Molecular Signature of Polyoxometalates in Electron Transport of Silicon-based Molecular Junctions

Polyoxometalates (POMs) are unconventional electro-active molecules with a great potential for applications in molecular memories, providing efficient processing steps onto electrodes are available. The synthesis of the organic-inorganic polyoxometalate hybrids [PM$_{11}$O$_{39}$(Sn(C$_6$H$_4$)C$\equiv$C(C$_6$H$_4$)N$_2$)]$^{3-}$ (M = Mo, W) endowed with a remote diazonium function is reported together with their covalent immobilization onto hydrogenated n-Si(100) substrates. Electron transport measurements through the resulting densely-packed monolayers contacted with a mercury drop as a top electrode confirms their homogeneity. Adjustment of the current-voltage curves with the Simmons equation gives a mean tunnel energy barrier of 1.8 eV and 1.6 eV, for the Silicon-Molecules-Metal (SMM) junctions based on the polyoxotungstates (M = W) and polyoxomolybdates (M = Mo), respectively. This follows the trend observed in the electrochemical properties of POMs in solution, the polyoxomolybdates being easier to reduce than the polyoxotungstates, in agreement with lowest unoccupied molecular orbitals (LUMOs) of lower energy. The molecular signature of the POMs is thus clearly identifiable in the solid-state electrical properties and the unmatched diversity of POM molecular and electronic structures should offer a great modularity

POM hybrids synthesis : controlled grafting onto electrodes for molecular junction study

Les polyoxométallates (POMs) de type Keggin [XM12O40]n- (avec X=P… et M= W, Mo …) sont des oxydes moléculaires de métaux de transition à haut degré d’oxydation qui présentent des réductions successives et réversibles dans une gamme étroite de potentiel. Leur incorporation dans des dispositifs de mémoire moléculaire semble alors prometteuse. Nous avons développé leur intégration comme briques élémentaires via une approche “bottom-up” qui surmonte les limites de l’approche “top-down” plus commune. Cela nécessite un contrôle fin de leur greffage et de leur densité surfacique pour l’obtention de dispositifs performants. Nous avons donc développé le greffage covalent de POMs sur des surfaces à base de silicium et d’or. Des hybrides de POMs à terminaison diazonium BA3[PM11O39{SnC6H4C≡CC6H4N2}] (avec M=W or Mo) ont formé des monocouches complètes greffées sur des surfaces de silicium hydrogénées qui mettent en évidence l’influence du métal constitutif du fragment polyoxométallate sur les propriétés de transport de charges de la jonction. Le greffage d’hybrides de POM à terminaison acide carboxylique sur des substrats d’oxyde de silicium a aussi été développée. Un hybride de POM à terminaison aniline TBA4[PW11O39{SnC6H4C≡CC6H4NH2}] a été greffé en deux étapes via un couplage peptidique sur une monocouche à terminaison acide carboxylique sur surface d’or. Des monocouches compactes ont été obtenues mais pas de façon totalement reproductible et les premiers essais de dilution sont encourageants. Une nouvelle famille d’hybrides de POMs mixtes a été synthétisée : TBA4[PMoxW11-xO39{SnR}]. Cela permettra de combiner les propriétés redox du molybdène et la robustesse due au tungstène.Keggin type polyoxometalates (POMs) [XM12O40]n- (with X=P… and M= W, Mo…) are molecular oxides of early transition metals with a high oxidation state. They present electrochemical successive reversible reduction waves in a narrow range of potential. This makes them good candidates to be incorporated into molecular memory devices. We chose a “bottom-up” approach where the POMs are the building blocks to overcome the limitation of the “top-down” process commonly used. A fine control of the POM grafting and of the surface density is essential to get better erase/writing time of the device. So, we developed POM hybrids for grafting them covalently onto silicon based and gold substrates. Diazonium-terminated POM hybrids (with M=W or Mo) lead to compact homogeneous monolayers onto hydrogenated silicon surfaces. Electrical measurements of the two analogous modified surfaces show different behaviour highlighting the role of the constituting POM metal into the charge transport. Carboxylic-terminated POM hybrids have also been grafted in a one-step process onto silicon oxide surface resulting in a smooth and dense monolayer. Then, an aniline-terminated POM hybrid has been grafted onto a carboxylic-terminated SAM of thiols onto gold thanks to a peptide coupling. Compact monolayers have been obtained without complete reproducibility and the first attempts of dilution are encouraging. A new family of POM hybrids have been synthesized: mixed-metal POM hybrids TBA4[PMoxW11-xO39{SnR}]. This will permit to combine the electrochemical properties of molybdenum and the robustness of tungsten

