Selected Electrical Resistivity Values for the Platinum Group of Metals Part I: Palladium and Platinum
Selected Electrical Resistivity Values for the Platinum Group of Metals Part I: Palladium and Platinum
Improved values obtained for liquid phases of palladium and platinum
Electrical resistivity values for both the solid and liquid phases of the platinum group metals (pgms) palladium and platinum are evaluated. In particular improved values are obtained for the liquid phases of these metals. Previous reviews on electrical resistivity which included evaluations for the pgms included those of Meaden (1), Bass (2), Savitskii et al. (3) and Binkele and Brunen (4) as well as individual reviews by Matula (5) on palladium and White (6) on platinum.
Electrical resistivity (ρ) is defined in terms of the International System of Units (SI units) as:
ρ = R A / l (i)
R is the electrical resistance of a uniform specimen of material in ohms (Ω)
A is the cross-sectional area of the specimen in square metres (m2)
l is the length of the specimen in metres (m)
The units of ρ are therefore Ω m although practically the most useful units are μΩ cm.
The measured electrical resistivity (ρ) usually consists of a temperature dependent intrinsic resistivity, ρi, which is due to the pure metal and is caused by the scattering of the charge carriers (electrons or holes) by phonons (quantised vibrations of the lattice) and by their collisions with each other, and a residual resistivity (ρ0) due to impurities which also scatter the carriers and increase the resistivity. The quantity ρ0 is considered to be a summation of the effects of different impurities and is also considered to be temperature independent. The two contributions to the total resistivity are combined according to Matthiessen's Rule: ρ = ρ0 + ρi and because ρ0 may vary from sample to sample then attempts are made to evaluate values of ρi which should be universal for a specific metal.
1.1 Correction for Thermal Expansion Effects
In order to obtain a reference value to which all other measurements are adjusted the electrical resistivity is evaluated at 273.15 K (0ºC).
In the low temperature region below about 30 K the resistivity can be represented by ρ = ρ0 + A T2 + B T5 where the temperature dependent terms represent the intrinsic resistivity, whilst up to room temperature the experimental values are generally given in such a form that interpolation can be achieved by using simple polynomials rather than using the complicated Bloch-Grüneisen formula (7–9). In the definition of resistivity as ρ = R A / l then A and l are usually measured at room temperature and therefore at different temperatures both A and l have to be corrected for thermal expansion effects. It is found below room temperature that for the level of accuracy given for ρ, thermal expansion corrections are generally negligible but at higher temperature the measurements have to be corrected, especially if they are based entirely on the room temperature values for A and l which are usually measured at 293.15 K, the accepted reference temperature for length change measurements:
ρ (corrected) = ρ (uncorrected) [(AT / A293.15) × (I293.15 / IT)] (ii)
= ρ (uncorrected) [1 + (IT − I293.15) / I293.15] (iii)
where Equation (iii) can be considered to be a close approximation of Equation (ii). However since 273.15 K is the actual reference temperature then corrected values of ρ(T) should be further corrected for thermal expansion from 293.15 K to 273.15 K. Since this correction is usually negligible at the level of accuracy given then it is not applied.
In the case of rapid pulse heating to high temperatures, because of inertia l generally is unaltered and it is A that changes. If D is the diameter of the wire then:
ρ (T) = ρ (measured) (DT2 / D293.152) = ρ (measured) (VT / V293.15) (iv)
where VT is the volume of the sample at temperature T and V293.15 is the volume at 293.15 K. These are essentially DT2 and D293.152 respectively since l is assumed to be unaltered.
Palladium has a face-centred cubic structure and the melting point is a secondary fixed point on the International Temperature Scale of 1990 (ITS-90) at 1828.0 ± 0.1 K (10).
