Flow Characterization of Porous Ultra-High-Temperature Ceramics for Transpiration Cooling - Dataset by Ifti, H S, Hermann, T, McGilvray, M, Larrimbe, L, Hedgecock, R, Vandeperre, L

“…Porous ultra-high-temperature ceramics (UHTCs) are a candidate group of materials for transpiration cooling of hypersonic vehicles due to their exceptionally high melting point, typically above 3000 K. …”

Cubic and hexagonal boron nitride doped MgB2 bulk superconductor by Gao, Z, Santra, S, Grovenor, C R M, Speller, S C

Subjects:

Supplements for article titled Hybrid Electrolytes with 3D Bicontinuous Ordered Ceramic and Polymer Microchannels for All-Solid-State Batteries by Bruce, P

Supporting data - Interfaces between ceramic and polymer electrolytes: A comparison of oxide and sulfide solid electrolytes for hybrid solid-state batteries by Bruce, P

Performance of Transpiration Cooled Heat Shields for Re-entry Vehicles - Dataset by Hermann, T, McGilvray, M, Naved, I

“…Carbon/Carbon composite ceramic and the ultra high temperature ceramic Zirconium di-Boride are considered as wall materials. …”

Numerical Simulation of Transpiration Cooling for a High-Speed Vehicle with Substructure - Dataset by Naved, I, Hermann, T, McGilvray, M

“…Transpiration cooling using helium coolant has been applied to awing leading-edge model with an aluminum substructure. Carbon–carbon ceramic composite and the ultra-high-temperature ceramic Zirconium diboride (ZrB2) are chosen as candidate materials. …”

Mixing Characteristics in a Hypersonic Flow around a Transpiration Cooled Flat Plate Model - Dataset by Hermann, T, Ifti, H S, McGilvray, M, Doherty, L, Penty Geraets, R

“…Mass injection is realized through a porous ceramic material, and alternatively through a series of slots. …”

Measuring the concentration of freestream species on a hypersonic transpiration-cooled stagnation point - Dataset by Ewenz Rocher, M, Hermann, T, McGilvray, M, Grossman, M, Vandeperre, L

“…Porous alumina is chosen due to its ability to bond PSP and its similar microstructure to porous Ultra-High-Temperature Ceramics. Nitrogen, Argon and Krypton are used as injection gases at mass flow rates ranging from 0.01 - 0.55 kg/m2s, in order to displace up to 99% of the freestream gas at the surface. …”