Open AccessCooperative 1D Triazole-Based Spin Crossover FeII Material With Exceptional Mechanical Resilience
Author(s) -
Narsimhulu Pittala,
Franck Thétiot,
Smaı̈l Triki,
Kamel Boukheddaden,
Guillaume Chastanet,
Mathieu Marchivie
Publication year - 2016
Publication title -
chemistry of materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.741
H-Index - 375
eISSN - 1520-5002
pISSN - 0897-4756
DOI - 10.1021/acs.chemmater.6b04118
Subject(s) - resilience (materials science) , spin crossover , crossover , materials science , spin (aerodynamics) , nanotechnology , physics , radiochemistry , chemistry , computer science , condensed matter physics , engineering , composite material , mechanical engineering , artificial intelligence
International audienceThe magnetic spin change associated with the spin crossover (SCO) phenomenon represents a paradigm of bistability at the molecular level that is of current interest because of potential applications in the development of new generations of electronic devices such as nonvolatil memories, molecular sensors and displays.(1-5) The SCO phenomenon is especially observed in FeII complexes in which the paramagnetic high spin state (HS, S = 2) can be switched reversibly to the low spin state (LS, S = 0) by several external stimuli such as temperature, pressure or light irradiation.(6) A huge effort has been devoted to the understanding of the transition mechanisms using inter alia crystallographic tools..
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