A New Method for the Quantification and Correction of Thermal Effects on the Realization of Fixed Points

Fahr, Martin; Rudtsch, Steffen

doi:10.1007/s10765-007-0351-3

Cited by 15 publications

(30 citation statements)

References 9 publications

(11 reference statements)

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“…The 1.5 µK uncertainty due to the hydrostatic pressure is determined by the product of half the calculated liquid height within the cell and the temperature variation with depth of the neon triple-point temperature (1.9 mK·m -1 ) [1]. The uncertainty due to stray heat flux is estimated from the sensitivity of the plateau temperature to changes in the control set-point of the cryostat shield near the fixed-point cell [13]. Ne sample.…”

Section: Measurement Uncertaintymentioning

confidence: 99%

Triple-Point Temperatures of 20Ne and 22Ne

Hill

Fahr

2011

Int J Thermophys

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Section: Measurement Uncertaintymentioning

confidence: 99%

Triple-Point Temperatures of 20Ne and 22Ne

Hill

Fahr

2011

Int J Thermophys

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“…While a poor fixed-point initiation is evident in a slow recovery from recalescence and from sensitivity to the furnace temperature, there are no guidelines or criteria for the development of initiation procedures. The furnace oscillation test [26] provides a good test of the completeness of the phase boundary, but the test has not yet been applied to the evaluation of different initiation procedures.…”

Section: Initiation Of Freezing Pointsmentioning

confidence: 99%

Uncertainties in the SPRT Subranges of ITS-90: Topics for Further Research

White¹,

Ballico

Campo

et al. 2010

Int J Thermophys

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The CCT has completed the guide summarizing the uncertainties in the realization of the SPRT subranges of ITS-90 between the triple point of neon (24.5561 K) and the freezing point of silver (961.78 • C). This article identifies aspects of standard platinum resistance thermometry where either data or models are lacking and further research is required. In the calibration of SPRTs, the two main concerns are the need for data on liquidus slopes for the different impurities in the fixed points and improved understanding of the impact of the thermal environment of the fixed point on the realized temperature. In the use of SPRTs, the two largest sources of uncertainty are Types 1 and 3 non-uniqueness and oxidation. The causes of Type 3 non-uniqueness are not yet understood, especially at low temperatures, and there is a paucity of data for the high-temperature subranges. In respect of oxidation, there is a need for validation of the models developed in the 1980s, especially in light of the reduced partial pressure of oxygen used in modern SPRTs. A range of other effects including vacancy effects in SPRTs, isotopic effects in fixed points, and improved statistical methods are discussed.

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“…This requires the lowest possible uncertainties on a level of 0.2 mK or better. It is based on slim fixed-point cells with a sample mass of about 250 g [18].…”

Section: Phase Diagramsmentioning

confidence: 99%

“…This is because of the very low dependence of this maximum temperature on the homogeneity and stability of the furnace temperature. On the other hand, the slopes of freezing and melting curves depend on both the homogeneity of the temperature profile of the furnace and the segregation of impurities [18]. In order to derive complementary information on the segregation of impurities during a fixed-point realization, better understanding and the correction of thermal effects are necessary.…”

Section: Thermal Effectsmentioning

confidence: 99%

“…This shows that the proper determination of the influence of thermal effects on melting by the measurement of immersion characteristics requires detailed investigations and the consideration of transient effects. Recent investigations at PTB have shown that for specific fixed-point cell/furnace combinations, other parts of the freezing curve, and therefore its slope, are considerably influenced by the temperature profile of the furnace [18]. This was demonstrated by using a sequence of stepwise changes of the furnace temperature during a fixedpoint realization.…”

Section: Thermal Effectsmentioning

confidence: 99%

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High-Purity Fixed Points of the ITS-90 with Traceable Analysis of Impurity Contents

et al. 2008

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The International Temperature Scale of 1990 (ITS-90) is based on thermodynamic equilibrium states of ideally pure substances. The largest contribution to the uncertainty budgets of most metallic fixed points is the influence of impurities on the fixed-point temperature. Therefore, a traceable chemical analysis of the remaining impurities with small uncertainty is the basis of further progress. Further requirements are better knowledge of the phase diagrams at very low impurity contents, impurity segregation, and the quantification and correction of thermal effects during a fixedpoint realization. In this article, current and future activities at PTB and BAM in order to develop improved metallic fixed-point cells of the ITS-90 are reviewed.

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A New Method for the Quantification and Correction of Thermal Effects on the Realization of Fixed Points

Cited by 15 publications

References 9 publications

Triple-Point Temperatures of 20Ne and 22Ne

Triple-Point Temperatures of 20Ne and 22Ne

Uncertainties in the SPRT Subranges of ITS-90: Topics for Further Research

High-Purity Fixed Points of the ITS-90 with Traceable Analysis of Impurity Contents

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