Technetium (Tc) is a silver-grey transition metal with low natural abundance [1]. It is, however, one of the major fission product created during nuclear energy generation. Its fission yield is approximately 6 %, ranking amongst the highest of the fission products. Also its half-life ranks among one of the highest of the fission products, 2.1 × 10⁵ years. Technetium can occur in various oxidation states and the oxyanions of valence states IV, V and VI are quite stable [2], [3], and some are relatively mobile in an oxidising aqueous environment [4]. This makes technetium of major concern during both energy production as well as high-level waste storage [5].

In irradiated nuclear fuel the oxygen potential is low, and technetium remains in metallic state. It is a component of the 5-metal particles, a fission product alloy of Ru-Pd-Rh-MoTc, which are found throughout the nuclear fuel [6], [7] and are very stable, even surviving the fuel reprocessing in nitric acid. The stability of these 5-metal particles is generally modelled by computational chemical thermodynamic methods [8], which require accurate description of the lattice stability of the constituent elements. It is therefore necessary to have a accurate knowledge of both low- and high-temperature thermophysical properties. Since there is little to no information available of the technetium metal, previous assessments [9], [10], [11] have heavily relied on estimates and extrapolations of what is known. These estimates are made with sound scientific basis in mind using comparisons to other transition metals, particularly the neighboring Ru, Rh and Os metals, which have a hexagonal closepacked (A3) crystal structure, similar to technetium.

Thermophysical properties such as the heat capacity across a wide temperature range provide information on phase transitions, lattice vibrations, energy excitations as well as electronic properties. In recent years various studies have been performed on heat capacity and enthalpy increments of technetium metal. Experimental data exist between the temperature 3 and 15 K [12] and between 323 and 1500 K [13], [14]. In the range of 15 K to 323 K no experimental data exist, and data needs to be interpolated or estimated, in order to obtain the standard entropy, a key thermodynamic parameter. One of the reasons to perform experimental studies on lower temperature heat capacity is that the entropy Debye temperature model loses its validity under 100 K leading to uncertainty in the calculated values. In this study, we aim to fill this gap...

The technetium metal was taken from the batch that was produced by Spirlet and coworkers, as described in [15]. The metal was obtained by reducing ammonium pertechnetate in Ar/H2 in a resistance furnace at 1073 K. The metallic powder was remelted several times into small buttons by arc melting to improve the purity of the material by evaporating the impurities. Finally the metal was casted into rods that were cut to cylinders of required size. The microstructure of the rods consisted of large grains often extending from the centre to the rim of the rods [15]. Three analysis performed on the final ingots produced at that time show a purity of 99.819 % to 99.982 %, with main impurities W (∼1000 ppm), Ce (∼800 ppm), Re (∼450 ppm), Si (∼220 ppm) and (Pu + U) (∼210 ppm). The oxygen content was found between 44 and 187 ppm.

Figure 2. Measured low-temperature heat capacity for the normal state of technetium metal from 2.1 − 293 K in a magnetic field of B = 1 T. The solid line show the extrapolation to T = 298.15 K.

Figure 4. The high-temperature heat capacity of technetium metal; the red line shows the fitted equation, the blue line the recommendation from the OECDNEA review of 1999 [11], [37]. Also shown are the recommended curves for rhenium (light green), ruthenium (yellow) and osmium (dark green). (For interpretation of the references to colour in this figure legend, the reader is referred to the web version of this article.)

Figure 5. The low-temperature heat capacity of the metals in group (7) (top) and of the Mo-Tc-Ru suite in the second d-block series (bottom) of the periodic table of elements. The blue circles represent the results from the current study, the small magenta circles those of Trainor and Brodsky [27]. (For interpretation of the references to colour in this figure legend, the reader is referred to the web version of this article.)