Atomic-Scale Charge Distribution Mapping of Single Substitutional p- and n-Type Dopants in Graphene

Mallada, Benjamín; Edalatmanesh, Shayan; Lazar, Petr; Redondo, Jesús; Gallardo, Aurelio; Zbořil, Radek; Jelı́nek, Pavel; Švec, Martin

doi:10.1021/acssuschemeng.9b07623

“…Specifically, we observe a substantial variation of the local contact potential difference (LCPD), which shifts toward lower values with respect to the reference LCPD recorded on the bare Au(111) surface (Figure 4 b). This LCPD shift concurs very well with the positive net charge of 2 [44–48] . Moreover, simulated KPFM images of fully relaxed 2 on the Au(111) match very well the experimental KPFM images acquired in a close tip‐sample distance revealing submolecular resolution (see Figure S6 and methods section for further details) [48, 49] …”

Section: Resultssupporting

confidence: 78%

On‐Surface Synthesis of a Dicationic Diazahexabenzocoronene Derivative on the Au(111) Surface

Biswas

¹

,

Urgel

²

,

Xu

³

et al. 2021

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The atomically precise control over the size,s hape and structure of nanographenes (NGs) or the introduction of heteroatom dopants into their sp 2 -carbon lattice confer them valuable electronic, optical and magnetic properties.H erein, we report on the design and synthesis of ahexabenzocoronene derivative embedded with graphitic nitrogen in its honeycomb lattice,a chieved via on-surface assisted cyclodehydrogenation on the Au(111) surface.C ombined scanning tunnelling microscopy/spectroscopya nd non-contact atomic force microscopyi nvestigations unveil the chemical and electronic structures of the obtained dicationic NG.K elvin probe force microscopym easurements reveal ac onsiderable variation of the local contact potential difference toward lower values with respect to the gold surface,indicative of its positive net charge. Altogether,w ei ntroduce the concept of cationic nitrogen doping of NGs on surfaces,opening new avenues for the design of novel carbon nanostructures.

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“…This LCPD shift concurs very well with the positive net charge of 2. [44][45][46][47][48] Moreover,s imulated KPFM images of fully relaxed 2 on the Au(111) match very well the experimental KPFM images acquired in ac lose tip-sample distance revealing submolecular resolution (see Figure S6 and methods section for further details). [48,49]…”

Section: Methodssupporting

confidence: 71%

On‐Surface Synthesis of a Dicationic Diazahexabenzocoronene Derivative on the Au(111) Surface

Biswas

¹

,

Urgel

²

,

Xu

³

et al. 2021

Self Cite

View full text Add to dashboard Cite

The atomically precise control over the size,s hape and structure of nanographenes (NGs) or the introduction of heteroatom dopants into their sp 2 -carbon lattice confer them valuable electronic, optical and magnetic properties.H erein, we report on the design and synthesis of ahexabenzocoronene derivative embedded with graphitic nitrogen in its honeycomb lattice,a chieved via on-surface assisted cyclodehydrogenation on the Au(111) surface.C ombined scanning tunnelling microscopy/spectroscopya nd non-contact atomic force microscopyi nvestigations unveil the chemical and electronic structures of the obtained dicationic NG.K elvin probe force microscopym easurements reveal ac onsiderable variation of the local contact potential difference toward lower values with respect to the gold surface,indicative of its positive net charge. Altogether,w ei ntroduce the concept of cationic nitrogen doping of NGs on surfaces,opening new avenues for the design of novel carbon nanostructures.

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“…In a KPFM measurement, the local contact potential difference (LCPD) between the surface of a material and the conductive tip of an atomic force microscope (AFM) is spatially mapped across the sample . For graphene, KPFM measurements have been used to characterize several phenomena: the dependence of work function on carrier density, Moirè pattern potentials, quantum Hall edge states, screening clouds near defects, potential drops across biased samples, , and near electrical contacts . One complication of KPFM measurements is that the tip can have both a sharp (∼10 nm) apex and a large (∼1–10 μm) body which can measure different short- and long-range, respectively, CPD values .…”

Section: Introductionmentioning

confidence: 99%

Measuring and Tuning the Potential Landscape of Electrostatically Defined Quantum Dots in Graphene

Behn

¹

,

Krebs

²

,

Smith

³

et al. 2021

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We use Kelvin probe force microscopy (KPFM) to probe the carrier-dependent potential of an electrostatically defined quantum dot (QD) in a graphene/hexagonal boron nitride (hBN) heterostructure. We show that gate-dependent measurements enable a calibration scheme that corrects for uncertainty inherent in typical KPFM measurements and accurately reconstructs the potential well profile. Our measurements reveal how the well changes with carrier concentration, which we associate with the nonlinear dependence of graphene's work function on carrier density. These changes shift the energy levels of quasi-bound states in the QD which we can measure via scanning tunneling spectroscopy (STS). We show that the experimentally extracted energy levels closely compare with wave functions calculated from the reconstructed KPFM data. This methodology, where KPFM and STS data are simultaneously acquired from 2D materials, allows the quasiparticle response to an electrostatic potential to be determined in a self-consistent way.

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Atomic-Scale Charge Distribution Mapping of Single Substitutional p- and n-Type Dopants in Graphene

Cited by 18 publications

References 61 publications

On‐Surface Synthesis of a Dicationic Diazahexabenzocoronene Derivative on the Au(111) Surface

On‐Surface Synthesis of a Dicationic Diazahexabenzocoronene Derivative on the Au(111) Surface

On‐Surface Synthesis of a Dicationic Diazahexabenzocoronene Derivative on the Au(111) Surface

Measuring and Tuning the Potential Landscape of Electrostatically Defined Quantum Dots in Graphene

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