by Lu, Haiyu, Hashimoto, Makoto, Chen, Su-Di, Ishida, Shigeyuki, Song, Dongjoon, Eisaki, Hiroshi, Nag, Abhishek, Garcia-Fernandez, Mirian, Arpaia, Riccardo, Ghiringhelli, Giacomo, Braicovich, Lucio, Zaanen, Jan, Moritz, Brian, Kummer, Kurt, Brookes, Nicholas B., Zhou, Ke-Jin, Shen, Zhi-Xun, Devereaux, Thomas P. and Lee, Wei-Sheng
Abstract:
Identifying quantum critical points (QCPs) and their associated fluctuations may hold the key to unraveling the unusual electronic phenomena observed in cuprate superconductors. Recently, signatures of quantum fluctuations associated with charge order (CO) have been inferred from the anomalous enhancement of CO excitations that accompany the reduction of the CO order parameter in the superconducting state. To gain more insight into the interplay between CO and superconductivity, here we investigate the doping dependence of this phenomenon throughout the Bi-2212 cuprate phase diagram using resonant inelastic x-ray scattering (RIXS) at the Cu L3 edge. As doping increases, the CO wave vector decreases, saturating near a commensurate value of 0.25 reciprocal lattice unit beyond a characteristic doping pc, where the correlation length becomes shorter than the apparent periodicity (4a0). Such behavior is indicative of the fluctuating nature of the CO; the proliferation of CO excitations in the superconducting state also appears strongest at pc, consistent with expected behavior at a CO QCP. Intriguingly, pc appears to be near optimal doping, where the superconducting transition temperature Tc is maximal. © 2022 American Physical Society.
Reference:
Identification of a characteristic doping for charge order phenomena in Bi-2212 cuprates via RIXS (Lu, Haiyu, Hashimoto, Makoto, Chen, Su-Di, Ishida, Shigeyuki, Song, Dongjoon, Eisaki, Hiroshi, Nag, Abhishek, Garcia-Fernandez, Mirian, Arpaia, Riccardo, Ghiringhelli, Giacomo, Braicovich, Lucio, Zaanen, Jan, Moritz, Brian, Kummer, Kurt, Brookes, Nicholas B., Zhou, Ke-Jin, Shen, Zhi-Xun, Devereaux, Thomas P. and Lee, Wei-Sheng), In Physical Review B, volume 106, 2022.
Bibtex Entry:
@ARTICLE{Lu2022,
author = {Lu, Haiyu and Hashimoto, Makoto and Chen, Su-Di and Ishida, Shigeyuki and Song, Dongjoon and Eisaki, Hiroshi and Nag, Abhishek and Garcia-Fernandez, Mirian and Arpaia, Riccardo and Ghiringhelli, Giacomo and Braicovich, Lucio and Zaanen, Jan and Moritz, Brian and Kummer, Kurt and Brookes, Nicholas B. and Zhou, Ke-Jin and Shen, Zhi-Xun and Devereaux, Thomas P. and Lee, Wei-Sheng},
title = {Identification of a characteristic doping for charge order phenomena in Bi-2212 cuprates via RIXS},
year = {2022},
journal = {Physical Review B},
volume = {106},
number = {15},
doi = {10.1103/PhysRevB.106.155109},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85139737189&doi=10.1103%2fPhysRevB.106.155109&partnerID=40&md5=51145c42509545bf40310c330ef3ba4b},
abstract = {Identifying quantum critical points (QCPs) and their associated fluctuations may hold the key to unraveling the unusual electronic phenomena observed in cuprate superconductors. Recently, signatures of quantum fluctuations associated with charge order (CO) have been inferred from the anomalous enhancement of CO excitations that accompany the reduction of the CO order parameter in the superconducting state. To gain more insight into the interplay between CO and superconductivity, here we investigate the doping dependence of this phenomenon throughout the Bi-2212 cuprate phase diagram using resonant inelastic x-ray scattering (RIXS) at the Cu L3 edge. As doping increases, the CO wave vector decreases, saturating near a commensurate value of 0.25 reciprocal lattice unit beyond a characteristic doping pc, where the correlation length becomes shorter than the apparent periodicity (4a0). Such behavior is indicative of the fluctuating nature of the CO; the proliferation of CO excitations in the superconducting state also appears strongest at pc, consistent with expected behavior at a CO QCP. Intriguingly, pc appears to be near optimal doping, where the superconducting transition temperature Tc is maximal. © 2022 American Physical Society.},
type = {Article},
publication_stage = {Final},
source = {Scopus},
note = {All Open Access, Green Open Access}
}
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