Room temperature optoelectronic devices operating with spin crossover nanoparticles | Zendy

JeanFrançois Dayen | Zendy; Nikita Konstantinov | Zendy; Marlène Palluel | Zendy; Nathalie Daro | Zendy; B. Kundys | Zendy; Mohamed Soliman | Zendy; Guillaume Chastanet | Zendy; Bernard Doudin | Zendy

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Room temperature optoelectronic devices operating with spin crossover nanoparticles

Author(s) -

JeanFrançois Dayen,

Nikita Konstantinov,

Marlène Palluel,

Nathalie Daro,

B. Kundys,

Mohamed Soliman,

Guillaume Chastanet,

Bernard Doudin

Publication year - 2021

Publication title -

materials horizons

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 4.322

H-Index - 81

eISSN - 2051-6355

pISSN - 2051-6347

DOI - 10.1039/d1mh00703c

Subject(s) - materials science , nanoparticle , optoelectronics , crossover , spin (aerodynamics) , nanotechnology , computer science , mechanical engineering , engineering , artificial intelligence

Molecular systems can exhibit multi-stimuli switching of their properties, with spin crossover materials having unique magnetic transition triggered by temperature and light, among others. Light-induced room temperature operation is however elusive, as optical changes between metastable spin states require cryogenic temperatures. Furthermore, electrical detection is hampered by the intrinsic low conductivity properties of these materials. We show here how a graphene underlayer reveals the light-induced heating that triggers a spin transition, paving the way for using these molecules for room temperature optoelectronic applications.

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