Electron Cotunneling Transport in Gold Nanocrystal Arrays

Moreira, Henrique Morávia de Andrade Santos; Yu, Qian; Nadal, Brice; Bresson, Bruno; Rosticher, Michaël; Lequeux, Nicolas; Zimmers, A.; Aubin, H.

doi:10.1103/physrevlett.107.176803

Cited by 38 publications

(60 citation statements)

References 31 publications

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“…When the temperature is low enough, the current at low bias is suppressed due to Coulomb blockade. 45 There is a reliable way to determine the Coulomb charging energy in nanoparticle arrays. Theoretically, in the I-V curves of nanoparticle arrays at low temperature, there should exist a voltage threshold V th below which the current is suppressed.…”

Section: Andmentioning

confidence: 99%

Ordered nanoparticle arrays interconnected by molecular linkers: electronic and optoelectronic properties

et al. 2015

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Arrays of metal nanoparticles in an organic matrix have attracted a lot of interest due to their diverse electronic and optoelectronic properties. Recent work demonstrates that nanoparticle arrays can be utilized as a template structure to incorporate single molecules. In this arrangement, the nanoparticles act as electronic contacts to the molecules. By varying parameters such as the nanoparticle material, the matrix material, the nanoparticle size, and the interparticle distance, the electronic behavior of the nanoparticle arrays can be substantially tuned and controlled. Furthermore, via the excitation of surface plasmon polaritons, the nanoparticles can be optically excited and electronically read-out. The versatility and possible applications of well-ordered nanoparticle arrays has been demonstrated by the realization of switching devices triggered optically or chemically and by the demonstration of chemical and mechanical sensing. Interestingly, hexagonal nanoparticle arrays may also become a useful platform to study the physics of collective plasmon resonances that can be described as Dirac-like bosonic excitations.

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Section: Andmentioning

confidence: 99%

Ordered nanoparticle arrays interconnected by molecular linkers: electronic and optoelectronic properties

et al. 2015

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“…In order to discuss conduction by electron pairs, one can similarly define the energy associated with pair excitations, in analogy with Eqs. (12) and (11). Specifically:…”

Section: Modelmentioning

confidence: 99%

“…Since we are considering the case of relatively large grains, we also assume that the spacing δ between discrete electron energy eigenstates within the grain satisfies δ E c . In relatively dense arrays, electron conduction can occur both through hopping of electrons between nearestneighboring grains and through "cotunneling" of electrons between distant grains via a chain of intermediate virtual states in intervening grains 1,8,11,12 . In the presence of some disorder, the latter mechanism dominates at low temperatures, where the length of hops grows to optimize the conductivity.…”

Section: Introductionmentioning

confidence: 99%

Coulomb gap triptychs,2effective charge, and hopping transport in periodic arrays of superconductor grains

2012

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In granular superconductors, individual grains can contain bound Cooper pairs while the system as a whole is strongly insulating. In such cases the conductivity is determined by electron hopping between localized states in individual grains. Here we examine a model of hopping conductivity in such an insulating granular superconductor, where disorder is assumed to be provided by random charges embedded in the insulating gaps between grains. We use computer simulations to calculate the single-electron and electron pair density of states at different values of the superconducting gap ∆, and we identify "triptych" symmetries and scaling relations between them. At a particular critical value of ∆, one can define an effective charge √ 2e that characterizes the density of states and the hopping transport. We discuss the implications of our results for magnetoresistance and tunneling experiments.

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“…Granular metals and arrays of metallic nanocrystals (NCs) represent interesting composite systems, wherein the unique properties of individual NCs are combined with collective, correlation-driven effects between NCs to produce novel material properties [1,2]. One of the most important of these properties is the electron conductivity, which proceeds by electron tunneling, or "hopping", between NCs through the insulating gaps which separate them.…”

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confidence: 99%

Coulomb Gap Triptych in a Periodic Array of Metal Nanocrystals

2012

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The Coulomb gap in the single-particle density of states (DOS) is a universal consequence of electron-electron interaction in disordered systems with localized electron states. Here we show that in arrays of monodisperse metallic nanocrystals, there is not one but three identical adjacent Coulomb gaps, which together form a structure that we call a "Coulomb gap triptych." We calculate the DOS and the conductivity in two- and three-dimensional arrays using a computer simulation. Unlike in the conventional Coulomb glass models, in nanocrystal arrays the DOS has a fixed width in the limit of large disorder. The Coulomb gap triptych can be studied via tunneling experiments.

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Electron Cotunneling Transport in Gold Nanocrystal Arrays

Cited by 38 publications

References 31 publications

Ordered nanoparticle arrays interconnected by molecular linkers: electronic and optoelectronic properties

Ordered nanoparticle arrays interconnected by molecular linkers: electronic and optoelectronic properties

Coulomb gap triptychs,2effective charge, and hopping transport in periodic arrays of superconductor grains

Coulomb Gap Triptych in a Periodic Array of Metal Nanocrystals

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