Physics – Condensed Matter – Superconductivity
Scientific paper
2011-03-11
Science 331, 1579-1583 (2011)
Physics
Condensed Matter
Superconductivity
Scientific paper
10.1126/science.1198415
In this supporting material for the main paper (the preceding submission), we show, in addition to the related information for the experiments, additional discussion that cannot fit in the main paper (due to the space constraint). It includes further discussion about our experimental observations, wider implications of our main findings with various reported candidates for the pseudogap order, and a simple mean-field argument that favors interpretations based on a finite-Q order (density wave) for the pseudogap seen by ARPES (whether "the pseudogap order" is a single order or contains multiple ingredients, is an independent, open issue). We also include a detailed simulation section, in which we model different candidates (various density wave/nematic order) for the pseudogap order in simple forms using a mean-field approach, and discuss their partial success as well as limitations in describing the experimental observations. These simulations are based on a tight-binding model with parameters fitted globally (and reasonably well) to the experimental band dispersions (by tracking the maximum of the energy distribution curve), which could be useful for further theoretical explorations on this issue.
Devereaux Thomas P.
Eisaki Hiroshi
Hashimoto Makoto
He Rui-Hua
Hinton J. P.
No associations
LandOfFree
From a single-band metal to a high-temperature superconductor via two thermal phase transitions (Supporting Material) does not yet have a rating. At this time, there are no reviews or comments for this scientific paper.
If you have personal experience with From a single-band metal to a high-temperature superconductor via two thermal phase transitions (Supporting Material), we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and From a single-band metal to a high-temperature superconductor via two thermal phase transitions (Supporting Material) will most certainly appreciate the feedback.
Profile ID: LFWR-SCP-O-278032