Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Standard

Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections. / Quick, C. R.; Schawe, J. E.K.; Uggowitzer, P. J. et al.
in: Thermochimica Acta, Jahrgang 677.2019, Nr. June, 13.06.2019, S. 12-20.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Harvard

Quick, CR, Schawe, JEK, Uggowitzer, PJ & Pogatscher, S 2019, 'Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections', Thermochimica Acta, Jg. 677.2019, Nr. June, S. 12-20.

APA

Quick, C. R., Schawe, J. E. K., Uggowitzer, P. J., & Pogatscher, S. (2019). Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections. Thermochimica Acta, 677.2019(June), 12-20.

Vancouver

Quick CR, Schawe JEK, Uggowitzer PJ, Pogatscher S. Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections. Thermochimica Acta. 2019 Jun 13;677.2019(June):12-20.

Author

Quick, C. R. ; Schawe, J. E.K. ; Uggowitzer, P. J. et al. / Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections. in: Thermochimica Acta. 2019 ; Jahrgang 677.2019, Nr. June. S. 12-20.

Bibtex - Download

@article{d0a126883d8a43d9b356fbed566e3ee4,
title = "Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections",
abstract = "This study explores specific heat capacity (c p ) measurements via fast scanning calorimetry, with a focus on correcting measured heat flow by accounting for temperature dependent heat losses. Using MultiSTAR-UFS1 sensors with the Mettler-Toledo Flash-DSC 2+, c p of Pb (99.998% purity) was measured in dependence of the sample mass and scanning rate. Masses from 0.3–5 μg were evaluated at rates of 100, 1000 and 2000 K s −1 in the temperature range −20 to 320 °C. Two correction methods are shown and compared to c p results without corrections. Heat loss corrections are mandatory when measuring c p , but are in particular important for low masses and rates. High consistency was found between the two proposed correction procedures giving good confidence in their viability. A slight but consistent overestimation of c p compared to literature casts uncertainty upon the determined sample mass. Whilst the systems under study in this work encompass only pure Pb, the arguments and procedures of the shown method of c p determination are applicable to any system in the absence of physical transformations.",
keywords = "Chip calorimetry, Fast scanning calorimetry, Metals, Specific heat capacity",
author = "Quick, {C. R.} and Schawe, {J. E.K.} and Uggowitzer, {P. J.} and S. Pogatscher",
year = "2019",
month = jun,
day = "13",
language = "English",
volume = "677.2019",
pages = "12--20",
journal = "Thermochimica Acta",
issn = "0040-6031",
publisher = "Elsevier",
number = "June",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Measurement of specific heat capacity via fast scanning calorimetry—Accuracy and loss corrections

AU - Quick, C. R.

AU - Schawe, J. E.K.

AU - Uggowitzer, P. J.

AU - Pogatscher, S.

PY - 2019/6/13

Y1 - 2019/6/13

N2 - This study explores specific heat capacity (c p ) measurements via fast scanning calorimetry, with a focus on correcting measured heat flow by accounting for temperature dependent heat losses. Using MultiSTAR-UFS1 sensors with the Mettler-Toledo Flash-DSC 2+, c p of Pb (99.998% purity) was measured in dependence of the sample mass and scanning rate. Masses from 0.3–5 μg were evaluated at rates of 100, 1000 and 2000 K s −1 in the temperature range −20 to 320 °C. Two correction methods are shown and compared to c p results without corrections. Heat loss corrections are mandatory when measuring c p , but are in particular important for low masses and rates. High consistency was found between the two proposed correction procedures giving good confidence in their viability. A slight but consistent overestimation of c p compared to literature casts uncertainty upon the determined sample mass. Whilst the systems under study in this work encompass only pure Pb, the arguments and procedures of the shown method of c p determination are applicable to any system in the absence of physical transformations.

AB - This study explores specific heat capacity (c p ) measurements via fast scanning calorimetry, with a focus on correcting measured heat flow by accounting for temperature dependent heat losses. Using MultiSTAR-UFS1 sensors with the Mettler-Toledo Flash-DSC 2+, c p of Pb (99.998% purity) was measured in dependence of the sample mass and scanning rate. Masses from 0.3–5 μg were evaluated at rates of 100, 1000 and 2000 K s −1 in the temperature range −20 to 320 °C. Two correction methods are shown and compared to c p results without corrections. Heat loss corrections are mandatory when measuring c p , but are in particular important for low masses and rates. High consistency was found between the two proposed correction procedures giving good confidence in their viability. A slight but consistent overestimation of c p compared to literature casts uncertainty upon the determined sample mass. Whilst the systems under study in this work encompass only pure Pb, the arguments and procedures of the shown method of c p determination are applicable to any system in the absence of physical transformations.

KW - Chip calorimetry

KW - Fast scanning calorimetry

KW - Metals

KW - Specific heat capacity

M3 - Article

AN - SCOPUS:85063410160

VL - 677.2019

SP - 12

EP - 20

JO - Thermochimica Acta

JF - Thermochimica Acta

SN - 0040-6031

IS - June

ER -

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