This dataset contains data supporting the results presented in the paper "The nanometer limits of ballistic and diffusive hot-hole mediated nonlocal molecular manipulation". It includes the data used to plot each figure associated with this publication.We report an experimental investigation into the surface-specific and experimental limits of the range of STM induced nonlocal molecular manipulation. We measure the spot-size of the nonlocal manipulation of bromobenzene molecules on the Si(111)-7×7 surface at room temperature at two voltages and for a wide range of charge-injection times (number of hot charge-carriers) from 1 s up to 500 s. The results conform to a initially ballistic, 6 to 10 nm, and then hot-hole diffusive, 10to 30 nm, transport away from the localised injection site. This work gives further confirmation that nonlocal molecular manipulation by STM directly reveals the ultrafast transport properties of hot-charge carriers at surfaces.

This dataset contains data supporting the results presented in the paper "Common source of light emission and nonlocal molecular manipulation on the Si(111)-7x7 surface". It includes the data used to plot each figure associated with this publication, together with the raw oscilloscope data in .csv format.The study combines the results of the two near identical experimental techniques - nonlocal atomic manipulation and light emission from a scanning tunnelling microscope - for the system of toluene molecules chemisorbed on the Si(111)-7×7 surface at room temperature. The radial dependence of molecular desorption away from the tip injection site conforms to a two-step ballistic-diffusive transport of the injected hot electrons across the surface, with a threshold bias voltage of +2.0 V. We find the same threshold voltage of +2.0 V for light emission from the bare Si(111)-7×7 surface. Comparing these results with previous published spectra we propose that both the manipulation and the light emission follow the same hot electron dynamics, only differing in the outcome of the final relaxation step which may result in either molecular manipulation, or photon emission.