Tunable mid-infrared photodetector with graphene plasmon controlled by type-printable ferroelectric superdomain

Graphene plasmons can resonantly enhance the incident light absorption and offer a potential for tunable spectral selectivity for mid-infrared (MIR) detection. High-performance tunable MIR plasmonic devices are, however, typically based on electrode-patterned graphene, which requires high power input and are technologically challenging in compact assembly. Here we demonstrate a tunable MIR photodetector based on integration of graphene on periodically "type-printed" ferroelectric superdomain. The plasmon resonance of graphene is tuned by the artificially nanoscale patterned ferroelectric domains and enables a selective transmission in MIR region. Our devices operate at zero-bias source-drain voltage and exhibit a peak photoresponsivity of up to near 30 mA W-1 at 8.5 um at room temperature. We also observe a tunable photodetection performance ranging from 7.2 to 8.5 um by directly re-scaling the geometry of ferroelectric superdomain. The non-volatile tunability of graphene plasmons and bias-free devices provide a great potential for smart fabrication of on-chip MIR photodetector array with tunable spectrum and low-energy consumption.