Comparative study of the specific heat of superconducting and non-superconducting YBa2Cu3O7−x

We have measured the specific heat, the electrical resistance and the magnetic susceptibility of YBa₂Cu₃O_7–x in a superconducting (sc) and in a non-superconducting (nsc) version. The latter was obtained by inducing a small loss of oxygen. In the sc sample we find a jump of the specific heat with C=3.6 J mole^–1 K^–1. Below the maximum nearT _c the specific heat of the sc version drops too fast for an electronic effect alone: there is a cross-over from excess to deficiency already at 0.9T _c . The specific heat of the nsc version shows a change of slope in the temperature range between 70 and 80 K, which indicates the existence of a second specific heat anomaly, which apparently exists independently of that due to the onset of superconductivity and explains at least partially the premature crossover.Alexander von Humboldt fellow. On leave in absence from Centro Atomico Bariloche—CNEA Argentina     

Bestimmung von leichten Elementen in Silicium und Selen durch Ionenaktivierungsanalyse

Zusammenfassung Elemente mit niedriger Kernladungszahl lassen sich durch Aktivierung mit thermischen Neutronen entweder überhaupt nicht oder nur mit sehr geringer Empfindlichkeit bestimmen.In den letzten Jahren gewinnt daher die Bestrahlung mit Ionen (Protonen, Deuteronen, Tritium-, ³He- und ⁴He-Ionen) zur Aktivierungsanalyse der leichten Elemente zunehmend an Bedeutung. Zwischen Ionen- und Neutronenaktivierungen bestehen prinzipielle Unterschiede, die diskutiert werden.Aufgrund ihrer relativ geringen Reichweite in Materie eignen sich Ionen besonders zur Untersuchung von Oberflächen sowie dünnen Aufdampfschichten und Korrosionsschichten. Da die Aktivierungstiefe durch entsprechende Wahl der Versuchsparameter festgelegt werden kann, laßt sich auch die Tiefenverteilung von Fremdstoffen im Matrixmaterial untersuchen.Zur Bestimmung von Sauerstoff, Stickstoff und Kohlenstoff werden Protonen- und Deuteronenreaktionen herangezogen; aber auch Elemente wie Bor und Aluminium lassen sich dureh Ionenaktivierung erfassen. Bei einer Einschußenergie der Ionen von 3,0 MeV, einer Flußdichte von 5 A/cm² und einer Bestrahlungszeit, die der Halbwertszeit des zu aktivierenden Elementes entspricht, liegt die Bestimmungsempfindlichkeit für die genannten Elemente im Bereich von 1–100 ppb.Über die Bestimmung von Kohlenstoff in Silicium und Sauerstoff in aufgedampften Selenschichten wird berichtet.

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Determination of light elements in silicon and selenium by ion-activation analysis

Elements with low atomic number either cannot be determined at all by activation with thermal neutrons or only with very poor detection limit.In recent years, irradiation with ions (protons, deuterons, tritium ions, ³He- and ⁴He-ions) for activation analysis of the light elements has therefore gained increasing importance. There are basic differences between ion and neutron activation, which are discussed.Because of their relatively small range in matter, ions are particularly suited for analyzing surfaces as well as thin deposited films and corrosion layers. Since the activation depth can be established in advance by appropriate selection of the analysis parameters, the distribution of foreign matter in the matrix material can also be analyzed.Proton and deuteron reactions are employed to determine the presence of oxygen, nitrogen and carbon, but other elements such as boron and aluminium can also be detected by ion activation. The detection limit attained in analyzing the elements mentioned is within the range of 1 to 100 ppb with an ion bombarding energy of 3.0 MeV, a flux density of 5 A/cm² and an irradiation period which corresponds to the half-life of the element to be activated.A report is given on the determination of carbon in silicon and oxygen in thin-deposited selenium films and the results are discussed.

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Vortrag bei der Tagung Analytische Probleme der Reindarstellung von Halbleitern, Wiesbaden, 24.–25. 9. 1968.

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Herrn Prof. Dr. W. Gebauhr danken wir für viele anregende Diskussionen. Für die Mithilfe bei der Bestrahlung und Auswertung sind wir Frau K. Appler, Frl. E. Lüders und Herrn H. Pfann zu Dank verpflichtet.     

