An energy gap is, in principle, a dominant parameter in superconductivity. However, this view has been challenged for the case of high- T c cuprates, because anisotropic evolution of a d -wave-like superconducting gap with underdoping has been difficult to formulate along with a critical temperature T c. Here we show that a nodal-gap energy 2ΔN closely follows 8.5 k B T c with underdoping and is also proportional to the product of an antinodal gap energy Δ* and a square-root superfluid density √ P s for Bi2Sr2CaCu2O8+ δ , using low-energy synchrotron-radiation angle-resolved photoemission. The quantitative relations imply that the distinction between the nodal and antinodal gaps stems from the separation of the condensation and formation of electron pairs, and that the nodal-gap suppression represents the substantial phase incoherence inherent in a strong-coupling superconducting state. These simple gap-based formulae reasonably describe a crucial part of the unconventional mechanism governing T c.
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机译:原则上,能隙是超导性的主要参数。但是,对于高T c 铜酸盐,这种观点受到了挑战,因为难以与ad-like波状超导间隙的各向异性演化以及临界温度T c 。在这里,我们显示了节点间隙能量2Δ N 紧随8.5 k B T c 并具有欠掺杂,并且还与a的乘积成正比。 Bi 2 Sr 2 CaCu <的反节点间隙能Δ * 和平方根超流体密度√P s sub> 2 O 8+δ,使用低能同步辐射辐射角分辨的光发射。定量关系暗示,节点间隙和反节点间隙之间的区别源于缩合的分离和电子对的形成,并且节点间隙的抑制代表了强耦合超导状态中固有的基本相干。这些简单的基于间隙的公式合理地描述了控制T c 的非常规机制的关键部分。
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