Electrical resistivity values for solid palladium at 273.15 K are given in Table I. The selected value is an average of the last three determinations. The ρ0 correction to the measurement of Laubitz and Matsumura (14) was suggested by Matula (5) who also appears to have selected this value as the reference value.
|Authors||Ref.||ρi, μΩ cm||Temperature of data|
|Powell et al.||11||9.79||At 273.15 K. Corrected for ρ0 0.144 μΩ m|
|Powell et al.||12||9.75||Interpolated 200 – 400 K. Corrected for ρ0 0.143 μΩ m|
|White and Woods||13||9.70||At 273.15 K. Average of three samples|
|Laubitz and Matsumura||14||9.760||Interpolated 250–300 K. Corrected for ρ0 0.020 μΩ m|
|Williams and Weaver||15||9.751||At 273.15 K. Corrected for ρ0 0.007 μΩ m|
|Khellar and Vuillemin||16||9.765||Calculated. Fit 17–300 K|
|Selected||9.76 ± 0.01||At 273.15 K|
From 71 data sets for solid palladium Matula (5) selected only the measurements of Schriempf (17) (1.6 K–10.6 K), White and Woods (13) (10 K–295 K) and Laubitz and Matsumura (14) (90 K–1300 K). However it is considered that the values of White and Woods have been superseded by the later high precision measurements of Williams and Weaver (15) (0 K–300 K) and Khellar and Vuillemin (16) (17 K–300 K), with the latter given only in the form of an equation which was evaluated at 17 K and then at 10 K intervals from 20 K to 270 K. The measurements of Williams and Weaver were interpolated above 100 K so as to also obtain a full evaluation at 10 K intervals from 20 K to 270 K. The measurements of Schriempf and of Williams and Weaver agree satisfactorily and were averaged to 10 K with the measurements of Williams and Weaver being extended to 16 K. The measurements of the latter and of Khellar and Vuillemin do not agree below 35 K. However the equation of Khellar and Vuillemin showed peculiar behaviour below this temperature with derived values being 6% higher than those of Williams and Weaver at 17 K but 31% lower at 20 K. Therefore the latter measurements were given preference up to 35 K. At this temperature and above values from the two sets of measurements were averaged. Overall agreement is to within 0.5% between 60 K and 180 K and to within 0.1% above 180 K. The selected values of Matula below 273.15 K are based on a combination of the measurements of White and Woods and of Laubitz and Matsumura and on average the intrinsic values show a bias of 0.02 μΩ cm above the more recently selected values. Other measurements in the low temperature region were discussed by Matula.
In the high temperature region Matula (5) selected only the measurements of Laubitz and Matsumura (14) (90 K–1300 K). After correction for ρ0 = 0.020 μΩ cm the values were calculated at 50 K intervals from 350 to 1300 K. In the present evaluation these measurements were combined with the more recent measurements of Khellaf et al. (18) (295 K–1700 K) which were given in the form of an equation which was also evaluated at 50 K intervals but over the range 350 K to 1750 K. After correction of both sets of measurements for thermal expansion using the values selected by the present author (19) they were fitted to Equation (v) which has an overall accuracy as a standard deviation of ± 0.13 μΩ cm. The two sets of measurements show a maximum disagreement of 1.0% at 1300 K. The equation was extrapolated to the melting point and selected values are given in Table II.
Measurements of Milošević and Babić (20) (250 K–1800 K) were independently corrected for thermal expansion. Their equation differs from the selected equation sinusoidally by trending from initially 0.3% high to 1.7% high at 400 K to 0.9% low at 1400 K to 0.4% high at 1800 K. Figure 1 shows the deviations of the selected values of Matula (which are considered as incorporating the measurements of Laubitz and Matsumura) and the experimental values of Khellaf et al. and Milošević and Babić from the fitted curve. Measurements of Binkele and Brunen (4) (273–1423 K) which were also independently corrected for thermal expansion, showed systematic biases of 1.3% high for runs 1 and 2 and 1.7% high for run 3.
Also in the high temperature region there are a number of other measurements which were published after the review of Matula. After correction for thermal expansion (19) the electrical resistivity measurements of Miiller and Cezairliyan (21) (1400 K–1800 K) trend from 4.0% to 6.9% high whilst the measurement of Pottlacher (22) at the melting point is 5.9% high. Resistivity ratio measurements of García and Löffler (23) (295 K–1100 K) were corrected from RT/R295 to RT/R273.15 and were also corrected for thermal expansion. On this basis the differences reached a maximum of 4.1% high at 450 K but then showed some scatter varying between 1.0% low at 800 K and 1.6% high at 1100 K. Figure 2 shows the deviations of these three sets of measurements from the fitted curve where the resistivity ratios of García and Löffler were converted to electrical resistivity values for comparison purposes.
