P. Heintzmann scite author profile

P. Heintzmann

5Publications

58Citation Statements Received

108Citation Statements Given

How they've been cited

How they cite others

162

106

Affiliations

German Aerospace Center, Forschungszentrum Jülich

Publications

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Preparation of Ohmic contacts to GaAs/AlGaAs-core/shell-nanowires

Wirths

Mikulics

Heintzmann

et al. 2012

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Ohmic contacts to GaAs/AlGaAs core/shell nanowires are prepared by using a Ni/AuGe/Ni/Au layer system. In contrast to Ohmic contacts to planar GaAs/AlGaAs layer systems here, relatively low alloying temperatures are used in cylindrical geometry. Lowest resistances are found for annealing temperatures of 320 °C and 340 °C. For annealing temperatures exceeding 360 °C, the nanowires degraded completely. Nanowires annealed under optimized conditions preserved their Ohmic characteristics even down to temperatures of 4 K.

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Atomic dynamics in binary Zr-Cu liquids

Yang¹,

Holland‐Moritz²,

Gegner³

et al. 2014

EPL

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We studied Cu self-dynamics and liquid density of Zr66.7Cu33.3, Zr35.5Cu64.5, Zr36Cu64, and Zr38.2Cu61.8 liquids using a combination of containerless processing techniques and quasielastic neutron scattering. We show that the composition dependence of the Cu self-dynamics is qualitatively controlled by the liquid packing density. It is hence monotonic within a narrow composition range and not sensitive to small composition variations. Similarly, replacing Cu by Ni results in a slower atomic dynamics in the Zr-Ni liquids, as a consequence of the more dense packing. This is in contrast to the strong composition dependence of the glass-forming behaviour, and the better glass-forming ability of the Zr-Cu over Zr-Ni alloys, which usually favours sluggish liquid dynamics. Thus, in the Zr-Cu case, the glass-forming ability is not directly correlated with liquid dynamics and packing density.

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Viscosity measurements of metallic melts using the oscillating drop technique

Heintzmann

Yang

Schneider

et al. 2016

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By means of benchmarking reduced gravity experiments, we have verified the measured viscosity of binary Zr-Ni glass forming liquids utilizing the oscillating drop technique combined with ground-based electrostatic levitation (ESL). Reliable viscosity data can be obtained as long as internal viscous damping of a single oscillation mode of a levitated drop dominates external perturbations. This can be verified by the absence of a sample mass dependence of the results. Hence, ESL is an excellent tool for studying the viscosity of metallic glass forming melts in the range of about 10–250 mPa s, with sample masses below 100 mg. To this end, we show that, for binary Zr-Ni melts, the viscosity is qualitatively controlled by the packing density.

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AtmoFlow - Investigation of Atmospheric-Like Fluid Flows Under Microgravity Conditions

Zaussinger

Canfield

Froitzheim

et al. 2019

Microgravity Sci. Technol.

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Kinetics-dominated interdiffusion in metallic glass-forming liquids

et al. 2018

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P. Heintzmann

Preparation of Ohmic contacts to GaAs/AlGaAs-core/shell-nanowires

Atomic dynamics in binary Zr-Cu liquids

Viscosity measurements of metallic melts using the oscillating drop technique

AtmoFlow - Investigation of Atmospheric-Like Fluid Flows Under Microgravity Conditions

Kinetics-dominated interdiffusion in metallic glass-forming liquids

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