Deuterium retention in 1350 K self-ion irradiated tungsten rises with damage dose to 1.7 at.% at 2.3 dpa without saturation, driven by nm-sized voids that trap D2 gas inside and D atoms on their surfaces.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
citation-role summary
background 3
citation-polarity summary
years
2026 3verdicts
UNVERDICTED 3roles
background 3polarities
background 3representative citing papers
Ammonia poisons PEM fuel cell cathodes by ammonium ions displacing hydronium at sulfonic acid sites and forming hydronium-absorbing ion clusters via hydrogen bonds, with higher temperatures helping to break up clusters and restore proton transport.
316plus stainless steel keeps high cryogenic strength with hydrogen present but loses 40-50% ductility at 77 K and 20 K while still showing about 30% reduction in area.
citing papers explorer
-
Damage dose dependence of deuterium retention in high-temperature self-ion irradiated tungsten
Deuterium retention in 1350 K self-ion irradiated tungsten rises with damage dose to 1.7 at.% at 2.3 dpa without saturation, driven by nm-sized voids that trap D2 gas inside and D atoms on their surfaces.
-
Poisoning mechanism of ammonia on proton transport and ionomer structure in cathode catalyst layer of PEM fuel cells
Ammonia poisons PEM fuel cell cathodes by ammonium ions displacing hydronium at sulfonic acid sites and forming hydronium-absorbing ion clusters via hydrogen bonds, with higher temperatures helping to break up clusters and restore proton transport.
-
Cryogenic hydrogen embrittlement of 316plus (EN 1.4420) stainless steel at 77 K and 20 K
316plus stainless steel keeps high cryogenic strength with hydrogen present but loses 40-50% ductility at 77 K and 20 K while still showing about 30% reduction in area.