Sara Gullace scite author profile

The development of systems capable of responding to environmental changes, such as humidity, requires the design and assembly of highly sensitive and efficiently transducing elements. Such a challenge can be mastered only by disentangling the role played by each component of the responsive system, thus ultimately achieving high performance by optimizing the synergistic contribution of all functional elements. Here, we designed and synthesized a novel [1]benzothieno [3,2-b][1]benzothiophene derivative equipped with hydrophilic oligoethylene glycol lateral chains (OEG-BTBT) that can electrically transduce subtle changes in ambient humidity with high current ratios (>10 4 ) at low voltages (2 V), reaching state-of-the-art performance. Multiscale structural, spectroscopical, and electrical characterizations were employed to elucidate the role of each device constituent, viz., the active material's BTBT core and OEG side chains, and the device interfaces. While the BTBT molecular core promotes the self-assembly of (semi)conducting crystalline films, its OEG side chains are prone to adsorb ambient moisture. These chains act as hotspots for hydrogen bonding with atmospheric water molecules that locally dissociate when a bias voltage is applied, resulting in a mixed electronic/protonic long-range conduction throughout the film. Due to the OEG-BTBT molecules' orientation with respect to the surface and structural defects within the film, water molecules can access the humidity-sensitive sites of the SiO 2 substrate surface, whose hydrophilicity can be tuned for an improved device response. The synergistic chemical engineering of materials and interfaces is thus key for designing highly sensitive humidity-responsive electrical devices whose mechanism relies on the interplay of electron and proton transport.

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Universal Fabrication of Highly Efficient Plasmonic Thin‐Films for Label‐Free SERS Detection

Gullace

Montes‐García

Martín

et al. 2021

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The development of novel, highly efficient, reliable, and robust surface enhanced Raman scattering (SERS) substrates containing a large number of hot spots with programmed size, geometry, and density is extremely interesting since it allows the sensing of numerous (bio‐)chemical species. Herein, an extremely reliable, easy to fabricate, and label‐free SERS sensing platform based on metal nanoparticles (NPs) thin‐film is developed by the layer‐by‐layer growth mediated by polyelectrolytes. A systematic study of the effect of NP composition and size, as well as the number of deposition steps on the substrate's performance, is accomplished by monitoring the SERS enhancement of 1‐naphtalenethiol (532 nm excitation). Distinct evidence of the key role played by the interlayer (poly(diallyldimethylammonium chloride) (PDDA) or PDDA‐functionalized graphene oxide (GO@PDDA)) on the overall SERS efficiency of the plasmonic platforms is provided, revealing in the latter the formation of more uniform hot spots by regulating the interparticle distances to 5 ± 1 nm. The SERS platform efficiency is demonstrated via its high analytical enhancement factor (≈106) and the detection of a prototypical substance(tamoxifen), both in Milli‐Q water and in a real matrix, viz. tap water, opening perspectives towards the use of plasmonic platforms for future high‐performance sensing applications.

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Field-effect-transistor-based ion sensors: ultrasensitive mercury(ii) detection via healing MoS₂ defects

2021

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Sara Gullace

High-Performance Humidity Sensing in π-Conjugated Molecular Assemblies through the Engineering of Electron/Proton Transport and Device Interfaces

Universal Fabrication of Highly Efficient Plasmonic Thin‐Films for Label‐Free SERS Detection

Field-effect-transistor-based ion sensors: ultrasensitive mercury(ii) detection via healing MoS₂ defects

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Sara Gullace

High-Performance Humidity Sensing in π-Conjugated Molecular Assemblies through the Engineering of Electron/Proton Transport and Device Interfaces

Universal Fabrication of Highly Efficient Plasmonic Thin‐Films for Label‐Free SERS Detection

Field-effect-transistor-based ion sensors: ultrasensitive mercury(ii) detection via healing MoS2 defects

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Product

Resources

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Field-effect-transistor-based ion sensors: ultrasensitive mercury(ii) detection via healing MoS₂ defects