Non‐Local Atomic Manipulation on Semiconductor Surfaces in the <scp>STM</scp>: The Case of Chlorobenzene on <scp>S</scp>i(111)‐7×7

Pan, Tianluo; Sloan, Peter; Palmer, Richard E.

doi:10.1002/tcr.201402021

Cited by 13 publications

(21 citation statements)

References 32 publications

(47 reference statements)

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“…We take τ D =200 fs [36] and so convert the β values of figure 4 to the total probability of manipulation per injected electron N as displayed in figure 5(c). This form of analysis should be identical to the original 'scanning' manipulation work and indeed we find our results here match qualitatively and quantitatively with that earlier work [32,39]. Figure 5(c) shows the voltage dependence of both the probability per electron of molecular displacement and the probability per electron of photon emission.…”

Section: Discussionsupporting

confidence: 85%

“…The main difference is whereas desorption of toluene is an irreversible process, the manipulated silicon adatoms are meta-stable at room temperature and drop back to their original sites before they can be imaged by an STM. We have also reported that the low lying state at ∼+0.5 V is reduced in intensity but still present at the location of the bonding adatom to a chlorobenzene adsorbate [32]. Toluene and chlorobenzene both bond and are manipulated in near identical fashion on the Si(111)-7×7 surface.…”

Section: Discussionmentioning

confidence: 70%

“…We have previously reported on nonlocal manipulation of chlorobenzene and toluene from the Si(111) −7×7 surface [21][22][23]32]. See [33] for a general review of nonlocal manipulation.…”

Section: Stm Induced Nonlocal Atomic Manipulationmentioning

confidence: 99%

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Common source of light emission and nonlocal molecular manipulation on the Si(111)−7 × 7 surface

et al. 2019

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The tip of a scanning tunnelling microscope can inject hot electrons into a surface with atomic precision. Their subsequent dynamics and eventual decay can result in atomic manipulation of an adsorbed molecule, or in light emission from the surface. Here, we combine the results of these two near identical experimental techniques 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 (here, desorption or diffusion) 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 displacement, or photon emission.

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Section: Discussionsupporting

confidence: 85%

Section: Discussionmentioning

confidence: 70%

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Common source of light emission and nonlocal molecular manipulation on the Si(111)−7 × 7 surface

et al. 2019

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“…Both, STM-induced desorption [22] and dissociation [23] of the carbon-chlorine-bond, have been reported in experiments at room temperature. Desorption can be induced by electrons or holes (positive or negative bias voltage) and was found to be largely non-local [8,24]. We characterised physisorbed and chemisorbed chlorobenzene using a cluster approach and density functional theory (DFT) in Ref.…”

Section: Introductionmentioning

confidence: 99%

Local resonances in STM manipulation of chlorobenzene on Si(111)-7×7: performance of different cluster models and density functionals

Utecht

Klamroth

2018

Molecular Physics

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Hot localised charge carriers on the Si(111)-7×7 surface are modelled by small charged clusters. Such resonances induce non-local desorption, i.e. more than 10 nm away from the injection site, of chlorobenzene in scanning tunnelling microscope experiments. We used such a cluster model to characterise resonance localisation and vibrational activation for positive and negative resonances recently. In this work, we investigate to which extent the model depends on details of the used cluster or quantum chemistry methods and try to identify the smallest possible cluster suitable for a description of the neutral surface and the ion resonances. Furthermore, a detailed analysis for different chemisorption orientations is performed. While some properties, as estimates of the resonance energy or absolute values for atomic changes, show such a dependency, the main findings are very robust with respect to changes in the model and/or the chemisorption geometry.

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“…Desorption [15] of chlorobenzene from a Si(111)-7x7 surface can be induced in a one-electron (positive surface bias voltage) or a one-hole process (negative bias voltage) and is to a large extent non-local [13,16]. Also dissociation of the carbon-chlorine-bond has been reported either in a two-electron process [17] or a thermally assisted one-electron process [18].…”

mentioning

confidence: 99%

Quantum chemical approach to atomic manipulation of chlorobenzene on the Si(111)- 7×7 surface: Resonance localization, vibrational activation, and surface dynamics

Utecht

Palmer

Klamroth

2017

Phys. Rev. Materials

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We present a cluster model to describe the localization of hot charge carriers on the Si(111)-7x7 surface, which leads to (non-local) desorption of chlorobenzene molecules in scanning tunneling microscope (STM) manipulation experiments. The localized charge carriers are modeled by a small cluster. By means of quantum chemical calculations, this cluster model explains many experimental findings from STM manipulation. We show that the negative charge is mainly localized in the surface, while the positive one also resides on the molecule. Both resonances boost desorption: in the negative resonance the adatom is elevated, in the positive one the chemisorption bond between the silicon surface adatom and chlorobenzene is broken. We find normal modes promoting desorption matching experimental low temperature activation energies for electron and hole induced desorption.

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Non‐Local Atomic Manipulation on Semiconductor Surfaces in the STM: The Case of Chlorobenzene on Si(111)‐7×7

Cited by 13 publications

References 32 publications

Common source of light emission and nonlocal molecular manipulation on the Si(111)−7 × 7 surface

Common source of light emission and nonlocal molecular manipulation on the Si(111)−7 × 7 surface

Local resonances in STM manipulation of chlorobenzene on Si(111)-7×7: performance of different cluster models and density functionals

Quantum chemical approach to atomic manipulation of chlorobenzene on the Si(111)- 7×7 surface: Resonance localization, vibrational activation, and surface dynamics

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