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Structural analysis of HyFlex EDM instruments
Author(s) -
Iacono F.,
Pirani C.,
Generali L.,
Bolelli G.,
Sassatelli P.,
Lusvarghi L.,
Gandolfi M. G.,
Giorgini L.,
Prati C.
Publication year - 2017
Publication title -
international endodontic journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.988
H-Index - 119
eISSN - 1365-2591
pISSN - 0143-2885
DOI - 10.1111/iej.12620
Subject(s) - materials science , martensite , austenite , microstructure , nanoindentation , raman spectroscopy , composite material , elastic modulus , optics , physics
Aim To compare the phase transformation behaviour, the microstructure, the nano‐hardness and the surface chemistry of electro‐discharge machined HyFlex EDM instruments with conventionally manufactured HyFlex CM . Methodology New and laboratory used HyFlex EDM were examined by X‐ray diffraction ( XRD ) and differential scanning calorimetry ( DSC ). Nano‐hardness and modulus of elasticity were also investigated using a maximum load of 20 mN with a minimum of 40 significant indentations for each sample. Raman spectroscopy and field emission‐scanning electron microscope ( FE ‐ SEM ) were used to assess the surface chemistry of HyFlex EDM . HyFlex CM were subjected to the same investigations and used as a comparison. Nano‐indentation data were statistically analysed using the Student's t‐test. Results XRD analysis on HyFlex EDM revealed the presence of martensite and rhombohedral R‐phase, while a mixture of martensite and austenite structure was identified in HyFlex CM . DSC analysis also disclosed higher austenite finish (Af) temperatures for electro‐discharge machining ( EDM ) instruments. Significant differences in nano‐hardness and modulus of elasticity were found between EDM and CM files ( P < 0.05). FE ‐ SEM and EDS analyses confirmed that both new EDM and CM files were covered by an oxide layer. Micro‐Raman spectroscopy assessed the presence of rutile‐TiO 2 .Conclusions HyFlex EDM revealed peculiar structural properties, such as increased phase transformation temperatures and hardness. Present results corroborated previous findings and shed light on the enhanced mechanical behaviour of these instruments.