We use ultra-resolving terahertz (THz) near-field microscopy based on THz scattering at atomic force microscope tips to analyze 65-nm technology node transistors. Nanoscale resolution is achieved by THz field confinement at the very tip apex to within 30 nm. Images of semiconductor transistors provide evidence of 40 nm (λ/3000) spatial resolution at 2.54 THz (wavelength λ = 118µm) and demonstrate the simultaneous THz recognition of materials and mobile carriers in a single nanodevice. The mobile carrier contrast can be clearly related to near-field excitation of THz-plasmons in the semiconductor regions. The extraordinary high sensitivity of our microscope provides THz near-field contrasts from less then 100 mobile electrons in the probed volume.

The usefulness of scattering-type near-field optical microscopy for mapping the material and doping in microelectronic devices at nanoscale resolution is demonstrated. Both amplitude and phase of infrared (λ = 10.7 μm) laser light scattered by a metallised, vibrating AFM tip scanned a few nanometers above the sample are detected and transformed into images showing contrast of materials, as well as of doping concentration. Cross-sections through layers as thin as 20 nm have been clearly imaged.