Tailoring a Zinc Oxide Nanorod Surface by Adding an Earth-Abundant Cocatalyst for Induced Sunlight Water Oxidation

Herein, a detailed investigation of the surface modification of a zinc oxide (ZnO) nanorod electrode with FeOOH nanoparticles dispersed in glycine was conducted to improve the water oxidation reaction assisted by sunlight. The results were systematically analysed in terms of the general parameters (light absorption, charge separation, and surface for catalysis) that govern the photocurrent density response of metal oxide as photoanode in a photoelectrochemical (PEC) cell. ZnO electrodes surface were modified with different concentration of FeOOH nanoparticles using the spin-coating deposition method, and it was found that 6-layer deposition of glycine-FeOOH nanoparticles is the optimum condition. The glycine plays an important role decreasing the agglomeration of FeOOH nanoparticles over the ZnO electrode surface and increasing the overall performance. Comparing bare ZnO electrodes with the ones modified with glycine-FeOOH nanoparticles an enhanced photocurrent density can be observed from 0.27 to 0.57 mA/cm² at 1.23 V_RHE under sunlight irradiation. The impedance spectroscopy data aid us to conclude that the higher photocurrent density is an effect associated with more efficient surface for chemical reaction instead of electronic improvement. Nevertheless, the charge separation efficiency remains low for this system. The present discovery shows that the combination of glycine-FeOOH nanoparticle is suitable and environmentally-friend cocatalyst to enhance the ZnO nanorod electrode activity for the oxygen evolution reaction assisted by sunlight irradiation.     

Production and Characterization of β-Glucanase Secreted by the Yeast Kluyveromyces marxianus

An extracellular β-glucanase secreted by Kluyveromyces marxianus was identified for the first time. The optimal conditions for the production of this enzyme were evaluated by response surface methodology. The optimal conditions to produce β-glucanase were a glucose concentration of 4 % (w/v), a pH of 5.5, and an incubation temperature of 35 °C. Response surface methodology was also used to determine the pH and temperature required for the optimal enzymatic activity. The highest enzyme activity was obtained at a pH of 5.5 and a temperature of 55 °C. Furthermore, the enzyme was partially purified and sequenced, and its specificity for different substrates was evaluated. The results suggest that the enzyme is an endo-β-1,3(4)-glucanase. After optimizing the conditions for β-glucanase production, the culture supernatant was found to be effective in digesting the cell wall of the yeast Saccharomyces cerevisiae, showing the great potential of β-glucanase in the biotechnological production of soluble β-glucan.     

Transport properties of LaCu2Si2 and CeCu2Si2 between 1.5K and 300K

We report measurements of the electrical resistivity, the thermal conductivityk and the thermoelectric powerS between 1.5K and 300K on the anomalous CeCu₂Si₂ compound and on LaCu₂Si₂ as reference compound. For LaCu₂Si₂ the temperature dependences of andS are in accord with those found in otherd band metals. For CeCu₂Si₂ the observed resistivity (220 µ cm at 200K) leads to a very short electronic mean free path which is of the order of the Ce-Ce spacing. Correspondingly,k is almost identical with the phonon contributionk _p . Below 20K, resistivity and thermoelectric power strongly suggest Fermi liquid behavior with a degeneracy temperature between 20K and 40K. Above 200K, both andS decrease proportionally to –ln(T/1 K).Work performed within the research program of the Sonderforschungsbereich 125 Aachen/Jülich/KölnPart of this work will be presented at the Int. Conf. on Rare Earths in the Metallic State, St. Pierre de Chartreuse, Sept. 1978     

Investigation of surface and thermogravimetric characteristics of carbon-coated iron nanopowder

Demand for high-density press and sinter components is increasing day by day. Of the different ways to improve the sinter density, the addition of nanopowder to the conventional micrometer-sized metal powder is an effective solution. The present investigation is aimed at studying the surface chemistry of iron nanopowder coated with graphitic carbon, which is intended to be mixed with the conventional iron powder. For this purpose, iron nanopowder in the size range of 30 nm to submicron (less than 1 micron) was investigated using thermogravimetry at different temperatures: 400°C, 600°C, 800°C, 1000°C, and 1350°C. The X-ray photoelectron spectroscopy (XPS), Auger electron spectroscopy (AES), and high-resolution scanning electron microscopy (HR-SEM) were used for characterizing the powder as well as samples sintered at different temperatures. The presence of iron, oxygen, carbon, chromium, and zinc were observed on the surface of the nanopowder. Iron was present in oxide state, although a small metallic iron peak at 707 eV was also observed in the XPS spectra obtained from the surface indicating the oxide scale to be maximum of about 5 nm in thickness. For the sample treated at 600°C, presence of manganese was observed on the surface. Thermogravimetry results showed a two-step mass loss with a total mass loss of 4 wt.% when heated to 1350°C where the first step corresponds to the surface oxide reduction.     

Electrical and thermal conductivity of CePd3, YPd3, GdPd3 and some dilute alloys of CePd3 with Y and Gd

Resistivity and thermal conductivity of the intermediate valence compound CePd₃ between 1.3 and 300 K are compared with those of the nonmagnetic and magnetic reference compounds YPd₃ and GdPd₃ and of alloys of the type Ce₁–xRE _x Pd₃ with RE=Y, Gd and 0.01<x<0.5. The analysis reveals the existence of a maximum metallic resistivity of 300 cm for CePd₃. The intrinsic resistivity of CePd₃ rises proportional toT ² up to 100 K, with a coefficientB about 10⁷ times larger than e.g. in copper. We interpret this with indirect electron-electron scattering mediated through valence transitions.