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Temperature measurement, differential scanning

The solid-liquid transition temperatures of ionic liquids can (ideally) be below ambient and as low as -100 °C. The most efficient method for measuring the transition temperatures is differential scanning calorimetry (DSC). Other methods that have been used include cold-stage polarizing microscopy, NMR, and X-ray scattering. [Pg.43]

Differential thermal analysis (DTA) is a technique in which the temperature difference between the sample tested and a reference material is measured while both are subjected to the controlled temperature program. Differential scanning calorimetry (DSC) is a technique in which the heat flow difference between the sample and reference material is monitored while both are subjected to the controlled temperature program. Thermogravimetric analysis (TGA) is a technique in which the weight of a sample is monitored during the controlled temperature program. [Pg.424]

Schawe, J. E. K. (1998). A description of the glass transition measured by temperature modulated differential scanning calorimetry. Colloid Polym. Sci. 276(7), 565-569. [Pg.834]

For the examinations three different mono- and multifilament PET-yams were used. As seen by the effective temperature two of the fibers (220 dtex multifil and 360 monofil) were heat setted in air at 160°C. The experiments in air and supercritical C02 were carried out in a 400 ml autoclave, the DSC measurements (Differential Scanning Calorimetry) under pressure in a home-made apparatus with an integrated TA-Instruments calorimeter. [Pg.581]

Although a large number of thermal analysis techniques have been developed, the most commonly applied are those of thermogravimetry (TG, the measure of thermally induced weight loss of a material as a function of applied temperature), differential thermal analysis (DTA, the difference in temperature existing between a sample and a reference as a function of temperature), and differential scanning calorimetry (DSC, the difference in heat capacity between the sample and... [Pg.2941]

Figm 13 (a) Sequence and schematic representation of the self-assembly of an amphiphilic diblock elastin polypeptide into core-shell nanoparticles. Elastin-mimetic protein polymers that comprise fusions of elastin sequences with different 7, values can be induced to undergo self-assembly at a temperature between the two transition temperatures, (b) Differential scanning calorimetry measurements indicate an endothermic transition for the more hydrophobic (lower 7 block with a value that corresponds to those observed for the burial of hydro-phobic residues within a folded protein, (c) This transition coincides with the formation of spherical assemblies in which the more hydrophobic block is confined within the micellar core. Transmission electron microscopy measurements are consistent with spherical micelles and more complex assemblies. Reprinted from Lee, T. A. T. Cooper, A. Apkarian, R. P. Conticello, V. P. Adv. Mater. 2000, f2(15), Copyright 2000, with... [Pg.94]

Pyda et al. (1998) studied in detail the heat capacity of PTT by adiabatic calorimetry, standard DSC and temperature-modulated differential scanning calorimetry (TMDSC) for this measurement. The computation of the heat capacity of solid PTT is based on an approximate group vibrational spectrum and the general Tarasov approach for the skeletal vibrations, using the well-established Advanced Thermal Analysis System (ATHAS) scheme. The experimental heat capacity at constant pressure is first converted to heat capacity at constant volume using the Nemst-Lindemann approximation... [Pg.579]

HOhne GWH, Kurelec L (2001) Temperature-modulated Differential Scanning Calorimetric Measurements on Nascoit Ultra-high Molecular Mass Polyethylene. Thermochim Acta 377 141-150. [Pg.704]

Calorimetric studies have depicted the impact of nanoparticles on isothermal curing of epoxy-amine system. Isothermal measurements done at 298 K using temperature-modulated differential scanning calorimetry are shown in Figure 9.15. The heat flow signal recorded during this measurement is directly proportional to the reaction rate of the curing process. It was foxmd that,... [Pg.287]

Microcalorimetric Measurements. Differential scanning calorimetry was performed with a Microcal MC 2 DSC microcalorimeter. The samples, prepared as described above, were analyzed using a heating rate of. 0.75°C min-1 in the temperature range of 10 to 40°C for DMPC liposomes and 25 to 65°C for DSPC liposomes. [Pg.218]

