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1. Twisted nanoporous graphene/graphene bilayers: electronic decoupling and chiral currents

Author

de Cerio, Xabier Diaz, Lorentzen, Aleksander Bach, Brandbyge, Mads, and Garcia-Lekue, Aran

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We investigate bilayers of nanoporous graphene (NPG), laterally bonded carbon nanoribbons, and graphene. The electronic and transport properties are explored as a function of the interlayer twist angle using an atomistic tight-binding model combined with non-equilibrium Green's functions. At small twist angles ($\theta \lesssim 10^\circ$), NPG and graphene are strongly coupled, as revealed by the hybridization of their electronic bands. As a result, when electrons are point-injected in NPG, a substantial interlayer transmission occurs and an electronic Talbot-like interference pattern appears in the current flow on both layers. Besides, the twist-induced mirror-symmetry-breaking leads to chiral features in the injected current. Upon increasing the twist angle, the coupling is weakened and the monolayer electronic properties are restored. Furthermore, we demonstrate the emergence of resonant peaks in the electronic density of states for small twist angles, allowing to probe the twist-dependent interlayer coupling via scanning tunneling microscopy., Comment: 6+7 pages, 4+6 figures

Published
2024

4. Tunable spin and transport in porphyrin-graphene nanoribbon hybrids

Author

Gao, Fei, Menchón, Rodrigo E., Garcia-Lekue, Aran, and Brandbyge, Mads

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Computational Physics
Abstract

Recently, porphyrin units have been attached to graphene nanoribbons (Por-GNR) enabling a multitude of possible structures. Here we report first principles calculations of two prototypical, experimentally feasible, Por-GNR hybrids, one of which displays a small band gap relevant for its use as electrode in a device. Embedding a Fe atom in the porphyrin causes spin polarization with a spin ground state $S=1$. We employ density functional theory and nonequilibrium Green's function transport calculations to examine a 2-terminal setup involving one Fe-Por-GNR between two metal-free, small band gap, Por-GNR electrodes. The coupling between the Fe-$d$ and GNR band states results in a Fano anti-resonance feature in the spin transport close to the Fermi energy. This feature makes transport highly sensitive to the Fe spin state. We demonstrate how mechanical strain or chemical adsorption on the Fe give rise to a spin-crossover to $S=1$ and $S=0$, respectively, directly reflected in a change in transport. Our theoretical results provide a clue for the on-surface synthesis of Por-GNRs hybrids, which can open a new avenue for carbon-based spintronics and chemical sensing.

Published
2022

5. Addressing electron spins embedded in metallic graphene nanoribbons

Author

Friedrich, Niklas, Menchon, Rodrigo E., Pozo, Iago, Hieulle, Jeremy, Vegliante, Alessio, Li, Jingcheng, Sanchez-Portal, Daniel, Pena, Diego, Garcia-Lekue, Aran, and Pascual, Jose Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Spin-hosting graphene nanostructures are promising metal-free systems for elementary quantum spintronic devices. Conventionally, spins are protected from quenching by electronic bandgaps, which also hinder electronic access to their quantum state. Here, we present a narrow graphene nanoribbon substitutionally doped with boron heteroatoms that combines a metallic character with the presence of localized spin 1/2 states in its interior. The ribbon was fabricated by on-surface synthesis on a Au(111) substrate. Transport measurements through ribbons suspended between the tip and the sample of a scanning tunnelling microscope revealed their ballistic behavior, characteristic of metallic nanowires. Conductance spectra show fingerprints of localized spin states in form of Kondo resonances and inelastic tunnelling excitations. Density functional theory rationalizes the metallic character of the graphene nanoribbon due to the partial depopulation of the valence band induced by the boron atoms. The transferred charge builds localized magnetic moments around the boron atoms. The orthogonal symmetry of the spin-hosting state's and the valence band's wavefunctions protects them from mixing, maintaining the spin states localized. The combination of ballistic transport and spin localization into a single graphene nanoribbon offers the perspective of electronically addressing and controlling carbon spins in real device architectures., Comment: 9 pages in the main manuscript, including 4 figures, 13 pages in the supporting info, including 13 figures

Published
2022
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6. Band structure and energy level alignment of chiral graphene nanoribbons on silver surfaces

Author

Corso, Martina, Menchón, Rodrigo E., Piquero-Zulaica, Ignacio, Vilas-Varela, Manuel, Ortega, J. Enrique, Peña, Diego, Garcia-Lekue, Aran, and de Oteyza, Dimas G.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Chiral graphene nanoribbons are extremely interesting structures due to their low bandgaps and potential development of spin-polarized edge states. Here, we study their band structure on low work function silver surfaces and assess the effect of charge transfer on their properties.

