Diamondoid Nanostructures as sp<sup>3</sup>‐Carbon‐Based Gas Sensors

Moncea, Oana; Casanova-Cháfer, Juan; Poinsot, Didier; Ochmann, Lukas; Mboyi, Clève D.; Nasrallah, Houssein; Llobet, Eduard; Makni, Imen; El atrous, Molka; Brandès, Stéphane; Rousselin, Yoann; Domenichini, B.; Nuns, Nicolás; Fokin, Andrey A.; Schreiner, Peter R.; Hierso, Jean‐Cyrille

doi:10.1002/ange.201903089

Cited by 5 publications

(9 citation statements)

References 45 publications

(34 reference statements)

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“…Because of the thin layer and hybrid metal-organic nature the overall resistivity will be stronger providing a more sensitive material. That is what was observed in our recent works, [8,9] and confirmed herein. We recently achieved hybrid materials from molecularly-defined functionalized diamondoids with palladium, by chemical vapor deposition of a palladium organometallic complex over the selfassembly of diamondoids scaffold.…”

Section: Introductionsupporting

confidence: 94%

Advanced Composite for sp³‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Bouzid,

Poinsot,

Mboyi

et al. 2023

Adv Materials Technologies

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The assembly of hybrid materials combining a pure sp3‐C platform from nano‐and microcrystals of molecularly‐defined nanometer‐sized functionalized diamondoids (nanodiamonds) coated with a gold transition metal nanolayer is conducted from the gas phase, following a two‐steps vapor phase dry construction process. By using first the controlled vapor phase self‐assembly of primary phosphine diamantane derivatives, followed by a chemical vapor decomposition of a suited gold organometallic complex the synthesis of the nanocomposite Au@H2P–DiamOH 2 is achieved. The gold deposit surface analysis reveals the formation of a Au–P covalent bonding, which excludes the formation of phosphine oxide, as confirmed at higher depth into the nanocomposite by Hard X‐ray Photoelectron Spectroscopy analysis (HaXPES). The thickness d of the gold layers deposited onto the surface of diamondoids is estimated to be around d = 0.8 ± 10% nm from XPS data, which allows combining the composite Au@H2P–DiamOH 2 with ITO interdigitated electrodes, to produce a long‐life, highly stable and reproducible, n‐type behavior sensor for ammonia detection. A relative response (RR) of 150% at 30 ppm and a limit of detection of 6 ppm are measured at room temperature (20 to 25 °C) and at 45% of relative humidity.

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Section: Introductionsupporting

confidence: 94%

Advanced Composite for sp³‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Bouzid,

Poinsot,

Mboyi

et al. 2023

Adv Materials Technologies

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“…Here, it should be stressed that unlike previous reports (Tables 2 and 3), the gas-sensing studies were carried out using low gas flows (100 sccm) and long reaction times (30 min), close to the practical conditions of environmental monitoring sensors. The response/recovery is slow, which could be further improved by decreasing the dead volume in the airtight chamber or device miniaturization [64]. Therefore, considering the high sensitivity obtained for low concentration of pollutants (Table 2), the as-produced FLG shows a high potential to be further optimized towards a commercial NO 2 gas-sensor for continuous environmental monitoring [13].…”

Section: Methodsmentioning

confidence: 99%

Wafer-scale few-layer graphene growth on Cu/Ni films for gas sensing applications

Deokar

Casanova-Cháfer

Rajput

et al. 2020

Sensors and Actuators B: Chemical

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“…Commercially available adamantane and diamantane have mechanically rigid and thermodynamically extremely stable structures, 19,20 which are easily amenable to synthetic modifications, [21][22][23] and have been used with success to assemble various innovative functional materials. [24][25][26] Thus, we employed adamantane, bis-adamantane and diamantane as platform for synthesizing dicarboxylic and diamine ligands, which are used for the first time to produce a set of Ru NP networks with well-defined characteristics (NP size, interparticle distance, electronic environment) of interests for catalysis. These materials were investigated for the selective hydrogenation of phenylacetylene into styrene.…”

Section: Introductionmentioning

confidence: 99%

3D Ruthenium Nanoparticle Covalent Assemblies from Polymantane Ligands for Confined Catalysis

et al. 2020

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The synthesis of metal nanoparticle (NP) assemblies stabilized by functional molecules is an important research topic in nanoscience, and the ability to control interparticle distances and positions in NP assemblies is one of the major challenges in designing and understanding functional nanostructures. Here, two series of functionalized adamantanes, bisadamantanes and diamantanes bearing carboxylic acid or amine functional groups have been used as building blocks to produce, via a straightforward method, networks of ruthenium NP. Both the nature of the ligand and the Ru/ligand ratio affect the interparticle distance in the assemblies. The use of 1,3-adamantanedicarboxylic acid allows the synthesis of 3D networks of 1.7-1.9 nm Ru NP presenting interparticle distance of 2.5-2.7 nm. The surface interaction between Ru NP and the ligands were investigated spectroscopically using a 13 C labeled ligand, as well as theoretically with Density Functional Theory (DFT) calculations. We found that Ru species formed during the NP assembly are able to partially decarbonylate carboxylic acid ligands at room temperature. Decarbonylation of a carboxylic acid at room temperature in the presence of dihydrogen usually occurs on catalysts at much higher temperature and pressure. This result reveals a very high reactivity of ruthenium species formed during network assembling. The Ru NP networks were found active catalysts for the selective hydrogenation of phenyl acetylene, reaching good selectivity towards styrene. Overall, we demonstrated that catalyst activity, selectivity, and NP network stability are significantly affected by Ru NP interparticle distance, and electronic ligand effects. As such, these materials constitute a unique set that should allow a better understanding of the complex surface chemistry in carbonsupported metal catalysts.

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Diamondoid Nanostructures as sp³‐Carbon‐Based Gas Sensors

Cited by 5 publications

References 45 publications

Advanced Composite for sp³‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Advanced Composite for sp³‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Wafer-scale few-layer graphene growth on Cu/Ni films for gas sensing applications

3D Ruthenium Nanoparticle Covalent Assemblies from Polymantane Ligands for Confined Catalysis

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Diamondoid Nanostructures as sp3‐Carbon‐Based Gas Sensors

Cited by 5 publications

References 45 publications

Advanced Composite for sp3‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Advanced Composite for sp3‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Wafer-scale few-layer graphene growth on Cu/Ni films for gas sensing applications

3D Ruthenium Nanoparticle Covalent Assemblies from Polymantane Ligands for Confined Catalysis

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Product

Resources

About

Diamondoid Nanostructures as sp³‐Carbon‐Based Gas Sensors

Advanced Composite for sp³‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids

Advanced Composite for sp³‐Carbon‐Based Gas Sensing Application from Gold Organometallic Single Nanolayering on Diamondoids