Ubiquitous suppression of the nodal coherent spectral weight in Bi-based cuprates

M. Zonno; F. Boschini; E. Razzoli; S. K. Y. Dufresne; M. Michiardi; M. X. Na; T. M. Pedersen; S. Gorovikov; S. Gonzalez; G. Di Santo; L. Petaccia; M. Schneider; D. Wong; P. Dosanjh; Y. Yoshida; H. Eisaki; R. D. Zhong; J. A. Schneeloch; G. D. Gu; A. K. Mills; S. Zhdanovich; G. Levy; D.J.Jones; A. Damascelli

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Ubiquitous suppression of the nodal coherent spectral weight in Bi-based cuprates

机译：BI基铜酸盐蛋白的节点相干光谱重量无处不在

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High-temperature superconducting cuprates exhibit an intriguing phenomenology for the low-energy elementary excitations. In particular, an unconventional temperature dependence of the coherent spectral weight (CSW) has been observed in the superconducting phase by angle-resolved photoemission spectroscopy (ARPES), both at the antinode where the d-wave paring gap is maximum, as well as along the gapless nodal direction. Here, we combine equilibrium and time-resolved ARPES to track the temperature-dependent meltdown of the nodal CSW in Bi-based cuprates with unprecedented sensitivity. We find the nodal suppression of CSW upon increasing temperature to be ubiquitous across single- and bi-layer Bi cuprates, and uncurrelated to superconducting and pseudogap onset temperatures. We quantitatively model both the lineshape of the nodal spectral features and the anomalous suppression of CSW within the Fermi-liquid framework, establishing the key role played by the normal state electrodynamics in the description of nodal quasiparticles in superconducting cuprates.

机译：高温超导铜酸盐表现出低能元激发一个有趣的现象。特别地，所述相干光谱重量的一种非常规的温度依赖性（CSW）已经在超导相位角分辨光电子能谱学（ARPES），无论是在波腹，其中d-WAVE配对间隙是最大的，以及沿着观察该无带隙结方向。在这里，我们结合平衡和时间分辨角分辨光电子能谱追踪Bi系铜酸盐具有空前的灵敏度节点CSW的温度相关的崩溃。我们在温度升高找到CSW的节点抑制是跨单层和双层双铜酸盐无处不在，并uncurrelated超导和赝起始温度。我们定量的节点光谱特征的线形和CSW的费米液体框架内的反常压低模型，建立由正常状态电动力学中节点的准粒子的描述超导铜酸盐发挥了关键作用。

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《Physical review.B.Condensed matter and materials physics 》 |2021年第15期| 155109.1-155109.9| 共9页
作者
M. Zonno; F. Boschini; E. Razzoli; S. K. Y. Dufresne; M. Michiardi; M. X. Na; T. M. Pedersen; S. Gorovikov; S. Gonzalez; G. Di Santo; L. Petaccia; M. Schneider; D. Wong; P. Dosanjh; Y. Yoshida; H. Eisaki; R. D. Zhong; J. A. Schneeloch; G. D. Gu; A. K. Mills; S. Zhdanovich; G. Levy; D.J.Jones; A. Damascelli;
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Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1 Centre Energie Materiaux Telecommunications Institut National de la Recherche Scientitique Varennes Quebec J3X 1S2 Canada;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1 Swiss FEL Paul Scherrer Institut 5232 Villigen PSI Switzerland;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1 Max Planck Institute for Chemical Physics of Solids Noethnitzer Strasse 40 Dresden 01187 Germany;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Canadian Light Source Inc.44 Innovation Boulevard Saskatoon Saskatchewan Canada S7N 2V3;

Canadian Light Source Inc.44 Innovation Boulevard Saskatoon Saskatchewan Canada S7N 2V3;

Elettra Sincrotrone Trieste Strada Statale 14 km 163.5 34149 Trieste Italy;

Elettra Sincrotrone Trieste Strada Statale 14 km 163.5 34149 Trieste Italy;

Elettra Sincrotrone Trieste Strada Statale 14 km 163.5 34149 Trieste Italy;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4;

National Institute of Advanced Industrial Science and Technology (AIST) Tsukuba 305-8568 Japan;

National Institute of Advanced Industrial Science and Technology (AIST) Tsukuba 305-8568 Japan;

Condensed Matter Physics and Materials Science Brookhaven National Laboratory Upton New York 11973-5000 USA;

Condensed Matter Physics and Materials Science Brookhaven National Laboratory Upton New York 11973-5000 USA;

Condensed Matter Physics and Materials Science Brookhaven National Laboratory Upton New York 11973-5000 USA;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

Quantum Matter Institute University of British Columbia Vancouver British Columbia Canada V6T 1Z4 Department of Physics & Astronomy University of British Columbia Vancouver British Columbia Canada V6T 1Z1;

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3. On the coherent quasiparticle weight in high-T-c cuprates [J] . Zheng Yong, Zhang Xiaowei, Zhou Wulei, Physics Letters, A . 2017 ,第33期

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4. IODINE INTERCALATION AND DEINTERCALATION OF A Sr-FREE Bi-BASED CUPRATE: Bi_2(La,Na)_2CuO_= [C] . Yoshiaki Tanaka, Makoto Nakanishi, Tatsuo Fujii, Pacific Rim Conference on Ceramic and Glass Technology . 2006

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5. Crystal Growth of Bi-based Cuprate Whiskers and Their Superconducting Properties [D] . Matsubara, Ichiro 1994

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6. Coupling of a high-energy excitation to superconducting quasiparticles in a cuprate from coherent charge fluctuation spectroscopy [O] . Barbara Mansart, José Lorenzana, Andreas Mann, 2013

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7. High-temperature optical spectral weight and Fermi liquid renormalization in Bi-based cuprates [O] . Nicoletti, D., Limaj, O., Calvani, P., 2010

机译：高温光谱重量和费米液 Bi基铜酸盐的重整化

Ubiquitous suppression of the nodal coherent spectral weight in Bi-based cuprates

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