1、Designation: E2105 00 (Reapproved 2016)Standard Practice forGeneral Techniques of Thermogravimetric Analysis (TGA)Coupled With Infrared Analysis (TGA/IR)1This standard is issued under the fixed designation E2105; the number immediately following the designation indicates the year oforiginal adoption
2、 or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This practice covers techniques that are of general use inthe qualitative an
3、alysis of samples by thermogravimetric analy-sis (TGA) coupled with infrared (IR) spectrometric techniques.The combination of these techniques is often referred to asTGA/IR.1.2 A sample heated in a TGA furnace using a predeter-mined temperature profile typically undergoes one or moreweight losses. M
4、aterials evolved during these weight losses arethen analyzed using infrared spectroscopy to determine chemi-cal identity. The analysis may involve collecting discreteevolved gas samples or, more commonly, may involve passingthe evolved gas through a heated flowcell during the TGAexperiment. The gene
5、ral techniques of TGA/IR and othercorresponding techniques, such as TGA coupled with massspectroscopy (TGA/MS), as well as, TGA, used in conjunctionwith GC/IR, are described in the referenced literature (1-4).21.3 Some thermal analysis instruments are designed toperform both thermogravimetric analys
6、is and differential scan-ning calorimetry simultaneously. This type of instrument issometimes called a simultaneous thermal analyzer (STA). Theevolved gas analysis performed with an STA instrument (5) issimilar to that with a TGA, and so, would be covered by thispractice. With use of a simultaneous
7、thermal analyzer, thecoupled method typically is labeled STA/IR.1.4 The values stated in SI units are to be regarded asstandard. No other units of measurement are included in thisstandard.1.5 This statement does not purport to address all of thesafety concerns, if any, associated with its use. It is
8、 theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:3E131 Terminology Relating to Molecular SpectroscopyE168 Practices for General Techn
9、iques of Infrared Quanti-tative AnalysisE334 Practice for General Techniques of Infrared Micro-analysisE473 Terminology Relating to Thermal Analysis and Rhe-ologyE1131 Test Method for Compositional Analysis by Thermo-gravimetryE1252 Practice for General Techniques for Obtaining Infra-red Spectra for
10、 Qualitative AnalysisE1421 Practice for Describing and Measuring Performanceof Fourier Transform Mid-Infrared (FT-MIR) Spectrom-eters: Level Zero and Level One Tests3. Terminology3.1 DefinitionsFor general definitions of terms andsymbols, refer to Terminologies E131 and E473.3.2 Definitions of Terms
11、 Specific to This Standard:3.2.1 evolved gas, nany material (or mixture) evolvedfrom a sample during a thermogravimetric or simultaneousthermal analysis experiment. Materials evolved from thesample may be in the form of a gas, a vapor, an aerosol or asparticulate matter. For brevity, the term “evolv
12、ed gas” will beused throughout this practice to indicate any material form ormixture evolved from a sample.3.2.2 evolved gas analysis (EGA), na technique in whichthe nature and amount of gas evolved from a sample ismonitored against time or temperature during a programmedchange in temperature of the
13、 sample.3.2.3 evolved gas profile (EGP), nan indication of thetotal amount of gases evolved, as a function of time ortemperature, during the thermogravimetric experiment. InTGA/IR, this profile is calculated from the infrared spectro-scopic data recorded by application of the Gram-Schmidt1This pract
14、ice is under the jurisdiction of ASTM Committee E13 on MolecularSpectroscopy and Separation Science and is the direct responsibility of Subcom-mittee E13.03 on Infrared and Near Infrared Spectroscopy.Current edition approved April 1, 2016. Published June 2016. Originallyapproved in 2000. Last previo
15、us edition approved in 2010 as E2105 00 (2010).DOI: 10.1520/E2105-00R16.2The boldface numbers in parentheses refer to a list of references at the end ofthis standard.3For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual B
16、ook of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States1reconstruction (GSR) algorithm (6,7). Because the GSR wasdesigned for use in gas
17、chromatography coupled with infrared(GC/IR) analysis, the evolved gas profile has sometimes beenerroneously called the evolved gas chromatogram.3.2.4 functional group profile (FGP), nan indication ofthe amount of gas evolved during the thermogravimetricexperiment that contains a particular chemical
18、functionalitymeasured as a function of time or temperature. This profile iscalculated from the infrared spectroscopic data recorded byintegration of the absorbances over selected spectral regions asthe experiment progresses. Typically, a number of such profilesare calculated in real-time. Additional