Synthèse d'hybrides de polyoxométallates : greffage contrôlé sur électrodes pour l'étude de jonctions moléculaires

Keggin type polyoxometalates (POMs) [XM12O40]n- (with X=P… and M= W, Mo…) are molecular oxides of early transition metals with a high oxidation state. They present electrochemical successive reversible reduction waves in a narrow range of potential. This makes them good candidates to be incorporated into molecular memory devices. We chose a “bottom-up” approach where the POMs are the building blocks to overcome the limitation of the “top-down” process commonly used. A fine control of the POM grafting and of the surface density is essential to get better erase/writing time of the device. So, we developed POM hybrids for grafting them covalently onto silicon based and gold substrates. Diazonium-terminated POM hybrids (with M=W or Mo) lead to compact homogeneous monolayers onto hydrogenated silicon surfaces. Electrical measurements of the two analogous modified surfaces show different behaviour highlighting the role of the constituting POM metal into the charge transport. Carboxylic-terminated POM hybrids have also been grafted in a one-step process onto silicon oxide surface resulting in a smooth and dense monolayer. Then, an aniline-terminated POM hybrid has been grafted onto a carboxylic-terminated SAM of thiols onto gold thanks to a peptide coupling. Compact monolayers have been obtained without complete reproducibility and the first attempts of dilution are encouraging. A new family of POM hybrids have been synthesized: mixed-metal POM hybrids TBA4[PMoxW11-xO39{SnR}]. This will permit to combine the electrochemical properties of molybdenum and the robustness of tungsten.Les polyoxométallates (POMs) de type Keggin [XM12O40]n- (avec X=P… et M= W, Mo …) sont des oxydes moléculaires de métaux de transition à haut degré d’oxydation qui présentent des réductions successives et réversibles dans une gamme étroite de potentiel. Leur incorporation dans des dispositifs de mémoire moléculaire semble alors prometteuse. Nous avons développé leur intégration comme briques élémentaires via une approche “bottom-up” qui surmonte les limites de l’approche “top-down” plus commune. Cela nécessite un contrôle fin de leur greffage et de leur densité surfacique pour l’obtention de dispositifs performants. Nous avons donc développé le greffage covalent de POMs sur des surfaces à base de silicium et d’or. Des hybrides de POMs à terminaison diazonium BA3[PM11O39{SnC6H4C≡CC6H4N2}] (avec M=W or Mo) ont formé des monocouches complètes greffées sur des surfaces de silicium hydrogénées qui mettent en évidence l’influence du métal constitutif du fragment polyoxométallate sur les propriétés de transport de charges de la jonction. Le greffage d’hybrides de POM à terminaison acide carboxylique sur des substrats d’oxyde de silicium a aussi été développée. Un hybride de POM à terminaison aniline TBA4[PW11O39{SnC6H4C≡CC6H4NH2}] a été greffé en deux étapes via un couplage peptidique sur une monocouche à terminaison acide carboxylique sur surface d’or. Des monocouches compactes ont été obtenues mais pas de façon totalement reproductible et les premiers essais de dilution sont encourageants. Une nouvelle famille d’hybrides de POMs mixtes a été synthétisée : TBA4[PMoxW11-xO39{SnR}]. Cela permettra de combiner les propriétés redox du molybdène et la robustesse due au tungstène

Immobilising molecular Ru complexes on a protective ultrathin oxide layer of p-Si electrodes towards photoelectrochemical CO2 reduction

