Unlocking room-temperature bistable spin transition at the nanoscale: the synthesis of core@shell [Fe(NH2trz)3(NO3)]@SiO2 nanoparticles

Handle

https://riunet.upv.es/handle/10251/206707

Cita bibliográfica

Regueiro, A.; Martí-Carrascosa, M.; Torres-Cavanillas, R.; Coronado, E. (2024). Unlocking room-temperature bistable spin transition at the nanoscale: the synthesis of core@shell [Fe(NH2trz)3(NO3)]@SiO2 nanoparticles. Dalton Transactions. 53(20):8764-8771. https://doi.org/10.1039/d4dt00911h

Titulación

Resumen

[EN] In this work, we address the synthesis of stable spin-crossover nanoparticles capable of undergoing a hysteretic spin transition at room temperature. For this purpose, we use the reverse-micelle protocol to prepare naked Fe(NH(2)trz)(3)(2) and core@shell Fe(NH(2)trz)(3)(2)@SiO2 nanoparticles. Through meticulous adjustment of synthetic parameters, we achieved nanoparticle sizes ranging from approximately 40 nm to 60 nm. Our findings highlight that Fe(NH(2)trz)(3)(2) presents a modest thermal hysteresis of 7 K, which decreases by downsizing. Conversely, silica-coated nanoparticles with sizes of ca. 60 and 40 nm demonstrate a remarkable hysteretic response of approximately 30 K, switching their spin state around room temperature. Moreover, the presence of a SiO2 shell substantially enhances the nanoparticles' stability against oxidation. In this context, the larger 60 nm Fe(NH(2)trz)(3)(2)@SiO2 hybrid remains stable in water for up to two hours, enabling the observation of an unreported water-induced spin transition after 30 min. Therefore, this work also introduces an intriguing avenue for inducing spin transitions through solvent exchange, underscoring the versatility and potential of these nanoparticles.

Fuente

Dalton Transactions issn: 1477-9226

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