19、 profiles (using differentspectral regions) can often be calculated after the experimentfrom the stored spectroscopic data. Because the software usedhas similarities with that used for GC/IR analysis, the func-tional group profile has sometimes been erroneously called thefunctional group chromatogra
20、m.3.2.5 hit quality index (HQI), nthe numerical ranking ofinfrared reference spectra against that of an analyte spectrumthrough the use of search algorithms that measure a compara-tive fit spectral data.3.2.6 specific gas profile (SGP), na special type of func-tional group profile arises when the se
21、lected region of thespectrum contains absorbances due to a specific gas such asammonia or carbon monoxide.4. Significance and Use4.1 This practice provides general guidelines for the prac-tice of thermogravimetry coupled with infrared spectrometricdetection and analysis (TGA/IR). This practice assum
22、es thatthe thermogravimetry involved in the practice is proper. It isnot the intention of this practice to instruct the user on properthermogravimetric techniques. Please refer to Test MethodE1131 for more information.5. General TGA/IR Techniques5.1 Two different types of TGA/IR techniques are used
23、toanalyze samples. These consist of discrete evolved gas trap-ping and use of a heated flowcell interface. It should be notedthat only the latter technique allows for the calculation of theevolved gas and functional group profiles.5.2 Evolved Gas Trapping TechniquesEvolved gas trap-ping techniques a
24、re the least elaborate means for obtainingTGA/IR data. In these techniques, the evolved gas is collectedfrom the TGA furnace in discrete aliquots that are thenanalyzed. In use of such techniques, it is essential to monitorthe TGA weight loss curve to determine the time or tempera-ture at which the e
25、ffluent was captured. Vapor phase samplescan be trapped in a heated low-volume gas cell at the exit of theTGA, analyzed, then flushed out by the TGA effluent. Whenthe next aliquot of interest is in the gas cell, the flow is stoppedagain for analysis. This process can be made more convenientby design
26、ing the TGA temperature profile such that thetemperature is held constant while a trapped sample is beinganalyzed (ramp-and-hold method). Alternatively, fractions canbe trapped in the condensed phase by passing the TGAeffluentthrough a solvent, a powdered solid, or a cold trap to yieldcondensed phas
27、e material for subsequent analysis (8). Infraredspectrometry is performed with either a monochromator, afilter spectrometer or a Fourier transform spectrometer. Seealso Practices E334 and E1252 for general techniques onmicroanalysis and qualitative practices.5.2.1 Since the analyte of interest is st
28、atic when employingan evolved gas trapping technique, the spectrum can berecorded using a long integration time or increasing scanco-addition to improve the signal-to-noise ratio (SNR).However, in vapor phase evolved gas trapping, the sampleintegrity can be compromised by slow decomposition or bydep
29、osition on the cell walls. A spectrum should be obtainedinitially within a short co-addition time to create a referencespectrum to ensure the integrity of the spectrum obtained afterlong co-addition.5.3 Evolved Gas Analysis Using a FlowcellAnother wayto examine the gases evolved during a TGA/IR expe
30、riment isto use a specially designed flowcell. This flowcell is situated inthe IR beam of the infrared spectrometer. IR monochromatorsand filter spectrometers are typically used to monitor a specificfrequency range during the TGAexperiment. If a full spectrumis to be obtained with these IR devices,
31、the evolved gas istrapped via a stopped flow routine and the spectrometers arepermitted to scan the infrared spectrum. In contrast, the Fouriertransform IR spectrometer permits the acquisition of thecomplete IR spectrum in brief timeframes without impact uponthe typical TGA experiment, that is, cont
32、inuous spectralcollection without interruption of evolved gas flow or sampleheating.5.3.1 In the typical TGA/IR experiment, the evolved gas ismonitored in real-time by the IR spectrometer. The temporalresolution required during aTGA/IR experiment is on the orderof 560 s/spectral data acquisition eve
33、nt. If the full IRspectrum is to be acquired, the rapidity of the TGAexperimentrequires a Fourier-transform infrared (FT-IR) spectrometer tomaintain sufficient temporal resolution. Such instruments in-clude a computer that is capable of storing large amounts ofspectroscopic data for subsequent evalu
34、ation.5.3.2 Some spectrometer data systems may have limitedsoftware, or data storage capabilities. Such instrument systemsare capable of recording suitable spectra during the TGA/IRexperiment, but may not be able to calculate the evolved gasand functional group profiles.5.3.3 The flowcell is coupled
