Transport through nanostructures with asymmetric coupling to the leads

Celardo, G. L.; Smith, A. Matthew; Sorathia, S.; Zelevinsky, Vladimir; Sen'kov, R. A.; Kaplan, L.

doi:10.1103/physrevb.82.165437

Cited by 46 publications

(60 citation statements)

References 32 publications

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“…We start from an idealized description of the heterostructure where the interlayer transport of a single excitation is modeled by a one dimensional N -site chain connected to one collector and one source. Within this simple approach we obtain analytic expressions to estimate the parameters range compatible with quantum-transport efficiency enhancement, and we are able to connect the optimal transport conditions with the superradiant transition [15][16][17] , which takes place as a function of the ratio between the coupling with the leads γ out and the hopping between the sites of the chain t. When γ out t all the N eigenstates acquire a finite lifetime of the order of N /γ out , thus allowing coherent transport throughout the chain. In the opposite regime γ out t one superradiant edge solution appears, spatially located at the edge (N th ) site, which acquires a broadening much larger than the average one.…”

Section: Introductionmentioning

confidence: 99%

Towards high-temperature coherence-enhanced transport in heterostructures of a few atomic layers

et al. 2019

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The possibility to exploit quantum coherence to strongly enhance the efficiency of charge transport in solid state devices working at ambient conditions would pave the way to disruptive technological applications. In this work, we tackle the problem of the quantum transport of photogenerated electronic excitations subject to dephasing and on-site Coulomb interactions. We show that the transport to a continuum of states representing metallic collectors can be optimized by exploiting the "superradiance" phenomena. We demonstrate that this is a coherent effect which is robust against dephasing and electron-electron interactions in a parameters range that is compatible with actual implementation in few monolayers transition-metal-oxide (TMO) heterostructures.

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Section: Introductionmentioning

confidence: 99%

Towards high-temperature coherence-enhanced transport in heterostructures of a few atomic layers

et al. 2019

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“…The deviations from the PTD grow with κ up to the critical strength κ ∼ 1, when the broad "superradiant" state becomes essentially part of the background, while the remaining "trapped" states return to the weak-coupling regime. This physics was repeatedly discussed previously, especially in relation to quantum signal transmission through mesoscopic devices [21,29], but it is outside of our interest here.…”

Section: Discussionmentioning

confidence: 96%

Resonance width distribution for open quantum systems

Shchedrin

Zelevinsky

2012

Phys. Rev. C

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Recent measurements of resonance widths for low-energy neutron scattering off heavy nuclei show large deviations from the standard Porter-Thomas distribution. We propose a new resonance width distribution based on the random matrix theory for an open quantum system. Two methods of derivation lead to a single analytical expression; in the limit of vanishing continuum coupling, we recover the Porter-Thomas distribution. The result depends on the ratio of typical widths $\Gamma$ to the energy level spacing $D$ via the dimensionless parameter $\kappa=(\pi\Gamma/2D)$. The new distribution suppresses small widths and increases the probabilities of larger widths.Comment: 8 pages, 2 figure

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“…Indeed, since Anderson's paper, the study of electron transport has played a key role in the development of modern solid state physic, see for instance Refs. [6,7,8] and references therein. The systems of interest, here, are nanostructured devices made of an insulating matrix embedding randomly distributed drops of conducting material.…”

Section: Introductionmentioning

confidence: 99%

Quantum thermostatted disordered systems and sensitivity under compression

Vanzan

Rondoni

2018

Physica A: Statistical Mechanics and its Applications

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A one-dimensional quantum system with off diagonal disorder, consisting of a sample of conducting regions randomly interspersed within potential barriers is considered. Results mainly concerning the large N limit are presented. In particular, the effect of compression on the transmission coefficient is investigated. A numerical method to simulate such a system, for a physically relevant number of barriers, is proposed. It is shown that the disordered model converges to the periodic case as N increases, with a rate of convergence which depends on the disorder degree. Compression always leads to a decrease of the transmission coefficient which may be exploited to design nano-technological sensors. Effective choices for the physical parameters to improve the sensitivity are provided. Eventually large fluctuations and rate functions are analysed.

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Transport through nanostructures with asymmetric coupling to the leads

Cited by 46 publications

References 32 publications

Towards high-temperature coherence-enhanced transport in heterostructures of a few atomic layers

Towards high-temperature coherence-enhanced transport in heterostructures of a few atomic layers

Resonance width distribution for open quantum systems

Quantum thermostatted disordered systems and sensitivity under compression

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