La Sorbonne
La Sorbonne



La Sorbonne
La Sorbonne

Lescouëzec et coll.




Responsive Polymer

Cs{Fe4Co4} pro-cubes were shown to be stable in DMF solution. By reacting these polylmetallic building units with Tp blocking ligands, molecular cubes readily form. In contrast, the use of Tp-Ar-Tp bridging ligands leads to insoluble polymeric material. While the emectronic state of the molecular cubes can be switched through a photo-induced Fe-Co electron transfer, the polymeric network shows a thermally-induced electron transfer above room-temperature. Interestingly, the electron transfer and the resulting magnetic states of the polymeric material are shown to critically depend on its hydration state, indicating the capability of the material to act as a chemo-sensor. 

More in J. Mat. Chem. C , 2021 DOI : 10.1039/D1TC01825F

The [Fe(C6F5Tp)2] complex is converted through melting and recrystallization at high-T from a kinetic crystal phase (1) showing an extremely gradual spin-crossover to a thermodynamic crystal phase (2) showing a broad hysteretic spin-transition. The uncommon “rounded” hysteresis occurs in a non-cooperative SCO system. It is due to a symmetry-breaking phase transition that is triggered when roughly ca. 50% of the SCO complexes are switched from the low-spin state to the high-spin state or, conversely from the HS state to the LS state.

More in Angew. Chem. Int. Ed. 2021 DOI : 10.1002/anie.202015994


Cs⊂{Fe4Fe4} cube can be reversibly converted into 9 different redox states in solution. By changing the electric potential, LMCT, MLCT and MMCT transitions can be switched on and off  leading to at least 3 very different optical signatures. 
Not only that ! The cube is also a MMS,  showing a
Spin-transition in the neutral form in the solide-state

More in Chem. Commun. 2020 DOI : 10.1039/D0CC04279J

Bistable under pressure.png

Yanling Li & Co

The investigated Fe2Co2 square complex shows a Fe(III/II)-Co(II/III) Electron Transfer equilibrium in MeOH solution, with Teq near 0°C.  Crystallization at 35°C allows isolating the square in its paramagnetic FeIII-CoII electronic state (see Part I, RSC Adv. 2016 S. De et al.).

Here we showed  that application of pressure allows recovering a Fe(III)Co(II) <=> Fe(II)-Co(III) Electron Transfer Transition in the solid-state.

Remarkably, the FeCo shows an unusual p-enhanced hysteresis that allows reaching bistability at room temperature.

More in Angew. Chem. 2020 DOI : 10.1002/anie.202008051



Amina Benchohra & Co

Many efforts are currently devoted in depositing ultra-thin layers of SCO Molecular Switches onto surfaces. Most of the time,  researchers use evaporation methods applied to robust neutral monometallic complexes. Things are more complicated with polymetallic charged complexes that can undergo dissociation, etc... unless you find the good way.

Here we showed with the help of the colleagues from LRS lab (Sorbonne Univ.) that EI allows depositing cubes onto Gold(111)

What's Next ?  Probing that the switching properties are preserved, another story...

More in Chem. Commun. 2020 DOI :10.1039/D0CC01906B


Fe4Mn4-Electron Transfer.png

While the switchable properties of the FeCo PBA (first observed by Sato et al in 1996) can be "easily" transferred to discrete molecular systems, things seem much more complicated in the case of the FeMn systems... After some efforts studying cyanide-bridged FeMn systems showing intringuing behaviours, we decided to publish that cube, which shows a  fragile transition ascribed to a FeMn electron transfer, together with interesting electrochromic properties ...
More in Angew. Chem. 2020, DOI: 10.1002/anie.201916199


© Copyright

Juan Jiménez, Akira Sugahara & Co

In the frame of an ANR-JST joined project, we have been investigated the intercalation of cation into cyanido-molecular materials.

In this work Juan and Akira showed that "simple" monodimentional cyanide-bridged complex can reversibly intercalate Li+ ions. Although the material becomes amorphous during the Li intercalation process, crystallinity is recovered once the Li is removed. All the process can be repeated at least 20 times without significant loss of capacity.

More in Chem. Comm. 2018 DOI : 10.1039/C8CC01374H



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