722 22 12032 2 35308 document 12032 FigureData.xlsx application/vnd.openxmlformats-officedocument.spreadsheetml.sheet 1b8761dd2710dc4c333c6e7fa7a63604 MD5 14061 2019-10-30 10:14:16 https://researchdata.bath.ac.uk/722/1/FigureData.xlsx 722 1 1 application/vnd.openxmlformats-officedocument.spreadsheetml.sheet other Excel (Office Open XML) spreadsheets containing the data from Figures 2 and 3. Data from Figure 2 is contained in the sheet labelled 'figure 2': Probability of manipulation (with associated error) as function of radius from tip site after an injection of−2.1 V and 900 pA for different charge injection durations. Data from Figure 3 is contained in sheet labelled 'figure 3': Half-desorption radius as function of injection duration for−2.1 V and−1.6 V injections at 900pA. en public cc_by

FigureData.xlsx

data archive 3587 disk0/00/00/07/22 2019-12-05 16:02:45 2024-07-15 10:59:17 2019-12-05 16:02:45 data_collection show Etheridge Henry H.G.Etheridge@bath.ac.uk University of Bath FALSE Rusimova Kristina K.R.Rusimova@bath.ac.uk 0000-0002-3679-9948 University of Bath TRUE Sloan Peter P.Sloan@bath.ac.uk 0000-0002-0810-8468 University of Bath FALSE CA0040 dept_physics 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. 2019-11-29 University of Bath public RightsHolder University of Bath Engineering and Physical Sciences Research Council https://doi.org/10.13039/501100000266 EP/K00137X/1 Breaking the Single Atom Limit in Atomic Manipulation cent_nan cent_photon Full details of the methodology are available in the associated manuscript. en 1 10.15125/BATH-00722 https://doi.org/10.1088/1361-6528/ab5d7c pub