Metal Domain Size Dependent Electrical Transport in Pt-CdSe Hybrid Nanoparticle Monolayers

Meyns, Michaela; Willing, Svenja; Lehmann, Hauke; Klinke, Christian

doi:10.1021/acsnano.5b01221

Cited by 19 publications

(24 citation statements)

References 80 publications

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“…For instance, nanoantenna array (Fig. 5a) [11,24,[52][53][54][67][68][69][70][71][72][73][74][75][76][77][78][79][80][81][82][83][84] and tapered waveguide (Fig. 5b) [2,[55][56][57][58][59][60] are frequently used structures to couple the free space light into extremely small volumes and produce significantly enhanced localized field.…”

Section: Confined Light-matter Interaction Within Extremely Small Strmentioning

confidence: 99%

Light–Matter Interaction within Extreme Dimensions: From Nanomanufacturing to Applications

Song

et al. 2018

Advanced Optical Materials

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Light-matter interaction lies at the heart of photonics/optical material science. As the research emphasis in recent years shifted from microscale towards nanoscale, light-matter interaction within extreme dimensions raised new challenges as well as opportunities. However, due to the diffraction limit of conventional optics, coupling and confinement of light into deepsubwavelength volume is usually very challenging, resulting in difficulties in exploring the lightmatter interaction within ultra-thin and ultra-small dimensions. Based on recent advances in theoretical modeling, nanomanufacturing and experimental validation efforts, unique features have been recognized. Here we summarize recent key progresses of light-matter interaction within extreme dimensions and discuss future directions based on new combinations of materials, structures, nanomanufacturing and applications, ranging from quantum plasmonics, nonlinear optics to optical biosensing.

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Section: Confined Light-matter Interaction Within Extremely Small Strmentioning

confidence: 99%

Light–Matter Interaction within Extreme Dimensions: From Nanomanufacturing to Applications

Song

et al. 2018

Advanced Optical Materials

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“…Charge is transferred from the AuNP dopant to the CuPcSu layer, since the Fermi level of Au NPs in contact with the molecular film is spaced only 1.2 eV below the CB distribution maximum (in contrast to the 2.0 eV spacing from the VB maximum), which is equivalent to saying we have an extrinsic n-type semiconductor. The concept of n-type doping of originally p-type semiconducting linkers through the utilization of metal NPs (metal NP doping-induced Fermi level shift) has been reported before [77,78]. The mixing of the p molecular orbitals with NP states [79] is believed to be responsible for this electronic coupling.…”

Section: Electron Transport Through Aunps/cupcsu Multijunction Networkmentioning

confidence: 99%

Probing the localization of charge and the extent of disorder through electronic transport on Au nanoparticle–copper phthalocyanine multijunction networks

Balliou

Kazim

Pfleger

et al. 2016

Physica Status Solidi (b)

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Precision control of charge transport can provide a solid basis for the design of materials with novel properties. We report on the bottom‐up fabrication and study of the electronic properties of molecular multijunction networks comprising ultrafine gold nanoparticles (AuNPs) of diameter ∼1.4 nm, electronically linked by means of copper 3‐diethylamino‐1‐propylsulfonamide sulfonic acid‐substituted phthalocyanine (CuPcSu) molecules. When electrons flow through the nonlinked nanoparticle arrays, they experience onsite Coulomb repulsion and are strongly localized, with a localization length ξ = 0.7 nm. Under dynamic excitation the system functions as a single electron‐transport regulator, undergoing Coulomb oscillations, whereas the introduction of CuPcSu molecules results in the formation of a network of multiple molecular/Au nanojunctions and conductance increases by five orders of magnitude. This switching behavior functions on reversible redox reactions and pushes carriers into a state of weaker localization. In this state, electrons spread over several junctions and all temperature‐scaled current versus voltage curves, J/T1 + α versus eV/kT, collapse into one universal curve, characterizing the network and the extent of its disorder. Utilizing this property, we demonstrate the effect of interelectrode distance on the conduction nodes' topological disorder. The system consists a promising candidate for Au NPs‐based thin films with tunable properties wherever solution‐based fabrication methods, such as injection printing, are envisioned.

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“…Colloidal nanoparticles (NPs) have been widely investigated for the last several decades because of their unique quantum‐confinement‐effect‐driven optical, electronic, magnetic, and chemical properties . Coupled with their nanometer‐scale size, extremely high surface area to volume ratio, and high reactivity, NPs are actively used for diverse applications in biological, environmental, analytical, medicinal, and energy‐related fields …”

Section: Introductionmentioning

confidence: 99%

“…quantum-confinement-effect-driven optical, electronic, magnetic, and chemical properties. [1][2][3][4] Coupled with their nanometer-scale size, extremely high surface area to volume ratio, and high reactivity, NPs are actively used for diverse applications in biological, environmental, analytical, medicinal, and energy-related fields. [5][6][7][8][9][10][11] Although NPs are frequently employed for the aforementioned applications, there are some critical issues regarding their long-term storability that must be resolved.…”

mentioning

confidence: 99%

A Paper‐Based Platform for Long‐Term Deposition of Nanoparticles with Exceptional Redispersibility, Stability, and Functionality

Cho

Kim

Jafry

et al. 2019

Part & Part Syst Charact

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Although nanoparticles (NPs) can be carefully engineered to have maximal stability and functionality desirable for use in diverse applications, they are generally not suitable for long‐term storage in solution. It is also difficult to store NPs in a dry state because dried NPs generally become aggregated and cannot easily be redispersed. Thus, a new strategy allowing long‐term storage of NPs with high stability, redispersibility, and functionality is highly demanded. By passivating the 13 nm gold nanoparticle (AuNP) surface with stabilizing agents and treating a paper substrate with both bovine serum albumin and sucrose after coating with a hydrophobic polyvinyl butyral layer, it is possible to fully redisperse (≈100%) dried AuNPs with colloidal stability comparable to that of as‐prepared AuNPs. Furthermore, AuNPs physically stabilized with polyvinylpyrrolidone can react with thiol‐containing compounds, such as 1,4‐dithiothreitol (DTT). Taking advantage of the oxidation reaction of hypochlorous acid with DTT, it is possible to demonstrate a paper‐based colorimetric sensor for detection of residual chlorine in water. Since this strategy is applicable to large‐sized AuNPs (30–90 nm), silver NPs, oleic acid‐capped magnetic NPs, and cetrimonium bromide‐passivated gold nanorods, it can be used for diverse NPs requiring long‐term storage for many applications.

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Metal Domain Size Dependent Electrical Transport in Pt-CdSe Hybrid Nanoparticle Monolayers

Cited by 19 publications

References 80 publications

Light–Matter Interaction within Extreme Dimensions: From Nanomanufacturing to Applications

Light–Matter Interaction within Extreme Dimensions: From Nanomanufacturing to Applications

Probing the localization of charge and the extent of disorder through electronic transport on Au nanoparticle–copper phthalocyanine multijunction networks

A Paper‐Based Platform for Long‐Term Deposition of Nanoparticles with Exceptional Redispersibility, Stability, and Functionality

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