Qubits with electrons on liquid helium

Dykman, M. I.; Platzman, P. M.; Seddighrad, P.

doi:10.1103/physrevb.67.155402

Cited by 120 publications

(164 citation statements)

References 33 publications

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“…44 Despite its simplicity, this model has been useful for studying the behavior of many physical systems, such as Rydberg atoms in external fields 45,46 or the dynamics of surface-state electrons in liquid helium 47,48 and its potential application to quantum computing. 49,50 Most work since Loudon has focused on one-electron ions 44,[51][52][53][54][55][56][57] and, to the best of our knowledge, no calculation has been reported for larger chemical systems. In part, this can be attributed to the ongoing controversy concerning the mathematical structure of the eigenfunctions.…”

Section: D Chemistrymentioning

confidence: 99%

Chemistry in one dimension

Loos

Ball

Gill

2015

Phys. Chem. Chem. Phys.

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We report benchmark results for one-dimensional (1D) atomic and molecular systems interacting via the Coulomb operator |x| −1 . Using various wavefunction-type approaches, such as Hartree-Fock theory, second-and third-order Møller-Plesset perturbation theory and explicitly correlated calculations, we study the ground state of atoms with up to ten electrons as well as small diatomic and triatomic molecules containing up to two electrons. A detailed analysis of the 1D helium-like ions is given and the expression of the high-density correlation energy is reported. We report the total energies, ionization energies, electron affinities and other interesting properties of the many-electron 1D atoms and, based on these results, we construct the 1D analog of Mendeleev's periodic table. We find that the 1D periodic table contains only two groups: the alkali metals and the noble gases. We also calculate the dissociation curves of various 1D diatomics and study the chemical bond in H + 2 , HeH 2+ , He 3+ 2 , H 2 , HeH + and He 2+ 2 . We find that, unlike their 3D counterparts, 1D molecules are primarily bound by one-electron bonds. Finally, we study the chemistry of H + 3 and we discuss the stability of the 1D polymer resulting from an infinite chain of hydrogen atoms.

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Section: D Chemistrymentioning

confidence: 99%

Chemistry in one dimension

Loos

Ball

Gill

2015

Phys. Chem. Chem. Phys.

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“…The upper-bound limit lifetime of excited states of surface electrons in a quantum dot is found to be t < -10 6 -10 7 -s. Surface electrons (SEs) localized over the liquid helium surface have been an remarkable archetype for studying confined charged systems of low dimensionality [1,2]. In particular and more important, SE systems have been intensively investigated in the last years as potential candidate of qubit generators in quantum computation [3,4]. The main reasons for this are twofold.…”

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confidence: 99%

“…In particular and more important, SE systems have been intensively investigated in the last years as potential candidate of qubit generators in quantum computation [3,4]. The main reasons for this are twofold.…”

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confidence: 99%

“…The problem of the decay rate and the subband lifetime t, which is inversely proportional to decay rate, was first discussed in Ref. 4. The authors concluded that the contribution of the oneripplon scattering processes predominates.…”

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confidence: 99%

“…On the contrary, for long wavelength ripplons N T q q ; / hw >>1. Therefore a linear T -dependence of the decay rate is obtained when only the one-ripplon process is considered [4].…”

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Confinement effects on decay rate of surface electron states over liquid helium

Соколов

Monarkha

Villas‐Bôas

et al. 2008

Low Temperature Physics

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The decay rate of excited states of surface electrons in liquid helium, trapped in a quantum dot system, is evaluated, taking into account the process of spontaneous radiation of two-ripplons with short wavelength. We find that the values of the decay rate in later process are rather higher than those for the one-ripplon process previously calculated. The upper-bound limit lifetime of excited states of surface electrons in a quantum dot is found to be t < -10 6 -10 7 -s. Surface electrons (SEs) localized over the liquid helium surface have been an remarkable archetype for studying confined charged systems of low dimensionality [1,2]. In particular and more important, SE systems have been intensively investigated in the last years as potential candidate of qubit generators in quantum computation [3,4]. The main reasons for this are twofold. Firstly, the energy spectrum of SEs is quite simple and well-known. In the limit of zero holding electric field E^oriented in the normal direction to the electron layer, the spectrum is given by hydrogenic-like subbandswhereHe He , e He ; 1 0572 . is liquid helium dielectric constant, e and m are electron charge and mass, respectively. The total electron energy is given by E E

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Information theory of D-dimensional hydrogenic systems: Application to circular and Rydberg states

Dehesa

López-Rosa

Martínez–Finkelshtein

et al. 2009

Int. J. Quantum Chem.

151

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ABSTRACT:The analytic information theory of quantum systems includes the exact determination of their spatial extension or multidimensional spreading in both position and momentum spaces by means of the familiar variance and its generalization, the power and logarithmic moments, and, more appropriately, the Shannon entropy and the Fisher information. These complementary uncertainty measures have a global or local character, respectively, because they are power-like (variance, moments), logarithmic (Shannon) and gradient (Fisher) functionals of the corresponding probability distribution. Here we explicitly discuss all these spreading measures (and their associated uncertainty relations) in both position and momentum for the main prototype in D-dimensional physics, the hydrogenic system, directly in terms of the dimensionality and the hyperquantum numbers which characterize the involved states. Then, we analyze in detail such measures for s-states, circular states (i.e., single-electron states of highest angular momenta allowed within an electronic manifold characterized by a given principal hyperquantum number), and Rydberg states (i.e., states with large radial hyperquantum numbers n).

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Qubits with electrons on liquid helium

Cited by 120 publications

References 33 publications

Chemistry in one dimension

Chemistry in one dimension

Confinement effects on decay rate of surface electron states over liquid helium

Information theory of D-dimensional hydrogenic systems: Application to circular and Rydberg states

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