation begins. Key metrics for evaluating thermal stability include the temperature at 5% mass loss (T5%) and 10% mass loss (T10%), which serve as indicators of the onset of significant and overall . Additionally, yield, defined as the percentage of residue remaining after complete at high temperatures (typically 800–1000°C), quantifies the stability of the non-volatile fraction and is particularly useful for materials intended for high-temperature applications. Decomposition mechanisms revealed by TGA often occur in distinct stages, reflecting the chemical processes involved in material breakdown. Endothermic processes, such as or volatilization of low-molecular-weight components, typically manifest as initial mass loss steps at lower temperatures, while exothermic reactions like oxidation or cross-linking dominate higher-temperature regimes, leading to more abrupt weight changes. In composite materials, multi-stage decomposition is common, where each corresponds to the sequential of individual constituents, allowing identification of breakdown pathways without direct calorimetric data. In , TGA demonstrates that engineering plastics exhibit high thermal stability with T5% values exceeding 300°C under inert atmospheres, enabling their use in demanding environments like aerospace components. For pharmaceuticals, TGA evaluates stability up to processing temperatures (often 150–250°C), ensuring active ingredients remain intact during ; for instance, studies on drug-polymer blends confirm decomposition thresholds that guide and conditions. Several factors influence the thermal stability observed in TGA experiments. Additives, such as fillers or flame retardants, can enhance stability by promoting formation or inhibiting volatile release in matrices. The atmosphere plays a pivotal role: inert gases like preserve material integrity by preventing oxidation, resulting in higher yields compared to oxidative environments (e.g., air), where exothermic accelerates mass loss and reduces residue. Standardized protocols ensure reproducible assessment of decomposition temperatures and stability endpoints. The ASTM E1131 method outlines procedures for compositional analysis via TGA, including guidelines for determining onset and volatile content, which are essential for comparing thermal performance across materials.

Compositional and purity analysis

Thermogravimetric analysis (TGA) enables the determination of material composition by quantifying sequential mass losses associated with different components during controlled heating. In proximate analysis, a standard approach for carbonaceous materials such as coal, the procedure typically involves determining moisture content by heating to approximately 107°C in an inert atmosphere, volatile matter by further heating to 900–950°C in inert gas (with a hold time), followed by switching to an oxidative atmosphere (e.g., air) to burn off fixed carbon and measure the remaining ash residue; fixed carbon is then calculated as the difference (100% minus moisture, volatiles, and ash). This provides a breakdown of the sample's major fractions. Purity assessment via TGA involves monitoring for unexpected mass loss events that indicate impurities, as pure materials exhibit predictable decomposition profiles. For instance, in organic compounds, a residue below 1% after complete volatilization suggests high purity, while deviations signal contaminants such as residual solvents or inorganic fillers. In ceramics processing, TGA quantifies burnout by measuring the mass loss percentage due to organic additives, typically 5–20% depending on the formulation, ensuring complete removal before . For pharmaceuticals, TGA determines active pharmaceutical ingredient () to excipient ratios by comparing mass losses in mixtures, such as : at 1:5, where distinct steps reveal compositional proportions. In fuels like , ASTM D7582 uses TGA to measure volatile matter content, often 20–40%, as a key indicator of and composition. For multi-component systems with overlapping mass loss steps, derivative thermogravimetry (DTG) aids in , separating peaks to assign individual contributions from components like polymers or fillers. Limitations of TGA in compositional analysis include the assumption of additive mass losses, which may not hold if components interact during heating, and the potential for low-boiling volatiles to escape undetected at ambient conditions before analysis begins.

