Experimental straintronics in nanotube quantum dots

Single-wall carbon nanotubes (SWCNTs) are narrow ribbons of graphene with atomically precise edges and a single quantum transport channel, at experimentally-relevant dopings. This makes them ideal systems to harness quantum transport straintronics (QTS), i.e. using mechanical strain to control accurately quantum transport. We present QTS data from three single-wall carbon nanotube quantum dot (SWCNT-QD) transistors over a broad range of in-situ tunable and reversible uniaxial strain $Δvarepsilon_mechapprox$ 0 to 3 %. We first present the nanofabrication of the suspended SWCNT transistors whose channel lengths are approx 30 nm. The channels are strained by moving gold clamps holding firmly the nanotubes. We present detailed charge transport data, dI/dV_B - V_B - V_G and dI/dV_B - V_B - Δvarepsilon_mech, showing a large mechanical-gating effect of the SWCNT-QDs. The precise reversibility of the data, and their agreement with QTS theory, confirms that the tubes are strained elastically. We demonstrate that the mechanical control of the QD doping is not due to capacitive-gating effects, but to quantitatively predictable bandstructure changes including a strain-tunable bandgap. This precise mechanical control of the doping and bandgap of SWCNT-QDs could find applications in qubits, condensed matter physics, and homojunction molecular transistors.