HyProSA - Hydrogen Production from Sulphuric Acid
In the HyProSA project, a test facility is being built in which the production of hydrogen from the electrolysis of concentrated sulphuric acid is being investigated. With a suitable choice of operating parameters, hydrogen peroxide (or another peroxide) is produced at the anode instead of oxygen.
HyProSA - Hydrogen Production from Sulphuric Acid
In the HyProSA project, a test facility is being built in which the production of hydrogen from the electrolysis of concentrated sulphuric acid is being investigated. With a suitable choice of operating parameters, hydrogen peroxide (or another peroxide) is produced at the anode instead of oxygen.
Head of P3E
Prof. Dr.-Ing. Christian Schumann Contact:
Campus Kaiserslautern, Building F, Room F2.029 Phone: +49 631 3724-2216 E-Mail: christian.schumann(at)hs-kl.de ORCID: 0000-0003-1774-5212
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Use of Kerr microscopy to characterise the development of damage in steels
The Kerr microscope used in the project is a two-in-one system. Fig. 1 therefore shows both the near-field microscopy with the corresponding non-magnetic Epiplan Neofluar objectives (20x0.5 Pol; 50x0.8 Pol; 100x1.3 Pol) and the arrangement of the far-field (Carl Zeiss Op
Topics
Current topics PhDs Supervisor at HS KL TRAPP – Nanocarrier in Trägermatrix für Transdermale Applikationen Prof. Dr. Hildegard Möbius Dotted Design for OLEDs Prof. Dr. Hildegard Möbius Development of Superparamagnetic Functional Materials for Hyperthermia Applications Pro
Topics completed PhDs Supervisor at HS KL
Development of electrochemical deposition of NiFeMo and its application in magnetic field sensor technology Prof. Dr. Monika Saumer
Development of 3D electrodes for biomedical applications Prof. Dr. Monika Saumer
Random nanostructured interfaces for bioanalytical applications Prof. Dr. Monika Saumer
Ch
Use of Kerr microscopy to characterise the development of damage in steels
The Kerr microscope used in the project is a two-in-one system. Fig. 1 therefore shows both the near-field microscopy with the corresponding non-magnetic Epiplan Neofluar objectives (20x0.5 Pol; 50x0.8 Pol; 100x1.3 Pol) and the arrangement of the far-field (Carl Zeiss Optic
The magneto-optical Kerr effect, discovered by John Kerr in 1876 and named after him, describes the change in the properties of polarised light when reflected by a magnetic surface. This involves the rotation of the plane of polarisation on the one hand and the change in intensity of the polarised light on the other. This is illustrated in Fig. 2