Metallic carbon nanotube quantum dots with broken symmetries as a platform for tunable terahertz detection

Quantum dots (QD) in metallic single-walled carbon nanotubes (SWNT) have shown great potential to build sensitive terahertz (THz) detection devices usually based on photon-assisted tunneling. A recently reported mechanism based on a combination of resonant QD transitions and asymmetries in the tunneling barriers results in narrow linewidth photocurrent response with a large signal to noise ratio under weak THz radiation. However in such devices, due to metallic SWNTs linear dispersion relation, the detection range is intrinsically limited to allowed energy transitions between equidistant quantized states set by the QD length. Here, we show that simultaneously breaking translational, rotational and mirror symmetries in metallic SWNT QDs leads to a quantized spectrum with non-equidistant energy levels. This result stems from tight-binding and first-principle simulations of a defect-induced metallic zigzag SWNT QD and is validated experimentally by scanning tunneling spectroscopy studies. Importantly, we show that breaking symmetries in metallic SWNT QDs of arbitrary chirality strongly relaxes the selection rules in the electric dipole approximation, leading to a richer set of allowed optical transitions spanning frequencies from as low as 1 THz up to several tens of THz for a $\sim$10 nm QD. Such findings make metallic carbon nanotube QDs with broken symmetries a promising platform to design tunable THz detectors operating above liquid helium temperatures. In this context, we propose a device design based on a metallic SWNT QD engineered with artificially created defects.