Combined DSC and Pulse-Heating Measurements of Electrical Resistivity and Enthalpy of Platinum, Iron, and Nickel

Wilthan, Boris; Cagran, Claus; Pottlacher, Gernot

doi:10.1007/s10765-004-5756-7

Cited by 16 publications

(14 citation statements)

References 21 publications

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“…The temperatures covered by the different optical pyrometers range from 1200 K up to about 5000 K, depending on the actual emissivity of the material under investigation [3]. Thus, the lower temperature limit of the pyrometer of the pulse-heating experiment is also due to the use of a neutral density filter and reaches about 1700 K for titanium and niobium, and about 2300 K for tungsten.…”

Section: Measurementsmentioning

confidence: 99%

“…This issue has already been discussed extensively in Ref. 3. To overcome this limitation and to obtain temperature dependences for these quantities below the onset temperature of the pyrometers, a differential scanning calorimeter (Netzsch DSC 404) was added to our setup and incorporated into the basic measurement routines for data in the temperature range of about 500-1500 K. The DSC is basically designed and used for accurate specific-heat-capacity measurements in the above mentioned temperature range.…”

Section: Introductionmentioning

confidence: 99%

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Combined DSC and Pulse-Heating Measurements of Electrical Resistivity and Enthalpy of Tungsten, Niobium, and Titanium

2005

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Measurements of thermophysical properties such as enthalpy, electrical resistivity, and specific heat capacity as a function of temperature starting from the solid state into the liquid phase for W, Nb, and Ti are presented in this work. An ohmic pulse-heating technique allows measurements of enthalpy and electrical resistivity from room temperature to the end of the stable liquid phase within 60 µs. The simultaneous optical measurement of temperature is limited by the fast pyrometers with an onset temperature of T min = 1200-1500 K; below these temperatures, the fast pyrometers are not sensitive. A differential scanning calorimeter (DSC) is used for determination of the specific heat capacity, and also to obtain enthalpy values in the temperature range of 600-1700 K. Combining the two methods entends the range of values of electrical resistivity and enthalpy versus temperature down to 600 K. Results on the metals W, Nb, and Ti are reported and compared to literature values. This paper is a continuation of earlier work.

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Section: Measurementsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Combined DSC and Pulse-Heating Measurements of Electrical Resistivity and Enthalpy of Tungsten, Niobium, and Titanium

2005

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“…A simple binary alloy system (copper-nickel) with a small melting range and complete miscibility was chosen for this work to investigate different concentrations and to compare the results to properties of both pure elements, which have been extensively investigated by different authors [2][3][4]. The samples were die-cast and drawn to wires of 0.5 mm in diameter.…”

Section: Introductionmentioning

confidence: 99%

“…Specific enthalpy of five Cu-Ni alloys, pure copper[2,3], and pure nickel[4] as a function of temperature; numbers refer to mass% nickel, dashed line: 1750 K (seeFig. 2) Specific enthalpy of five Cu-Ni alloys, pure copper[2,3], and pure nickel[4] at 1750 K (as indicated by the dashed line inFig.…”

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confidence: 99%

“…2) Specific enthalpy of five Cu-Ni alloys, pure copper[2,3], and pure nickel[4] at 1750 K (as indicated by the dashed line inFig. 1) as a function of nickel content; solid line: Specific heat capacity of five Cu-Ni alloys, pure copper[2,3], and pure nickel[4] for the liquid phase as a function of nickel content; solid line: linear interpolation according to Kopp-Neumann rule…”

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Thermophysical Properties of Five Binary Copper–Nickel Alloys

et al. 2010

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Thermophysical properties (e.g., specific enthalpy, heat of fusion, electrical resistivity, thermal volume expansion) are measured in the liquid phase up to very high temperatures by an extreme fast pulse-heating method. Heating rates of about 10 8 K · s −1 are applied by self-heating of wire-shaped metallic specimens with a current of approximately 10,000 A. Pure elements seem to be still close to thermal equilibrium as the obtained results are in good agreement with those obtained by static methods. However, this situation might be different for alloys. The rapid volume heating can shift diffusion-controlled phase transitions at heating to higher temperatures or even make them not noticeable anymore. The simple binary Cu-Ni system was chosen to test the heating rate dependence; this system is well known and shows complete miscibility in the liquid and solid ranges of interest. This study is a further step to test the performance of the fast pulse-heating method being applied to simple and more complex alloys. Measured results of enthalpy, heat of fusion, heat capacity, and electrical resistivity in the vicinity of the melting range are presented. The results of enthalpy and heat capacity agree with simple mixing rules. The measured electrical resistivity of different compositions is compared to results obtained by electromagnetic levitation measurements.

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Thermophysical Properties of Solid and Liquid Ti-6Al-4V (TA6V) Alloy

et al. 2006

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Ti-6Al-4V (TA6V) titanium alloy is widely used in industrial applications such as aeronautic and aerospace due to its good mechanical properties at high temperatures. Experiments on two different resistive pulse heating devices (CEA Valduc and TU-Graz) have been carried out in order to study thermophysical properties (such as electrical resistivity, volume expansion, heat of fusion, heat capacity, normal spectral emissivity, thermal diffusivity, and thermal conductivity) of both solid and liquid Ti-6Al-4V. Fast timeresolved measurements of current, voltage, and surface radiation and shadowgraphs of the volume have been undertaken. At TU-Graz, a fast laser polarimeter has been used for determining the emissivity of liquid Ti-6Al-4V at 684.5 nm and a differential scanning calorimeter (DSC) for measuring the heat capacity of solid Ti-6Al-4V. This study deals with the specific behavior of the different solid phase transitions (effect of heating rate) and the melting region, and emphasizes the liquid state (T >2000 K).

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Combined DSC and Pulse-Heating Measurements of Electrical Resistivity and Enthalpy of Platinum, Iron, and Nickel

Cited by 16 publications

References 21 publications

Combined DSC and Pulse-Heating Measurements of Electrical Resistivity and Enthalpy of Tungsten, Niobium, and Titanium

Combined DSC and Pulse-Heating Measurements of Electrical Resistivity and Enthalpy of Tungsten, Niobium, and Titanium

Thermophysical Properties of Five Binary Copper–Nickel Alloys

Thermophysical Properties of Solid and Liquid Ti-6Al-4V (TA6V) Alloy

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