Scanning gate microscopy explained

Scanning gate microscopy (SGM) is a scanning probe microscopy technique with an electrically conductive tip used as a movable gate that couples capacitively to the sample and probes electrical transport on the nanometer scale.[1] [2] Typical samples are mesoscopic devices, often based on semiconductor heterostructures, such as quantum point contacts or quantum dots. Carbon nanotubes too have been investigated.

Operating principle

In SGM one measures the sample's electrical conductance as a function of tip position and tip potential. This is in contrast to other microscopy techniques where the tip is used as a sensor, e.g., for forces.

Development

SGMs were developed in the late 1990s from atomic force microscopes. Most importantly, these had to be adapted for use at low temperatures, often 4 kelvins or less, as the samples under study do not work at higher temperatures. Today an estimated number of eleven research groups worldwide use the technique.

Notes and References

  1. Sellier. H. Hackens. B. Pala. M G. Martins. F. Baltazar. S. Wallart. X. Desplanque. L. Bayot. V. Huant. S. On the imaging of electron transport in semiconductor quantum structures by scanning-gate microscopy: successes and limitations. Semiconductor Science and Technology. 26. 6. 2011. 064008. 0268-1242. 10.1088/0268-1242/26/6/064008. 1104.2032. 2011SeScT..26f4008S.
  2. Gorini. Cosimo. Jalabert. Rodolfo A.. Szewc. Wojciech. Tomsovic. Steven. Weinmann. Dietmar. Theory of scanning gate microscopy. Physical Review B. 88. 3. 2013. 1098-0121. 10.1103/PhysRevB.88.035406. 1302.1151. 2013PhRvB..88c5406G.