Chemiluminescence in the Agglomeration of Metal Clusters

König, Lutz; Rabin, Ira; Schulze, W.; Ertl, G.

doi:10.1126/science.274.5291.1353

Cited by 114 publications

(73 citation statements)

References 11 publications

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“…Before the seminal work in 2002 by Zheng and Dickson who used dendrimers as a stabilizer [12], metal NCs were only prepared in cryogenic noble gases or in solid zeolites [30][31][32]. Following this initial discovery, the Dickson group further showed that cytosine (C)-rich DNA can also stabilize fluorescent AgNCs [15], which represents the first connection between metal NCs and DNA.…”

Section: Synthesis Of Ncsmentioning

confidence: 99%

DNA-stabilized, fluorescent, metal nanoclusters for biosensor development

Liu

2014

TrAC Trends in Analytical Chemistry

195

141

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In the past decade, fluorescent silver, gold and copper nanoclusters (Ag, Au and CuNCs) have emerged as a new class of signaling moiety for biosensor development. Compared to semiconductor quantum dots, metal NCs have less toxicity concerns and can be more easily conjugated to biopolymers. Due to their extremely small size, these NCs need a stabilizing ligand. Many polymers, proteins and nucleic acids have been reported to stabilize NCs. In particular, many DNA sequences produce highly fluorescence NCs. Coupling these DNA stabilizers with other sequences such as aptamers has generated a large number of biosensors. In this review, the synthesis of DNA and nucleotide-templated NCs is first summarized; their chemical interactions are also discussed. In the second part, the properties of NCs such as fluorescence quantum yield, emission wavelength and lifetime, structure and photostability are briefly reviewed. In the last part, various sensor design strategies using these NCs are categorized into the following four classes: 1) fluorescence de-quenching; 2) generation of templating DNA sequences to produce NCs; 3) change of nearby environment; and 4) reacting with heavy metal ions or other quenchers. Finally, the future trends in this field are discussed.

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Section: Synthesis Of Ncsmentioning

confidence: 99%

DNA-stabilized, fluorescent, metal nanoclusters for biosensor development

Liu

2014

TrAC Trends in Analytical Chemistry

195

141

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“…While such sub-nm nanoclusters are too small to have the continuous density of states (DOS) necessary to support a "plasmon" characteristic of larger free electron metal nanoparticles (1,44), the jellium model predicts that both nanoparticle plasmon widths and nanocluster transition energies of true free electron metals should scale with inverse cluster radius (40). As gas phase photodissociation experiments are unable to probe the lowest energy transitions (1), the size-dependent behavior of gold and the development of the plasmon remain poorly understood (1,7,9,(45)(46)(47).…”

Section: Absorption and Emission Of Noble Metal Clustersmentioning

confidence: 99%

Highly Fluorescent Noble-Metal Quantum Dots

Zheng

Nicovich

Dickson

2007

Annu. Rev. Phys. Chem.

1,213

1,115

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Highly fluorescent, water-soluble, few-atom noble metal quantum dots have been created that behave as multi-electron artificial atoms with discrete, size-tunable electronic transitions throughout the visible and near IR. These "molecular metals" exhibit highly polarizable transitions and scale in size according to the simple relation, E fermi /N 1/3 , predicted by the free electron model of metallic behavior. This simple scaling indicates that fluorescence arises from intraband transitions of free electrons and that these conduction electron transitions are the low number limit of the plasmonthe collective dipole oscillations occurring when a continuous density of states is reached. Providing the "missing link" between atomic and nanoparticle behavior in noble metals, these emissive, watersoluble Au nanoclusters open new opportunities for biological labels, energy transfer pairs, and light emitting sources in nanoscale optoelectronics.

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“…While finding utility within electronic devices (17,18) and even as electrically excited single-photon sources at cryogenic temperatures (19), the useful properties of individual molecules have not, to date, been used to create novel optical or electroluminescent materials with behavior different from that in bulk. Recently, we reported photoactivated fluorescence from individual Ag n nanoclusters (n ϭ 2ϳ8 atoms) (20), which have been observed and calculated to absorb and emit strongly throughout the visible spectrum (21)(22)(23)(24). Here we report that these same Ag n molecules can be electrically created, thus demonstrating that it is possible to prepare room-temperature electroluminescent single molecules.…”

mentioning

confidence: 74%

“…The similarity to photoactivated single silver nanocluster fluorescence (20,28) indicates that both fluorescence and electroluminescence occur from individual Ag n molecules. Since each Ag n molecule has discrete electronic energy levels defined by its size and geometry (21)(22)(23)(24), radiative electron-hole pair recombination occurs only at the Ag nanoclusters within the discolored AgO regions of the films. This narrow recombination zone leads to extremely low film dielectricity, except at the individual electroluminescent molecules.…”

mentioning

confidence: 99%

Strongly enhanced field-dependent single-molecule electroluminescence

Lee

González

Dickson

2002

Proc. Natl. Acad. Sci. U.S.A.

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Individual, strongly electroluminescent Agn molecules (n ‫؍‬ 2ϳ8 atoms) have been electrically written within otherwise nonemissive silver oxide films. Exhibiting characteristic single-molecule behavior, these individual room-temperature molecules exhibit extreme electroluminescence enhancements (>10 4 vs. bulk and dc excitation on a per molecule basis) when excited with specific ac frequencies. Occurring through field extraction of electrons with subsequent reinjection and radiative recombination, single-molecule electroluminescence is enhanced by a general mechanism that avoids slow bulk material response. Thus, while we detail strong electroluminescence from single, highly fluorescent Agn molecules, this mechanism also yields strong ac-excited electroluminescence from similarly prepared, but otherwise nonemissive, individual Cu nanoclusters.

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Chemiluminescence in the Agglomeration of Metal Clusters

Cited by 114 publications

References 11 publications

DNA-stabilized, fluorescent, metal nanoclusters for biosensor development

DNA-stabilized, fluorescent, metal nanoclusters for biosensor development

Highly Fluorescent Noble-Metal Quantum Dots

Strongly enhanced field-dependent single-molecule electroluminescence

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