Electron doping enhances s±-wave superconductivity in bulk La3Ni2O7 and its heterostructure with La3Al2O7, yielding highest Tc in the underdoped heterostructure via inter-orbital d_x2-y2 and d_z2 cooperation.
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A d_x2-y2 orbital bilayer t-J model with first-principles parameters unifies experimental Tc controls in La3Ni2O7 via particle-hole asymmetry and J_perp dependence, proposing electron doping to enhance Tc.
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Enhanced $s^\pm$-wave superconductivity in electron-doped La$_3$Ni$_2$O$_7$
Electron doping enhances s±-wave superconductivity in bulk La3Ni2O7 and its heterostructure with La3Al2O7, yielding highest Tc in the underdoped heterostructure via inter-orbital d_x2-y2 and d_z2 cooperation.
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A Unified Understanding of the Experimental Controlling of the T$_\text{c}$ of La$_3$Ni$_2$O$_7$
A d_x2-y2 orbital bilayer t-J model with first-principles parameters unifies experimental Tc controls in La3Ni2O7 via particle-hole asymmetry and J_perp dependence, proposing electron doping to enhance Tc.