Corrosion and Hydrogen Uptake in Zirconium Claddings Irradiated in Light Water Reactors

“…It should be kept in mind that this material is not designed to stay for such long residence times in reactor, and the 9-cycle cladding was produced for research activities only. The hydrogen pickup fraction of the cladding after 9 cycles had reached 30% compared to the 3-cycle cladding which was 17% [6]. This finding forms the basis for the motivation for the extensive characterisation and comparison of its high and low burnup samples [6], [19]- [23].…”

“…Hydrogen uptake and subsequent hydride formation during component lifetime has been identified as one of the critical life limiting degradation behaviours for these components [2]- [5]. It has been demonstrated by recent studies that hydrogen uptake is not constant throughout component lifetime and it can increase or decrease with residence time [4], [6]. To explain the mechanism of hydrogen uptake and its variation from one alloy to another, (or for the same alloy at different stages of oxidation and irradiation), the oxide electronic resistivity is considered.…”

“…Using micromanipulators (micromanipulator) in a scanning electron microscope (SEM), the resistivity of a certain thickness of oxide at a certain point could be directly measured. Although this paper will cover to some extent the experimental method, further detail for the hydrogen measurements and for the conductivity technique can be found in refs [6] and [17], [18]. The results will then be compared with the hydrogen uptake for both materials, previously measured in ref.…”

“…The results will then be compared with the hydrogen uptake for both materials, previously measured in ref. [6].…”

Characterization of the conductivity of metal-oxide interface of zirconium based fuel cladding at low and high burnups

“…It should be kept in mind that this material is not designed to stay for such long residence times in reactor, and the 9-cycle cladding was produced for research activities only. The hydrogen pickup fraction of the cladding after 9 cycles had reached 30% compared to the 3-cycle cladding which was 17% [6]. This finding forms the basis for the motivation for the extensive characterisation and comparison of its high and low burnup samples [6], [19]- [23].…”

“…Hydrogen uptake and subsequent hydride formation during component lifetime has been identified as one of the critical life limiting degradation behaviours for these components [2]- [5]. It has been demonstrated by recent studies that hydrogen uptake is not constant throughout component lifetime and it can increase or decrease with residence time [4], [6]. To explain the mechanism of hydrogen uptake and its variation from one alloy to another, (or for the same alloy at different stages of oxidation and irradiation), the oxide electronic resistivity is considered.…”

“…Using micromanipulators (micromanipulator) in a scanning electron microscope (SEM), the resistivity of a certain thickness of oxide at a certain point could be directly measured. Although this paper will cover to some extent the experimental method, further detail for the hydrogen measurements and for the conductivity technique can be found in refs [6] and [17], [18]. The results will then be compared with the hydrogen uptake for both materials, previously measured in ref.…”

“…The results will then be compared with the hydrogen uptake for both materials, previously measured in ref. [6].…”

Characterization of the conductivity of metal-oxide interface of zirconium based fuel cladding at low and high burnups

“…The in‐depth SIMS data can be used to generate 1‐dimensional (1D) depth profiles of the kind more commonly reported for HPU studies 7,41,13 . Typical depth profiles for 1 H – and 2 H – signals through the oxide into the metal matrix are shown in Figure 5.…”

Site‐specific specimen preparation for SIMS analysis of radioactive samples

Fracture behaviour of Zr(Fe,Cr)2 Laves phase precipitates in Zircaloy-4 subjected to β forging