Time-of-flight Elastic Recoil Detection Analysis
Time of Flight Elastic Recoil Detection Analysis (ToF-ERDA)
Matthew Sharpe & Callum McAleese
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Yifu Shi, et al. Appl. Phys. Lett. 2023; 123 (26): 261106.
Desorption electrospray ionisation (DESI) and particle induced X-ray emission (PIXE)
☐ The work investigates passivating‐contact stacks for solar cells; specifically thin film contact structures comprising e.g. poly-Si on SiOx.
☐ ToF-ERDA employed to directly detect and depth‐profile hydrogen (and deuterium) in these thin‐film stacks.
☐ The study shows that ToF-ERDA can resolve H/D. Artifact issues common to other techniques (e.g., SIMS) are mitigated by ToF-ERDA.
☐ Annealing treatments change the H/D distribution and that these changes correlate with passivation quality improvements. For example, H/D removal or redistribution is linked to changes in the interface oxide and poly‐Si structure.
Decontamination and Surface Analysis of PFAS-Contaminated Fire Suppression System Pipes: Effects of Cleaning Agents and Temperature
☐ The work addresses decontamination of infrastructure surfaces (specifically stainless steel pipes) that are contaminated by firefighting foams containing Per‐ and polyfluoroalkyl substances (PFAS).
☐ Time‐of‐Flight Elastic Recoil Detection Analysis (ToF-ERDA) is applied to analyse the pipe surfaces after different cleaning procedures. It enabled measurement of remaining fluorine (F) on the interior surfaces.
☐ ToF-ERDA results confirmed that even after cleaning there remained residual fluorine on the pipe surfaces (including deeper in the surface layers).
☐ The depth‐profiling capability of ToF-ERDA added critical insight about what’s left behind on surfaces.
Perovskite solar cells for space applications
☐ ToF-ERDA was used to quantitatively analyse elemental composition (especially light organic species such as H, C, N) and depth profiles in the perovskite layers before and after proton irradiation.
☐ ToF-ERDA played a central diagnostic role in this work, enabling:
☐ Accurate quantification of elemental loss (H, C, N) due to irradiation;
☐ Verification that PDAI₂ mitigates organic volatilisation;
☐ Support for the proposed mechanism of radiation-induced defect passivation and lattice stabilization.
Radiation effects on nuclear surrogate material
☐ Micro‐crystalline vs nano‐crystalline ZrN (zirconium nitride) thin films respond to radiation (ion beam or other irradiation) in terms of structural and compositional changes.
☐ The study applied ToF-ERDA to probe changes in elemental composition (particularly light elements like O, N) and depth distribution caused by radiation in the films.
☐ The findings suggest that nano‐crystalline ZrN is more susceptible to oxidation under irradiation than the micro‐crystalline form, and that the distribution of oxygen and nitrogen evolves differently in both forms.