Photoelectrochemical CO2 reduction is a promising approach for renewable fuel generation and to reduce greenhouse gas emissions. Owing to their synthetic tunability, molecular catalysts for the CO2 reduction reaction can give rise to high product selectivity. In this context, a Ru-II complex [Ru(HO-tpy)(6-mbpy)(NCCH3)](2+) (HO-tpy = 4 '-hydroxy-2,2 ':6 ',2 ''-terpyridine; 6-mbpy = 6-methyl-2,2 '-bipyridine) was immobilised on a thin SiOx layer of a p-Si electrode that was decorated with a bromide-terminated molecular layer. Following the characterisation of the assembled photocathodes by X-ray photoelectron spectroscopy and ellipsometry, PEC experiments demonstrate electron transfer from the p-Si to the Ru complex through the native oxide layer under illumination and a cathodic bias. A state-of-the-art photovoltage of 570 mV was determined by comparison with an analogous n-type Si assembly. While the photovoltage of the modified photocathode is promising for future photoelectrochemical CO2 reduction and the p-Si/SiOx junction seems to be unchanged during the PEC experiments, a fast desorption of the molecular Ru complex was observed. An in-depth investigation of the cathode degradation by comparison with reference materials highlights the role of the hydroxyl functionality of the Ru complex to ensure its grafting on the substrate. In contrast, no essential role for the bromide function on the Si substrate designed to engage with the hydroxyl group of the Ru complex in an S(N)2-type reaction could be established

Triiron clusters derived from dinuclear complexes related to the active site of [Fe-Fe] hydrogenases: Steric effect of the dithiolate bridge on redox properties, a DFT analysis.

International audienceA series of triiron clusters [Fe3(CO)5(2-dppe)(µ-pdtR2)(µ-pdt)] featuring different combination of dithiolate bridges have been prepared by using dinuclear and mononuclear precursors, [Fe2(CO)6(µ-xdt)] (xdt = pdt, pdtEt2, pdtBn2, adtBn) and [Fe(CO)2(2-dppe)(2-pdt)]. Novel triiron compounds, featuring sterically crowded dithiolate bridges (pdtEt2, pdtBn2), were spectroscopically and structurally characterized. Their protonation and redox behaviours are discussed. The effect of the dithiolate bridges on the electrochemical properties (oxidation and reduction) of the complexes [Fe3(CO)5(2-dppe)(µ-xdt)(µ-pdt)] has been examined by cyclic voltammetry and rationalized by DFT calculations. Studies of the protonation of these species and their proton reduction behaviour were considered

Covalent shaping of polyoxometalate molecular films onto ITO electrodes for charge trapping induced resistive switching

International audienceAs nano-sized molecular oxides, polyoxometalates (POMs) hold great promise in non-volatile memory materials based on redox-active molecules. Materials processed from solution, by drop-casting, by embedding POMs in polymers, or using Layer-by-Layer deposition techniques have thus been reported and successfully investigated. Almost all these examples are electrostatically assembled materials. We herein propose an original route to the elaboration of robust covalent POM networks, to seek the influence of the shaping process on the POM-to-POM communication and the final device performance. Capitalizing on our experience in the handling of organic-inorganic POM hybrids, we have prepared diazonium hybrids to harness the propensity of diazonium salts to form multi-layered materials upon electrochemical reduction. A few nanometers thick materials have thus been grown onto ITO electrodes and have shown to be potentially suitable for Write-Once-Read-Many (WORM) devices, with a low set voltage

Covalent Grafting of Polyoxometalate Hybrids onto Flat Silicon/Silicon Oxide: Insights from POMs Layers on Oxides

International audienceImmobilization of polyoxometalates (POMs) onto oxides is relevant to many applications in the fields of catalysis, energy conversion/storage, or molecular electronics. Optimization and understanding the molecule/oxide interface is crucial to rationally improve the performance of the final molecular materials. We herein describe the synthesis and covalent grafting of POM hybrids with remote carboxylic acid functions onto flat Si/SiO2 substrates. Special attention has been paid to the characterization of the molecular layer and to the description of the POM anchoring mode at the oxide interface through the use of various characterization techniques, including ellipsometry, AFM, XPS, and FTIR. Finally, electron transport properties were probed in a vertical junction configuration and energy level diagrams have been drawn and discussed in relation with the POM molecular electronic features inferred from cyclic-voltammetry, UV–visible absorption spectra, and theoretical calculations. The electronic properties of these POM-based molecular junctions are driven by the POM LUMO (d-orbitals) whatever the nature of the tether or the anchoring group