The sample (or furnace) temperature is controlled to follow a set course with superimposed periodical changes, and the heat flow rate is measured via the differential temperature between sample and reference (temperature-modulated differential scanning calorimetry, TMDSC [38]). [Pg.838]

Figure 11 Relaxation map for PS where the data were taken from Weyer, S. Hensel, A. Korus, J. etal. Thermochim. Acta 1997, 304/305, 251. A-Datafrom temperature modulated differential scanning calor-Imentry as measured at different places o, data measured by specific heat spectroscopy by employing the 3o method , AC calorimetry , data measured by photoacoustic calorimetry , dielectric data dashed line, data from shear compliance dotted-dotted-dashed line, data from shear modulus solid line, fit of the VF equation using all thermal data dotted line, fit of the VF,equation using the dielectric data. Figure 11 Relaxation map for PS where the data were taken from Weyer, S. Hensel, A. Korus, J. etal. Thermochim. Acta 1997, 304/305, 251. A-Datafrom temperature modulated differential scanning calor-Imentry as measured at different places o, data measured by specific heat spectroscopy by employing the 3o method , AC calorimetry , data measured by photoacoustic calorimetry , dielectric data dashed line, data from shear compliance dotted-dotted-dashed line, data from shear modulus solid line, fit of the VF equation using all thermal data dotted line, fit of the VF,equation using the dielectric data.
Glass transition temperature measurements on the solutions of Zdol in PFOM were performed in a temperature-modulated differential scanning calorimeter. [Pg.62]

As previously mentioned in 2.1, ASTM standard E473 defines differential scanning calorimetry (DSC) as a technique in which the heat flow rate difference into a substance and a reference is measured as a function of temperature while the substance and reference are subjected to a controlled temperature program. It should be noted that the same abbreviation, DSC, is used to denote the technique (differential scanning calorimetry) and the instrument performing the measurements (differential scanning calorimeter). [Pg.18]

The melting temperature for samples of isotactic polypropylene was measured as a function of temperature using differential scanning calorimetry. The following data were obtained for fully crystallized samples ... [Pg.109]

Poly(propylene oxide) polyols also form complexes with potassium and sodium thiocyanate. Teeters and coworkers (33) used glass transition temperatures from differential scanning calorimetry (DSC) measurements to investigate the complexation of a 3000-molecular-weight triol with these alkali metal salts. The results indicated that at least 10 ether atoms per cation were required for formation of stable complexes. [Pg.166]

Temperature-modulated differential scanning calorimetry (T-MDSC) applies a thermal modulation in temperature to a conventional DSC mn and determines a dynamic heat capacity from the relationship between the modulation components of temperature and of heat flow. Primary application of this technique has been the measurement of specific heat capacity and the examination of the anomaly in a relaxation process such as alpha process related to the glass transition. An application to the first-order phase transitions of crystallisation and melting of polymer crystals has recently been suggested. The method and typical results are described. 13 refs. [Pg.81]

METHOD FOR ANALYSIS OF THE MEASURED CURVES OF TEMPERATURE-MODULATED DIFFERENTIAL SCANNING CALORIMETRY(TMDSC) INVESTIGATION IN THE MELTING REGION OF POLYMERS Schawe J E K Bergmann E Winter W Ulm,University IFA GmbH... [Pg.102]

The product must be formulated and frozen in a manner which ensures that there is no fluid phase remaining. To achieve this, it is necessary to cool the product to a temperature below which no significant Hquid—soHd phase transitions exist. This temperature can be deterrnined by differential scanning calorimetry or by measuring changes in resistivity (94,95). [Pg.530]

Glass-transition temperatures are commonly determined by differential scanning calorimetry or dynamic mechanical analysis. Many reported values have been measured by dilatometric methods however, methods based on the torsional pendulum, strain gauge, and refractivity also give results which are ia good agreement. Vicat temperature and britde poiat yield only approximate transition temperature values but are useful because of the simplicity of measurement. The reported T values for a large number of polymers may be found ia References 5, 6, 12, and 13. [Pg.260]

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