2007
DOI: 10.1088/0034-4885/70/12/r02
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Symmetry breaking and quantum correlations in finite systems: studies of quantum dots and ultracold Bose gases and related nuclear and chemical methods

Abstract: Investigations of emergent symmetry breaking phenomena occurring in small finite-size systems are reviewed, with a focus on the strongly correlated regime of electrons in two-dimensional semiconductor quantum dots and trapped ultracold bosonic atoms in harmonic traps. Throughout the review we emphasize universal aspects and similarities of symmetry breaking found in these systems, as well as in more traditional fields like nuclear physics and quantum chemistry, which are characterized by very different interpa… Show more

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Cited by 240 publications
(369 citation statements)
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References 281 publications
(1,081 reference statements)
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“…In summary, focusing on the mesoscopic regime of electron interferometry, and using the Bardeen weak-coupling theory in conjunction with exact diagonalization of the many-body quantum dot Hamiltonian, we have shown for the first two transitions, (a) N = 1 → N = 2 and (b) N = 2 → N = 3, nonuniversal behavior of the transmission phases with no phase lapse for (a) and a phase lapse of π for (b), in agreement with the experiment [2]. These results were obtained for a range of dot parameters characterized by shape anisotropy and strong e − e repulsion, with both favoring electron localization and formation of Wigner molecules [5,15,16,17]. Additionally, our analysis of the quasiparticle wavefunction [Eq.…”
supporting
confidence: 85%
“…In summary, focusing on the mesoscopic regime of electron interferometry, and using the Bardeen weak-coupling theory in conjunction with exact diagonalization of the many-body quantum dot Hamiltonian, we have shown for the first two transitions, (a) N = 1 → N = 2 and (b) N = 2 → N = 3, nonuniversal behavior of the transmission phases with no phase lapse for (a) and a phase lapse of π for (b), in agreement with the experiment [2]. These results were obtained for a range of dot parameters characterized by shape anisotropy and strong e − e repulsion, with both favoring electron localization and formation of Wigner molecules [5,15,16,17]. Additionally, our analysis of the quasiparticle wavefunction [Eq.…”
supporting
confidence: 85%
“…In keeping with previous literature on two electrons in semiconductor quantum dots 21,30 , base 2 logarithms are used.…”
mentioning
confidence: 99%
“…We shall focus here on solutions preserving not only the total spin component S z but also the total spin S 2 , i.e., on RHF or ROHF solutions. The total-spin-violating solutions that arise in the presence of a triplet or a nonsinglet instability in closed-shell systems lead to UHF solutions that break the S 2 invariance and often also the space symmetry (as is, e.g., the case for quantum dots; see reviews [44,45]). Clearly, open-shell systems are always unstable to total-spin breaking in view of spin-polarization due to a different number of spin-up and spindown electrons.…”
Section: Broken-symmetry Solutions Vs Broken-symmetry Structuresmentioning
confidence: 99%