35、 directly to the TGA via aheated transfer line. Evolved gas components are analyzed asthey emerge from the transfer line. This technique typicallyyields low microgram detection limits for most analytes (1).Instruments that include the IR spectrometer, data system, thethermogravimetric analyzer, heat
36、ed transfer-line, and heatedflowcell are commercially available.5.3.4 It should be noted that any metal surface inside theTGA furnace, transfer line or flowcell assembly may reactwith, and sometimes destroy, specific classes of evolved gases,for example, amines. This can result in changes to the che
37、micalnature of the evolved gas. Consequently, it is possible to fail toidentify the presence of such compound in the mixture. Thissituation can sometimes be identified by comparison of theTGA weight loss profile with the evolved gas profile.E2105 00 (2016)25.3.5 The infrared energy throughput of the
38、 flowcell shouldbe periodically monitored since this indicates the overallcondition of this assembly. It is important that all tests beconducted at a constant flowcell temperature because of theeffect of the emitted energy on the detector (see 6.3.1). It isrecommended that records be kept of the int
39、erferogram signalstrength, single-beam energy response and the ratio of twosuccessive single-beam curves (as appropriate to the instru-ment used). For more information on such tests, refer toPractice E1421. If a mercury-cadmium-telluride (MCT) detec-tor is being employed, these tests will also revea
40、l degradationof performance due to loss of the Dewar vacuum and conse-quent buildup of ice on the detector face. In general, when aloss of transmitted energy greater than 10 % of the total energyis found, cleaning of the flowcell is recommended.5.3.6 Care must be taken to stabilize or, preferably, r
41、emoveinterfering spectral features that result from atmospheric ab-sorptions in the IR beam path of the spectrometer. Best resultswill be obtained by purging the entire optical path of thespectrometer with dry nitrogen gas. Alternatively, dry air canbe used as the spectrometer purge gas; however, th
42、is will leadto interferences in the regions of carbon dioxide absorption(2500 go 2200 cm1and 720 to 620 cm1) due to the presenceof carbon dioxide in air. Further, commercially-available airscrubbers, that remove both water vapor and carbon dioxide,provide adequate purging of the spectrometer. In som
43、einstruments, the beam path is sealed in the presence of adesiccant, but interferences from both carbon dioxide andwater vapor (1900 to 1400 cm1) may be found. Similarly, theTGA furnace, the transfer line and the gas cell interface arepurged with a gas that does not absorb infrared energy.Typically,
44、 this TGA purge gas is inert (nitrogen or helium) andhas a flow rate from 10 to 200 mL/min. Occasionally, oxidizingor reducing atmospheres, that is, oxygen or hydrogenrespectively, are used with the TGA to promote specificchemical reactions. When preparing for a TGA/IR experiment,the atmospheres wit
45、hin the spectrometer and within the furnaceand gas cell combination must be allowed to stabilize beforespectral data collection and the thermal experiment commenceto minimize spectral interferences. Atmospheric stability forthe experiment can be judged by recording the single-beamenergy response and
46、 the ratio of two successive single-beamspectra over a discrete time interval.5.3.6.1 The spectral features of both carbon dioxide and,more importantly, water vapor depend upon the temperature atwhich they were measured. This can become an awkwardproblem in TGA/IR analysis, as many samples evolve th
47、esegases as they are heated. It may be necessary to identify thesemolecules in the heated flowcell when there is a possiblebackground absorbance from molecules close to room tem-perature in the spectrometer and interface. It is particularlydifficult to use spectral subtraction techniques (see Practi
48、ceE1252) to compensate for the presence of water vapor in thespectrum under these conditions. The significance of thisproblem is demonstrated by the attempt to identify the presenceof a trace amount of a carbonyl compound when spectralfeatures due to water vapor also are observed.6. Component Design
49、 Considerations for TGA/IR Usinga Flowcell6.1 Transfer LineA transfer line from the TGA to theflowcell must present an inert, nonporous surface to theevolved gas. Evolved gas transfer lines must be heated totemperatures sufficient to prevent condensation of the evolvedgas species. Typically, the transfer line is constructed of anarrow-bore steel tube that has either a removable liner or iscoated internally with silica. The temperature of the transferline is normally held constant during an experiment at a levelchosen to avoid both condensation and degradation of theevo
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