Robust gold nanoparticles stabilized by trithiol for application in chemiresistive sensors

Garg, Niti; Mohanty, Ashok; Lazarus, Nathan; Schultz, L.; Rozzi, Tony R; Santhanam, Suresh; Weiss, Lee E.; Snyder, Jay L.; Fedder, Gary K.; Jin, Rongchao

doi:10.1088/0957-4484/21/40/405501

Cited by 47 publications

(41 citation statements)

References 37 publications

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“…Garg et al prepared trithiol‐capped Au MPCs and deposited them by inkjet‐printing on a spiral Au IDA of electrodes for chemiresistive sensing of various analytes including Tol, EtOH, dichloroethane, MeOH, and acetone 32. They compared stability of the trithiol‐protected Au MPC films with the conventional monothiol C8S Au MPCs.…”

Section: Chemiresistive Sensing Of Vapor‐phase Moleculesmentioning

confidence: 99%

Chemiresistive Sensing with Chemically Modified Metal and Alloy Nanoparticles

Ibáñez

Zamborini

2011

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This review describes the use of chemically modified pure and alloyed metal nanoparticles for chemiresistive sensing applications. Chemically modified metal nanoparticles consist of a pure or alloyed metallic core with some type of chemical coating. Researchers have studied the electronic properties of 1D, 2D, and 3D assemblies of chemically modified metal nanoparticles, and even single individual nanoparticles. The interaction with the analyte alters the conductivity of the sensitive material, providing a signal to measure the analyte concentration. This review focuses on chemiresistive sensing of a wide variety of gas- and liquid-phase analytes with metal nanoparticles coated with organothiols, ions, polymers, surfactants, and biomolecules. Different strategies used to incorporate chemically modified nanoparticles into chemiresistive sensing devices are reviewed, focusing on the different types of metal and alloy compositions, coatings, methods of assembly, and analytes (vapors, gases, liquids, biological materials), along with other important factors.

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Section: Chemiresistive Sensing Of Vapor‐phase Moleculesmentioning

confidence: 99%

Chemiresistive Sensing with Chemically Modified Metal and Alloy Nanoparticles

Ibáñez

Zamborini

2011

Small

142

136

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“…Surface functionalization is being used in wide range of applications, like surface and selfassembling monolayers (SAMs) in bio-sensors [1,2], gas sensors [3][4][5], corrosion resistance of metal [6] and electronics [7]. Generally, surfaces are organically modified to enhance detection performance, surface rigidity, selectivity and sensitivity of sensors, etc.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and characterization of tin dioxide thick film modified by APTES in vapor and liquid phases

et al. 2017

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International audienceSurface functionalization has numerous applications worldwide. Silicon oxide has been a research material of choice. However, tin dioxide (SnO₂) films are employed in many applications especially in gas sensors, and little studied in regard to functionalization. Thus, they were chosen to be functionalized via 3-aminopropyltriethoxysilane (APTES). Different synthesis parameters were tested such as APTES grafting by vapor or liquid phases deposition. In liquid, many parameters were investigated: water presence, reaction times, and APTES concentration. The presence and reactivity of grafted amine-terminated film on SnO₂ were carried out by Alexa Fluor® molecules. In addition, APTES grafting was characterized using attenuated total reflectance Fourier transform infrared spectroscopy and X-ray photoelectron spectrometry techniques. These characterizations showed how synthesis parameters affect the amount and thickness of APTES films. Optimal liquid silanization parameters were determined in order to obtain a saturated SnO₂ surface with APTES molecules. Importantly, the addition of 5 vol% H₂O to the APTES solution provided denser surface coverage, by hydrolyzing the ethoxy groups to silanol. An almost 50% improvement over anhydrous liquid and vapor methods was obtained

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“…The problem of the conservation of the initial size of nanoparticles during the isolation process is a very urgent task, so the isolation of the particles is performed in the presence of a protective agent preventing their agglomeration. Different types of protective reagents for gold nanoparticles are known, in particular citrate ion [6,7], alkylthiols [22][23][24], alkylthioacetates [25], organic amines [26,27], and phosphines [28].…”

Section: Introductionmentioning

confidence: 99%

Di-(2-ethylhexyl) dithiophosphoric acid surface protected gold nanoparticles: micellar synthesis, stabilization, isolation, and properties

et al. 2011

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Gold nanoparticles (AuNPs) were synthesized in the organic solution by means of the reduction of HAuCl 4 by hydrazine in reverse micelles of oxyethylated surfactant Triton N-42, with decane as the dispersion medium. To isolate the powder of particles, the micelles were destroyed with chloroform in the presence of di-(2-ethylhexyl) dithiophosphoric acid as a surface protecting agent. According to the results of several experiments, the yield is within the limits of 90-98%, calculated for gold. The obtained preparations are dark blue hydrophobic powders containing aggregated but not agglomerated gold nanoparticles, as well as microcrystals (∼0.08-0.2 μm) of NaCl. The powders get re-dispersed in weakly polar organic solvents with the formation of colloidal solutions. The shape of the nanoparticles is spherical. Their nuclei are gold single crystals with a narrow size distribution; their diameter (d Au ) is about two times as large as the diameter of the aqueous nucleus (d c ) of initial micelles: d Au =7.7±

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Robust gold nanoparticles stabilized by trithiol for application in chemiresistive sensors

Cited by 47 publications

References 37 publications

Chemiresistive Sensing with Chemically Modified Metal and Alloy Nanoparticles

Chemiresistive Sensing with Chemically Modified Metal and Alloy Nanoparticles

Synthesis and characterization of tin dioxide thick film modified by APTES in vapor and liquid phases

Di-(2-ethylhexyl) dithiophosphoric acid surface protected gold nanoparticles: micellar synthesis, stabilization, isolation, and properties

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