A strange metal is a type of material that exhibits unusual electrical properties, challenging our conventional understanding of how metals conduct electricity.

In these metals, electrons lose their individual identities, acting collectively in a soup, in which all particles are connected through quantum entanglement. 

Prof. Chung, National Yang Ming Chiao Tung University

Many so-called high temperature superconductors, such as doped cuprates, transition from their superconducting state to a strange metal state as they increase in temperature beyond a critical point. (Note that ‘high’ in this context means above −196.2 °C, the boiling point of liquid nitrogen!)

It has long been thought that revealing the mystery of the strange metal state is the key to understanding the mechanism for high-temperature conductivity. This could lead to understanding what would be required to make a truly room temperature superconductor.

In this new paper, the researchers used a cutting-edge theoretical framework to provide a microscopic description of the strange metal state, focusing on how local charge fluctuations near a critical transition, play a key role.

Their theoretical predictions for quantities such as the specific heat coefficient and the single-particle spectral function in the strange metal state agree well with experimental observations.

This work therefore brings us much closer to understanding how superconductivity emerges from the strange metal state in the cuprates – an open problem in condensed matter physics since the 1990s.

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