Coupled Techniques

TGA coupled with spectroscopy

TGA coupled with spectroscopy, particularly Fourier transform infrared (FTIR) spectroscopy, integrates thermogravimetric analysis (TGA) with real-time identification of evolved gases to provide detailed insights into decomposition processes. The setup typically involves connecting the TGA furnace exhaust to the FTIR gas cell via a heated transfer line maintained at 180–250°C to prevent condensation of volatile products. This interface allows the carrier gas stream, carrying the evolved species from the sample, to flow directly into the FTIR's long-path gas cell, where infrared spectra are recorded continuously as the temperature increases. The primary advantage of TGA-FTIR lies in its ability to fingerprint decomposition products through characteristic absorption bands, enabling unambiguous identification of gases that cause mass loss in the TGA curve. For instance, (CO₂) exhibits a strong asymmetric stretch at approximately 2350 cm⁻¹, while (H₂O) shows a broad O-H stretch around 3400 cm⁻¹; these peaks allow differentiation between processes like and , which might otherwise appear as similar mass loss events in standalone TGA. (NH₃) is identified by N-H stretching bands near 3330 cm⁻¹ and bending modes at 930–965 cm⁻¹. This spectroscopic resolution addresses limitations in TGA alone by specifying the chemical nature of volatiles, thus clarifying ambiguous thermogravimetric data. In polymer studies, TGA-FTIR has been instrumental in analyzing pyrolysis products; for example, the thermal degradation of at around 350°C releases , detectable by its aromatic C-H stretches at 3000–3100 cm⁻¹ and C=C ring vibrations at 1450–1600 cm⁻¹, alongside minor and . For inorganic materials, the technique identifies evolution during decomposition starting at 160°C, where NH₃ peaks intensify above 193°C, correlating with the initial mass loss stage to 40–50% of the sample weight. These examples highlight how TGA-FTIR elucidates reaction mechanisms by linking specific gas releases to temperature regimes. Data from TGA-FTIR experiments are often correlated by overlaying the mass loss () curve with plots of absorbance intensity versus for key bands, revealing the onset, , and of individual gas in synchrony with thermal events. This visual integration facilitates quantitative assessment of and product yields, such as the relative intensities of CO₂ and H₂O bands to quantify versus steps. Such correlations enhance the interpretative power of the for complex multi-step decompositions.

TGA coupled with mass spectrometry

Thermogravimetric analysis (TGA) coupled with (TGA-MS) employs a hyphenated setup where the evolved gases from the TGA furnace are transferred directly to the via a heated or skimmer , ensuring vacuum compatibility and minimizing dilution or of volatiles. The , typically made of or and heated to 150–300 °C, connects the TGA outlet to the MS ionization chamber, often using as a carrier gas to facilitate rapid gas transport. Common mass analyzers include systems for routine m/z scanning up to 300 amu or time-of-flight (TOF) instruments for higher resolution, achieving detection limits in the parts-per-billion (ppb) range for trace volatiles. In TGA-MS analysis, evolved gases are ionized (typically by electron impact at 70 eV) and separated by (m/z), producing peaks that identify specific species; for instance, m/z 44 corresponds to CO₂, m/z 18 to H₂O, and m/z 64 to SO₂. Fragmentation patterns from complex molecules aid identification, such as m/z 28 and 44 for CO and CO₂ from , or multiple ions (e.g., m/z 48 and 32) for compounds, often compared against NIST libraries for unambiguous assignment. This real-time monitoring correlates gas evolution with mass loss events in the TGA thermogram, revealing decomposition mechanisms. Quantitative analysis in TGA-MS relies on calibration with standard gases (e.g., known flows of CO₂ or H₂O at 100 mL/min against reference) to determine relative sensitivities and mass flow rates via methods like equivalent characteristic spectrum analysis (ECSA), which deconvolutes overlapping peaks and corrects for mass discrimination. This enables precise quantification of evolved , with sensitivity sufficient for detecting trace impurities at levels, as demonstrated in the of CaCO₃ yielding CO₂ (m/z 44) with accuracy validated against theoretical yields. Representative applications include environmental samples, where TGA-MS detects SO₂ (m/z 64) evolution from in aged diesel , aiding assessment of atmospheric transformation. In battery materials, TGA-MS identifies species (m/z 19) and other volatiles from and degradation, such as LiPF₆ above 200 °C producing PF₅ and HF-related fragments, informing safety and stability evaluations. Challenges in TGA-MS include potential interface clogging by condensable vapors (e.g., water or organics), mitigated by heated lines but requiring regular maintenance to avoid signal attenuation. Data visualization often involves specialized software like ® for generating 3D plots of ion current intensity versus m/z and , facilitating of multi-dimensional datasets but demanding computational resources for complex spectra.

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