High Temperature Superconductivity Dominated by Inner Underdoped CuO2 Planes in Quadruple-Layer Cuprate (Cu,C)Ba2Ca3Cu4O11+δ

Abstract

The superconducting transition temperature (Tc) of trilayer or quadruple-layer cuprates typically surpasses that of single-layer or bilayer systems. This observation is often interpreted within the ``composite picture", where strong proximity effect between inner CuO2 planes (IPs) and outer CuO2 planes (OPs) is crucial. Albeit intriguing, a straightforward scrutinization of this composite picture is still lacking. In this study, using angle-resolved photoemission spectroscopy to investigate (Cu,C)Ba2Ca3Cu4O11+δ (CuC-1234) with a high Tc of 110~K, we found that the OPs are not superconducting at the Tc of the material. Instead, the large pairing strength and phase coherence concurrently emerge at the underdoped IPs, suggesting that the high Tc is primarily driven by these underdoped IPs. Given that the Tc of CuC-1234 is comparable to other trilayer or quadruple-layer cuprates, our findings suggest that the conventional ``composite picture" is not universally required for achieving high Tc. More importantly, we demonstrate that CuO2 planes free of apical oxygen can support superconductivity up to 110~K even at a doping level of 0.07 holes per Cu, a level that lies deep in the underdoped regime of single- and bilayer cuprates. These findings provide new insights into the origin of high Tc in multilayer cuprates.