Neutron diffraction assessment at extreme temperatures to gain insights into the performance of thermocouple coatings. Part 2. [Dataset]

doi:10.5286/ISIS.E.RB2510004-2

Neutron diffraction assessment at extreme temperatures to gain insights into the performance of thermocouple coatings. Part 2. [Dataset]

Contributors

Beth Irungu
Data Collector

Professor Nadimul Faisal N.H.Faisal@rgu.ac.uk
Data Collector

Tung Lik Lee
Data Collector

Saurav Goel
Data Collector

Mubarak Abdelrasoul Elnour Ismail
Data Collector

Abstract

This project investigates the behaviour of Chromel-Alumel K-type thermocouples under extreme temperature conditions, focusing on coatings produced through thermal spray processes. These thermocouples, widely used in industrial and aerospace applications, experience phase changes that can compromise temperature accuracy, particularly in cryogenic environments. While bulk material behaviour is well-documented, the performance of thin films and coatings remains poorly understood, especially under high and low temperatures.

Citation

IRUNGU, B., FAISAL, N., LEE, T.L., GOEL, S. and ISMAIL, M.A.E. 2025. Neutron diffraction assessment at extreme temperatures to gain insights into the performance of thermocouple coatings. Part 2. [Dataset]. Hosted on STFC ISIS neutron and muon source data journal [online]. Available from: https://doi.org/10.5286/ISIS.E.RB2510004-2

Online Publication Date	Mar 15, 2025
Deposit Date	Mar 21, 2025
Publicly Available Date	Mar 21, 2025
Publisher	Science and Technology Facility Council (STFC) ISIS Neutron and Muon Source
DOI	https://doi.org/10.5286/ISIS.E.RB2510004-2
Keywords	Thermocouple behaviour; Extreme temperatures; Coatings; Thermal spray processes; Neurons
Public URL	https://rgu-repository.worktribe.com/output/2755910
Related Public URLs	https://rgu-repository.worktribe.com/output/2755520 (Part 1 Dataset)
Type of Data	RAW/Nexus files.
Collection Date	Mar 15, 2025
Collection Method	The proposed study employs neutron diffraction to assess in-situ phase transformations and residual stress effects in Ni–20Cr coatings. Neutron diffraction's deep material penetration and high resolution make it ideal for probing changes across coating thicknesses. The project will investigate the influence of residual stress on phase transformations, contributing to improved thermocouple calibration and performance in cryogenic and high-temperature applications. By addressing these material challenges, the research aligns with ongoing UK government initiatives to digitalize manufacturing processes, building on previous EPSRC-funded projects and supporting the completion of a PhD thesis on thermal spray coatings with embedded sensing capabilities.