Electrical resistivity values for palladium at the melting point are given in Table III. In the liquid state neither Dupree et al. (24) (1832 K–1924 K) nor Güntherodt et al. (25) (1864 K–2019 K) obtained evidence for any variation of resistivity with temperature. Although Seydel and Fischer (26) (1825 K–3000 K) did obtain evidence of such a variation, the values of Pottlacher (22) (1828 K–2900 K) were selected and fitted to Equation (vi) with selected values for the electrical resistivity of the liquid and are also given in Table II.
|Authors||Reference||ρS, μΩ cm||ρL, μΩ cm||ρL /ρS||Notes|
|Dupree et al.||24||(48.8)||83.0||1.700||(a)|
|Güntherodt et al.||25||47.3||78.8||1.666|
|Seydel and Fischer||26||50.2||79.1||1.576|
|Khellaf et al.||18||(45.2)||77.3||1.710||(b)|
Notes to Table III
(a) Solid value based on (ρL – ρS)/ ρS = 0.70 ± 0.05
(b) Solid value based on ρL /ρS = 1.71
Platinum has a face-centred cubic structure and the melting point is a secondary fixed point on ITS-90 at 2041.3 ± 0.4 K (10).
The resistance ratio of platinum, WT = RT/R273.15, forms the basis of the International Temperature Scale which White (6) extended to 1300 K and calculated values of intrinsic resistivity using the fixed reference value of 9.82 ± 0.01 μΩ cm at 273.15 K. Above 1300 K White combined the selected values to this temperature with the electrical resistivity measurements of Righini and Rosso (27) (1000 K–2000 K), Laubitz and van der Meer (28) (300 K–1500 K), and Flynn and O’Hagan (29) (273 K–1373 K) and the resistance ratios of Roeser (30) (73 K–1773 K) and Kraftmakher (31) (1000 K–2000 K) together with resistivity measurements given by Martin et al. (32) (300 K–1200 K). White fitted all selected values from 100 K to 2000 K to Equation (vii) which was extrapolated to the melting point. Differences between values derived from this equation and the tabulated values of White as given in Table IV do not exceed 0.01 μΩ cm. An abridged version of the values for the solid phase as given in Table IV was originally given in Platinum Metals Review by Corti (33).
For comparison between these measurements and the selected values as given in Figure 3, the resistivity ratios of Roeser (30) and Kraftmakher (31) were converted to electrical resistivity values and all measurements except those of Flynn and O’Hagan (29) were corrected for thermal expansion using values selected by the present author (34). In addition the measurements of Martin et al. (32) were corrected to correspond to the selected electrical resistivity value at 273.15 K. Because of their larger deviations values of Righini and Rosso (27) are compared with the selected values in Figure 4.
In the case of additional electrical resistivity measurements of Birkele and Brunen (4) (273–1497 K), combined runs 1 and 5 trend from initially 0.8% high to 0.1% high at 1200 K to 0.4% high at 1373 K whilst combined runs 2, 3 and 4 trend to an average of 0.5% low above 1000 K. These trends are also shown in Figure 3.
Electrical resistivity measurements of Pottlacher (22) (473 K–1573 K and 1740 K–2042 K in the solid range) are initially 1% higher then trend to an average of 3% higher between 900 and 1573 K before trending to 1.2% higher and then to 0.5% higher between 1740 K and the melting point. These differences are also shown in Figure 5.
Electrical resistivity values of platinum at the melting point are given in Table V. In the liquid state electrical resistivity measurements of Pottlacher (22) (2042 K–2900 K) were selected as Equation (viii) since in the overlap region they are closely confirmed by measurements of Gathers et al. (36) (2100 K–7300 K) obtained at a pressure of 0.3 GPa which trend from 0.5% low at 2100 K to 1.0% high at 2900 K. Measurements of Hixson and Winkler (37) (2042 K–5100 K) are initially 7% low at the melting point and trend 1% low to 1% high between 2100 K and 2900 K but above 3000 K, in direct comparison with the measurements of Gathers et al., the trend is to an average of 2% low. Selected values for the electrical resistivity of liquid platinum from the melting point to 2900 K are also given in Table IV.
