J.H. Ojeda scite author profile

J.H. Ojeda

3Publications

42Citation Statements Received

55Citation Statements Given

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Affiliations

Pedagogical and Technological University of Colombia, University of Tarapacá, Federico Santa María Technical University

Publications

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An array of quantum dots as a spin filter device by using Dicke and Fano effects

2009

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Recently, there has been much interest in understanding the manner in which the unique properties of nanostructures may be exploited in spintronics devices, which utilize the spin degree of freedom of the electron as the basis of their operation [1][2]. A natural feature of these devices is the direct connection between their conductance and their quantum-mechanical transmission properties, which may allow their use as an all-electrical means for generating and detecting spin polarized distributions of carriers.Quantum dots are man-made nanostructures in which electrons are confined in all space dimensions [3]. Energy and charge quantization results from this confinement. As both features are present in real atomic systems, useful analogies between real and artificial atomic systems have been exploited recently. Enforcing this analogy, Fano [4][5] and Dicke effects [6] were also found to be present in quantum dot configurations. On the other hand, Song et al. [2] described how a spin filter may be achieved in open quantum dot systems, by exploiting the Fano resonances that occur in their transmission characteristic. In a quantum dot in which the spin degeneracy of carrier is lifted they showed that the Fano effect may be used as an effective means to generate spin polarization of transmitted carriers and that electrical detection of the resulting polarization should be possible.In a previous work [7], we showed that in side-coupled double quantum-dot system the transmission shows a large peak-to-valley ratio. Moreover, the difference of energy between the resonances and antiresonances can be controlled adjusting the difference between the energy levels of the two quantum dots by gate voltages due to the Dicke effect. The Dicke effect in optics takes place in the spontaneous emission of a pair of atoms radiating a photon with a wavelength much larger than the separation between them [6]. The luminescence spectrum is characterized by a narrow and a broad peak, associated with long and short-lived states, respectively. The former state, coupled weakly to the electromagnetic field, is called subradiant, and the latter, strongly coupled, a superradiant state. In the present work, we show that the above properties can be used to design an efficient spin filter with a quantum dot array system. We show that by controlling the Fano and Dicke effects this system can be used as an efficient spin filter even for small values of the magnetic field.In this work we propose a new design of a spin-dependent polarizer. The device consists of a quantum dot array coupled to leads, as shown schematically in Fig1. By lifting the spin degeneracy of the carriers in a quantum dot by means of a magnetic field, Fano and Dicke effects are used as effective means to generate spin polarization of the electrical current. A detailed analysis of the spin-dependent transmission and polarized current is carried out. For instance, in Fig. 2 we show a contour plot with the weighted spin polarization for a fixed magnetic field of as a function of th...

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Trapping and motion of polarons in weakly disordered DNA molecules

Ojeda

Lima

Domı́nguez-Adame

et al. 2009

J. Phys.: Condens. Matter

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Polaron effects for charge migration in DNA molecules have been previously considered within the Peyrard-Bishop-Holstein model. When a uniform electric field is applied, the polaron moves asymptotically at a constant velocity, provided dissipative effects are taken into account, and then current flows through DNA. Disorder originating from interactions with a random environment of solute molecules and ions surrounding the DNA molecule could prevent charge migration due to the localization of the carrier wavefunction. We studied numerically the Peyrard-Bishop-Holstein model when the disordered DNA molecule is subjected to a uniform electric field. We found the threshold value of the electric field to observe polaron motion when disorder is present. We also calculated the fluctuations of the electric current and found that they provide valuable information about the polaron dynamics.

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Exciton states in conical quantum dots under applied electric and magnetic fields

Heyn

Radu

Vinasco

et al. 2021

Optics & Laser Technology

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J.H. Ojeda

An array of quantum dots as a spin filter device by using Dicke and Fano effects

Trapping and motion of polarons in weakly disordered DNA molecules

Exciton states in conical quantum dots under applied electric and magnetic fields

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