Fine structure of excitons in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">Cu</mml:mi></mml:mrow><mml:mrow><mml:mn>2</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math>O

Kavoulakis, G. M.; Chang, Yia‐Chung; Baym, Gordon

doi:10.1103/physrevb.55.7593

Cited by 92 publications

(139 citation statements)

References 25 publications

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“…It could be identified as the lattice constant for realistic band dispersion, but should be considered as an effective model parameter in the present simple treatment, similar to Ref. 4.…”

Section: The Exciton Modelmentioning

confidence: 99%

“…Central-cell corrections become important, which account for the possibility of finding electron and hole in the same unit cell and include non-parabolic dispersions and modifications of the 1/r-Coulomb potential 4 . A prototypical material is the cuprous oxide Cu 2 O, which receives constant attention in the search for an excitonic Bose-Einstein condensate 5,6 .…”

Section: Introductionmentioning

confidence: 99%

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Variational discrete variable representation for excitons on a lattice

Alvermann¹,

Littlewood²,

Fehske

2011

Phys. Rev. B

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We construct numerical basis function sets on a lattice, whose spatial extension is scalable from single lattice sites to the continuum limit.They allow us to compute small and large bound states with comparable, moderate effort. Adopting concepts of discrete variable representations, a diagonal form of the potential term is achieved through a unitary transformation to Gaussian quadrature points. Thereby the computational effort in three dimensions scales as the fourth instead of the sixth power of the number of basis functions along each axis, such that it is reduced by two orders of magnitude in realistic examples. As an improvement over standard discrete variable representations, our construction preserves the variational principle. It allows for the calculation of binding energies, wave functions, and excitation spectra. We use this technique to study central-cell corrections for excitons beyond the continuum approximation. A discussion of the mass and spectrum of the yellow exciton series in the cuprous oxide, which does not follow the hydrogenic Rydberg series of Mott-Wannier excitons, is given on the basis of a simple lattice model.

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“…It could be identified as the lattice constant for realistic band dispersion, but should be considered as an effective model parameter in the present simple treatment, similar to Ref. 4.…”

Section: The Exciton Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Variational discrete variable representation for excitons on a lattice

Alvermann¹,

Littlewood²,

Fehske

2011

Phys. Rev. B

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“…The exciton effective mass m 2 e =m 2 X ¼ 0:14, binding energy Ry 1S ¼ 153 meV and Bohr radius a X ¼ 5.1 A˚are given by the ''central cell correction'' model [1]. They are modified by non-parabolicity of the conduction and valence bands, the coupling of the exciton electron and hole with the longitudinal optical phonons and by the dielectric function dependence on the distance between the electron and hole.…”

Section: Pss-bcommentioning

confidence: 99%

“…The relatively large effective mass of the electrons in the conduction band (m e ) and holes in the valence band (m h ) results in a small exciton radius (a X ¼ 5.1 Å ), according to Kavoulakis [1] who considered ''central cell corrections.'' Equal parity of the conduction and valence band states produces dipole-forbidden, quadrupole-allowed 1S exciton which is characterized by a long radiative life-time depending on a dominating dephasing mechanism and varies from ns to ps.…”

mentioning

confidence: 99%

Coherent manipulation of quadrupole biexcitons in cuprous oxide by 2D femtosecond spectroscopy

Roslyak

Aparajita

Birman

et al. 2011

Physica Status Solidi (b)

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We propose using coherent optical spectroscopy to study and control optically-forbidden (dark) biexciton states in crystals of cuprous oxide. These states are revealed in the correlation spectra cross resonances due to coherence with the quadrupole allowed 1S exciton manifold. The signal is obtained by means of sum-over-state formalism and comparing equations of motion for the weakly interacting quadrupole excitons with their analogue of non-interacting quasiparticles. The dephasing mechanisms include rapid Auger relaxation of biexcitons which allegedly impedes the Bose-Einstein condensation of quadrupole excitons. An interesting effect attributed to the deviation of the quadrupole excitons from the ortho-para excitons picture is that the positions of the biexciton resonances are defined by the energy splitting between G þ 5;yz and G þ 5;xz excitons and can be tuned by an external perturbation. Possible quantum computing and lasing applications of the quadrupole induced chirality effects of the excitons and biexcitons, and coherence between exciton/biexciton manifolds are discussed. '' Equal parity of the conduction and valence band states produces dipole-forbidden, quadrupole-allowed 1S exciton which is characterized by a long radiative life-time depending on a dominating dephasing mechanism and varies from ns to ps. At low exciton density the measured life-time (%1.7 ns) is determined by phononassisted non-radiative transitions between ortho (J ¼ 1) and optically forbidden para (J ¼ 0) excitons separated by 12 meV due to spin-orbit interaction. Thanks to the small radius, the exciton gas saturation density n s ¼ 10 20 cm À3 is much higher than the critical density n c ¼ 10 17 cm À3 needed for the quadrupole exciton BEC at T ¼ 2 K.Unfortunately, BEC turned out to be an elusive goal due to a strong recombination process that becomes effective at gas densities above %10 14 cm À3 . Usually, this undesirable

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“…Being a coherent quantum superposition of a quadrupole exciton and a photon, this electron in the lowest conduction band ( 2 Γ + 6 ) and a hole in the highest valence band ( 2 Γ + 7 ), and shows a hydrogenic Rydberg series in the optical absorption spectrum [Hayashi & Katsuki (1952)]. Including so-called central cell corrections [Kavoulakis et al (1997)], a spectroscopic fit to the observed Rydberg series reveals a tightly bound 1s excitonic state with a binding energy of 153 meV, corresponding to Bohr radius of 0.7 nm. The measured translational mass of the exciton is about 2.7m e ,wherem e is the electron mass ].…”

Section: Introductionmentioning

confidence: 99%

Cuprous Oxide (Cu2O): A Unique System Hosting Various Excitonic Matter and Exhibiting Large Third-Order Nonlinear Optical Responses

Jang¹

2011

Optoelectronics - Materials and Techniques

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Fine structure of excitons inCu2O

Cited by 92 publications

References 25 publications

Variational discrete variable representation for excitons on a lattice

Variational discrete variable representation for excitons on a lattice

Coherent manipulation of quadrupole biexcitons in cuprous oxide by 2D femtosecond spectroscopy

Cuprous Oxide (Cu2O): A Unique System Hosting Various Excitonic Matter and Exhibiting Large Third-Order Nonlinear Optical Responses

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