Céline M. Leroy scite author profile

Citation for published item:rrenD FgF nd o¤ %t hovskyD uF nd hot nD rF nd veroyD gFwF nd gornuzD wF nd tell iD pF nd r¡ e ertD gF nd oths hildD eF nd qr¤ tzelD wF @PHIQA 9sdentifying h mpion n nostru tures for sol r w terEsplittingF9D x ture m teri lsFD IP @WAF ppF VRPEVRWF Further information on publisher's website: httpXGGdxFdoiForgGIHFIHQVGnm tQTVR Publisher's copyright statement: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-pro t purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. Charge transport in nanoparticle-based materials underlies many emerging energy conversion technologies, yet assessing the impact of nanometer-scale structure on charge transport across micron-scale distances remains a challenge. Here we develop an approach for correlating the spatial distribution of crystalline and current-carrying domains in entire nanoparticle aggregates. We apply this approach to nanoparticle-based α-Fe 2 O 3 electrodes that are of interest in solar-to-hydrogen energy conversion. In correlating structure and charge transport with nanometer resolution across micron-scale distances, we have identified the existence of champion nanoparticle aggregates that are most responsible for the high photoelectrochemical activity of the present electrodes. Indeed, when electrodes are fabricated with a high proportion of these champion nanostructures, the electrodes achieve the highest photocurrent of any metal oxide photoanode for photoelectrochemical water splitting under 100 mW cm -2 air mass 1.5 global sunlight.Batteries, fuel cells, and solar energy conversion devices have emerged as a class of important technologies that increasingly rely upon electrodes derived from nanoparticles 1 . These nanoparticle-based materials provide a unique challenge in assessing structure-property relationships because of the disordered arrangement of nanocrystals that results when nanoparticles collide and aggregate [2][3][4][5][6] . The morphological evolution that follows aggregation further obscures the influence of particle size, shape, and interfacial characteristics in defining the physical properties of these materials 7,8 . For the nanoparticle-based electrodes used in solar energy conversion, structural defects such as grain boundaries define pathways for charge transport by creating potential barriers and by promoting recombination 9 . Because of the complexity of these materials, within a single electrode there may exist a small proportion of "champion" nanostructures-by analogy with champion solar cells 10,11 , these are nanostructures that provide the highest solar conversion efficiencies-th...

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Giant magnetoresistance in magnetic multilayered nanowires

Piraux

et al. 1994

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Giant magnetoresistance (GMR) is observed in a new type of nanostructured material consisting of magnetic multilayered nanowires formed by electrodeposition into nanometer-sized pores of a template polymer membrane. The composition of these nanowires is modulated over nanometer length scales with distinct magnetic and nonmagnetic metallic layers. Magnetoresistance measurements with the current perpendicular to the layers were performed on the array of parallel nanowires. GMR of about 15% was observed at room temperature on Co/Cu multilayered nanowires.

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Towards an easy access to amphiphilic rod-coil miktoarm star copolymers

et al. 2005

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Designing Nanotextured Vanadium Oxide-Based Macroscopic Fibers: Application as Alcoholic Sensors

et al. 2007

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Composite vanadium oxide/PVA/latex macroscopic fibers have been generated by using an extrusion process. Specifically, inorganic vanadium oxide fibers enable the detection of 0.1 ppm of ethanol within 3-5 s at 42 °C, which is certainly one of the highest sensitivities to date concerning alcohol sensors. More importantly, by varying the starting latex inclusion contents, the shear rates applied during the extrusion process, and the final appliance of a thermal treatment, we were able to segregate each parameter involved within the mechanical and sensing properties associated with these as-synthesized fibers, i.e., the amount of the organic insulator counterpart, the degree of vanadium oxide ribbons alignment, and the induced porosity reached upon latex removal. Overall, we found out that all the parameters described above and involved within the as-synthesized fibers' mechanical and sensing properties are acting within a partitive action mode rather than a cooperative one.

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Céline M. Leroy

Identifying champion nanostructures for solar water-splitting

Giant magnetoresistance in magnetic multilayered nanowires

Towards an easy access to amphiphilic rod-coil miktoarm star copolymers

Designing Nanotextured Vanadium Oxide-Based Macroscopic Fibers: Application as Alcoholic Sensors

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