|Authors||Reference||ρS, μΩ cm||ρL, μΩ cm||ρL /ρS|
|Martynyuk and Tsapkov||35||62.1||92.6||1.491|
High Temperature Intrinsic Resistivity of Solid Palladium (273.15 to 1828 K)
ρi (μΩ cm) = 4.58639 × 10–2 T – 1.39098 × 10–5 T 2 + 1.84118 × 10–9 T 3 – 1.76742 (v)
Intrinsic Resistivity of Solid Platinum (100 to 2041.3 K)
ρi (μΩ cm) = 4.681197 × 10–2 T – 3.258075 × 10–5 T 2 + 8.554023 × 10–8 T 3 – 1.594242 × 10–10 T 4 + 1.837342 × 10–13 T 5 - 1.316886 × 10–16 T 6 + 5.678222 × 10–20 T 7 – 1.340980 × 10–23 T 8 + 1.329896 × 10–27 T 9 – 1.621733 (vii)
- G. T. Meadon, “Electrical Resistance of Metals”, Plenum Press, New York, USA, 1965
- J. Bass, ‘Electrical Resistivity of Pure Metals and Dilute Alloys’, in “Electrical Resistivity, Kondo and Spin Fluctuation Systems, Spin Glasses and Thermopower”, eds. K.-H. Hellwege and J. L. Olsen, Landolt-Börnstein Numerical Data and Functional Relationships in Science and Technology, New Series, Group III: Crystal and Solid State Physics, Vol. 15a, Springer-Verlag, Berlin, Heidelberg, New York, 1982, p. 1
- A. Andryushchenko, Yu. D. Chistyakov, A. P. Dostanko, T. L. Evstigneeva, E. V. Galoshina, A. D. Genkin, N. B. Gorina, V. M. Gryaznov, G. S. Khayak, M. M. Kirillova, E. I. Klabunovskii, A. A. Kuranov, V. L. Lisin, V. M. Malyshev, V. A. Matveev, V. A. Mityushov, L. V. Nomerovannaya, V. P. Polyakova, M. V. Raevskaya, D. V. Rumyantsev, E. I. Rytvin, N. M. Sinitsyn, A. M. Skundin, E. M. Sokolovskaya, I. P. Starchenko, N. I. Timofeyev, N. A. Vatolin, L. I. Voronova and V. E. Zinov’yev, “Blagorodnye Metally, Spravochnik” (“Handbook of Precious Metals”), ed. E. M. Savitskii, Metallurgiya Publishers, Moscow, Russia, 1984 (in Russian); English translation by S. N. Gorin, P. P. Pozdeev, B. A. Nikolaev and Yu. P. Liverov, English Edition, ed. A. Prince, Hemisphere Publishing Corp, New York, USA, 1989
- L. Binkele and M. Brunen, “Thermal Conductivity, Electrical Resistivity and Lorentz Function Data for Metallic Elements in the Range 273 to 1500 K”, Forschungszentrum Jülich, Institut für Werkstoffe der Energietechnik, Zentralbibliothek, Germany, 1994
- R. A. Matula, J. Phys. Chem. Ref. Data, 1979, 8, (4), 1147 LINK http://dx.doi.org/10.1063/1.555614
- G. K. White, ‘Recommended Values of Electrical Resistivity and Thermal Conductivity of Platinum’, in “Thermal Conductivity 17”, Gaithersburg, Maryland, USA, 15th–19th June, 1981, Proceedings of the Seventeenth International Thermal Conductivity Conference, ed. J. G. Hust, Purdue Research Foundation, Plenum Press, New York, USA, 1983, p. 95
- F. Bloch, Z. Physik, 1929, 52, (7–8), 555 LINK http://dx.doi.org/10.1007/BF01339455
- F. Bloch, Z. Physik, 1930, 59, (3–4), 208 LINK http://dx.doi.org/10.1007/BF01341426
- E. Grüneisen, Ann. Phys., 1933, 408, (5), 530 LINK http://dx.doi.org/10.1002/andp.19334080504
- R. E. Bedford, G. Bonnier, H. Maas and F. Pavese, Metrologia, 1996, 33, (2), 133 LINK http://dx.doi.org/10.1088/0026-1394/33/2/3
- R. W. Powell, R. P. Tye and M. J. Woodman, Platinum Metals Rev., 1962, 6, (4), 138LINK https://www.technology.matthey.com/article/6/4/138-143/#
- R. W. Powell, R. P. Tye and M. J. Woodman, J. Less Common Met., 1967, 12, (1), 1 LINK http://dx.doi.org/10.1016/0022-5088(67)90062-8
