# High-$T_\textrm{C}$ Superconductivity Originating from Interlayer   Coulomb Coupling in Gate-Charged Twisted Bilayer Graphene Moir$\'{e}$   Superlattices

**Authors:** Dale R. Harshman, Anthony T. Fiory

arXiv: 1908.01208 · 2019-08-06

## TL;DR

This paper proposes a high-$T_c$ superconductivity model in twisted bilayer graphene based on interlayer Coulomb coupling, deriving an expression for optimal transition temperature that aligns well with experimental data.

## Contribution

The study introduces a Coulomb coupling-based model for superconductivity in twisted bilayer graphene, providing a new theoretical framework and an explicit formula for $T_c$ that matches experimental results.

## Key findings

- Derived an explicit formula for $T_{C0}$ based on Coulomb coupling.
- Calculated $T_{C0}$ values consistent with experimental $T_C$.
- Estimated BKT transition temperatures aligning with observations.

## Abstract

Unconventional superconductivity in bilayer graphene has been reported for twist angles $\theta$ near the first magic angle and charged electrostatically with holes near half filling of the lower flat bands. A maximum superconducting transition temperature $T_\textrm{C}$ $\approx$ 1.7 K was reported for a device with $\theta$ = 1.05$\deg$ at ambient pressure and a maximum $T_\textrm{C}$ $\approx$ 3.1 K for a device with $\theta$ = 1.27$\deg$ under 1.33 GPa hydrostatic pressure. A high-$T_\textrm{C}$ model for the superconductivity is proposed herein, where pairing is mediated by Coulomb coupling between charges in the two graphene sheets. The expression derived for the optimal transition temperature, $T_\textrm{C0}$ = $k_\textrm{B}^{-1}$$\Lambda$(|$n_\textrm{opt}$ - $n_\textrm{0}$|/2)$^{1/2}$$e^2$/$\zeta$, is a function of mean bilayer separation distance $\zeta$, measured gated charge areal densities $n_\textrm{opt}$ and $n_\textrm{0}$ corresponding to maximum $T_\textrm{C}$ and superconductivity onset, respectively, and the length constant $\Lambda$ = 0.00747(2) $\mathring{\textrm{A}}$. Based on existing experimental carrier densities and theoretical estimates for $\zeta$, $T_\textrm{C0}$ = 1.94(4) K is calculated for the $\theta$ = 1.05$\deg$ ambient-pressure device and $T_\textrm{C0}$ = 3.02(3) K for the $\theta$ = 1.27$\deg$ pressurized device. Experimental mean-field transition temperatures $T_\textrm{C}^\textrm{mf}$ = 1.83(5) K and $T_\textrm{C}^\textrm{mf}$ = 2.86(5) K are determined by fitting superconducting fluctuation theory to resistance transition data for the ambient-pressure and pressurized devices, respectively; the theoretical results for $T_\textrm{C0}$ are in remarkable agreement with these experimental values. Corresponding Berezinskii-Kosterlitz-Thouless temperatures $T_\textrm{BKT}$ of 0.96(3) K and 2.2(2) K are also determined and interpreted.

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Source: https://tomesphere.com/paper/1908.01208