%0 Journal Article %1 Rey2009 %A Rey, A. M. %A Sensarma, R. %A Folling, S. %A Greiner, M. %A Demler, E. %A Lukin, M. D. %D 2009 %J EPL (Europhysics Letters) %K superlattice proposal fermions superconductivity %N 6 %P 60001 (6pp) %T Controlled preparation and detection of d-wave superfluidity in two-dimensional optical superlattices %U http://stacks.iop.org/0295-5075/87/60001 %V 87 %X d-wave Cooper pairs are believed to be the key for understanding the phenomenon of high-temperature superconductivity in cuprates. These superconductors are an example of the emergence of strong pairing in systems with purely repulsive interactions, similar to superfluid helium 3 and the newly discovered iron oxypnictides. Despite intense studies, there is currently no consensus as to what causes the formation of d-wave Cooper pairs in these materials. Here we propose a novel experimental scheme in which recently demonstrated methods for realizing optical lattices and superlattices are combined to create and to detect, in a controlled way, ultracold-atom d-wave Cooper pairs. Our scheme starts from arrays of isolated plaquettes which incorporate the required d-wave correlations on a short length scale. By tuning the parameters of the potentials, these plaquettes can be coupled to achieve long-range d-wave superfluid correlations, finally arriving at the generic Hubbard model.

@article{Rey2009, abstract = {d-wave Cooper pairs are believed to be the key for understanding the phenomenon of high-temperature superconductivity in cuprates. These superconductors are an example of the emergence of strong pairing in systems with purely repulsive interactions, similar to superfluid helium 3 and the newly discovered iron oxypnictides. Despite intense studies, there is currently no consensus as to what causes the formation of d-wave Cooper pairs in these materials. Here we propose a novel experimental scheme in which recently demonstrated methods for realizing optical lattices and superlattices are combined to create and to detect, in a controlled way, ultracold-atom d-wave Cooper pairs. Our scheme starts from arrays of isolated plaquettes which incorporate the required d-wave correlations on a short length scale. By tuning the parameters of the potentials, these plaquettes can be coupled to achieve long-range d-wave superfluid correlations, finally arriving at the generic Hubbard model.}, added-at = {2009-11-15T22:37:30.000+0100}, author = {Rey, A. M. and Sensarma, R. and Folling, S. and Greiner, M. and Demler, E. and Lukin, M. D.}, biburl = {https://www.bibsonomy.org/bibtex/25a143acbaa42a4d2dd538b29bbb7c65e/lindoze}, description = {Controlled preparation and detection of d-wave superfluidity in two-dimensional optical superlattices}, interhash = {633b4eaf5afa3998ce095644cb57768c}, intrahash = {5a143acbaa42a4d2dd538b29bbb7c65e}, journal = {EPL (Europhysics Letters)}, keywords = {superlattice proposal fermions superconductivity}, number = 6, pages = {60001 (6pp)}, timestamp = {2009-11-15T22:37:30.000+0100}, title = {Controlled preparation and detection of d-wave superfluidity in two-dimensional optical superlattices}, url = {http://stacks.iop.org/0295-5075/87/60001}, volume = 87, year = 2009 }