- G. K. White and S. B. Woods, Phil. Trans. R. Soc. Lond. A, 1959, 251, (995), 273 LINK http://dx.doi.org/10.1098/rsta.1959.0004
- M. J. Laubitz and T. Matsumura, Can. J. Phys., 1972, 50, (3), 196 LINK http://dx.doi.org/10.1139/p72-031
- R. K. Williams and F. J. Weaver, Phys. Rev. B, 1982, 25, (6), 3663LINK http://dx.doi.org/10.1103/PhysRevB.25.3663
- A. Khellar and J. J. Vuillemin, J. Phys.: Condens. Matter, 1992, 4, (7), 1757 LINK http://dx.doi.org/10.1088/0953-8984/4/7/013
- J. T. Schriempf, Phys. Rev. Lett., 1968, 20, (19), 1034 LINK http://dx.doi.org/10.1103/PhysRevLett.20.1034
- A. Khellaf, R. M. Emrick and J. J. Vuillemin, J. Phys. F: Met. Phys., 1987, 17, (10), 2081 LINK http://dx.doi.org/10.1088/0305-4608/17/10/016
- J. W. Arblaster, Platinum Metals Rev., 2012, 56, (3), 181 LINK https://www.technology.matthey.com/article/56/3/181-189/#
- N. Milošević and M. Babić, Int. J. Mater. Res., 2013, 104, (5), 462 LINK http://dx.doi.org/10.3139/146.110889
- A. P. Miiller and A. Cezairliyan, Int. J. Thermophys., 1980, 1, (2), 217 LINK http://dx.doi.org/10.1007/BF00504522
- G. Pottlacher, “High Temperature Thermophysical Properties of 22 Pure Metals”, Edition Keiper, Graz, Austria, 2010, p. 76
- E. Y. García and D. G. Löffler, J. Chem. Eng. Data, 1985, 30, (3), 304 LINK http://dx.doi.org/10.1021/je00041a020
- B. C. Dupree, J. B. Van Zytveld and J. E. Enderby, J. Phys. F: Met. Phys., 1975, 5, (11), L200 LINK http://dx.doi.org/10.1088/0305-4608/5/11/007
- H.-J. Güntherodt, E. Hauser, H. U. Künzi and R. Müller, Phys. Lett. A., 1975, 54, (4), 291
- U. Seydel and U. Fischer, J. Phys. F: Met. Phys., 1978, 8, (7), 1397 LINK http://dx.doi.org/10.1088/0305-4608/8/7/013
- F. Righini and A. Rosso, High Temp.-High Pressures, 1980, 12, (3), 335
- M. J. Laubitz and M. P. Van Der Meer, Can. J. Phys., 1966, 44, (12), 66 LINK http://dx.doi.org/10.1139/p66-259
- D. R. Flynn and M. E. O’Hagan, J. Res. Natl. Bur. Stand., 1967, C71, (4), 255 LINK http://dx.doi.org/10.6028/jres.071C.021
- W. Roeser, “Temperature: Its Measurement and Control in Science and Industry”, ed. M. S. van Dusen, Vol. I, Reinhold Publishing Corp, New York, USA, 1941, p. 1312
- Ya. A. Kraftmakher, High Temp.-High Pressures, 1973, 5, (4), 433
- J. J. Martin, P. H. Sidles and G. C. Danielson, J. Appl. Phys., 1967, 38, (8), 3075 LINK http://dx.doi.org/10.1063/1.1710065
- C. W. Corti, Platinum Metals Rev., 1984, 28, (4), 164 LINK https://www.technology.matthey.com/article/28/4/164-165/#
- J. W. Arblaster, Platinum Metals Rev., 1997, 41, (1), 12 LINK https://www.technology.matthey.com/article/41/1/12-21/#
- M. M. Martynyuk and V. I. Tsapkov, Fiz. Metal. Metalloved., 1974, 37, (1), 49; translated into English in Phys. Met. Metallogr., 1974, 37, (1), 40
- G. R. Gathers, J. W. Shaner and W. M. Hodgson, High Temp.-High Pressures, 1979, 11, (5), 529
- R. S. Hixson and M. A. Winkler, Int. J. Thermophys., 1993, 14, (3), 409 LINK http://dx.doi.org/10.1007/BF00566040
John W. Arblaster is interested in the history of science and the evaluation of the thermodynamic and crystallographic properties of the elements. Now retired, he previously worked as a metallurgical chemist in a number of commercial laboratories and was involved in the analysis of a wide range of ferrous and non-ferrous alloys.