Published
2021
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7. Topological phase transition in chiral graphene nanoribbons: from edge bands to end states

Author

Li, Jingcheng, Sanz, Sofia, Merino-Díez, Nestor, Vilas-Varela, Manuel, Garcia-Lekue, Aran, Corso, Martina, de Oteyza, Dimas G., Frederiksen, Thomas, Peña, Diego, and Pascual, Jose Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Precise control over the size and shape of graphene nanostructures allows engineering spin-polarized edge and topological states, representing a novel source of non-conventional $\pi$-magnetism with promising applications in quantum spintronics. A prerequisite for their emergence is the existence of robust gapped phases, which are difficult to find in extended graphene systems: only armchair graphene nanoribbons (GNRs) show a band gap that, however, closes for any other GNR orientation. Here we show that semi-metallic chiral GNRs (chGNRs) narrowed down to nanometer widths undergoes a topological phase transition, becoming first topological insulators, and transforming then into trivial band insulators for the narrowest chGNRs. We fabricated atomically precise chGNRs of different chirality and size by on surface synthesis using predesigned molecular precursors. Combining scanning tunnelling microscopy (STM) measurements and theory simulations, we follow the evolution of topological properties and bulk band gap depending on the width, length, and chirality of chGNRs. The first emerging gapped phases are topological, protected by a chiral interaction pattern between edges. For narrower ribbons, the symmetry of the interaction pattern changes, and the topological gap closes and re-opens again as a trivial band insulator. Our findings represent a new platform for producing topologically protected spin states and demonstrates the potential of connecting chiral edge and defect structure with band engineering., Comment: 12 pages, 5 figures

Published
2021
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8. Substrate-Independent Growth of Atomically Precise Chiral Graphene Nanoribbons

Author

de Oteyza, Dimas G., Garcia-Lekue, Aran, Vilas-Varela, Manuel, Merino, Nestor, Carbonell-Sanromà, Eduard, Corso, Martina, Vasseur, Guillaume, Rogero, Celia, Guitian, Enrique, Pascua, Jose Ignacio, Ortega, J. Enrique, Wakayama, Yutaka, and Peña, Diego

Subjects
Condensed Matter - Materials Science
Abstract

Contributing to the need of new graphene nanoribbon (GNR) structures that can be synthesized with atomic precision, we have designed a reactant that renders chiral (3,1) - GNRs after a multi-step reaction including Ullmann coupling and cyclodehydrogenation. The nanoribbon synthesis has been successfully proved on different coinage metals, and the formation process, together with the fingerprints associated to each reaction step, has been studied combining scanning tunnelling microscopy, core-level spectroscopy and density functional calculations. In addition to the GNR chiral edge structure, the substantial GNR lengths achieved and the low processing temperature required to complete the reaction grant this reactant extremely interesting properties for potential applications.

Published
2020
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9. Band Depopulation of Graphene Nanoribbons Induced by Chemical Gating with Amino Groups

Author

Li, Jingcheng, Brandimarte, Pedro, Vilas-Varela, Manuel, Merino-Díez, Nestor, Moreno, César, Mugarza, Aitor, Mollejo, Jaime Sáez, Portal, Daniel Sánchez, de Oteyza, Dimas G., Corso, Martina, Garcia-Lekue, Aran, Peña, Diego, and Pascual, Jose Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The electronic properties of graphene nanoribbons (GNRs) can be precisely tuned by chemical doping. Here we demonstrate that amino (NH$_2$) functional groups attached at the edges of chiral GNRs (chGNRs) can efficiently gate the chGNRs and lead to the valence band (VB) depopulation on a metallic surface. The NH$_2$-doped chGNRs are grown by on-surface synthesis on Au(111) using functionalized bianthracene precursors. Scanning tunneling spectroscopy resolves that the NH$_2$ groups significantly up-shift the bands of chGNRs, causing the Fermi level crossing of the VB onset of chGNRs. Through density functional theory simulations we confirm that the hole-doping behavior is due to an upward shift of the bands induced by the edge NH$_2$ groups., Comment: 7 pages with 5 figures and 4 page supplementary information. This document is the unedited Author's version of a Submitted Work that was subsequently accepted for publication in ACS Nano, copyright American Chemical Society after peer review

Published
2020
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10. Magnetism of topological boundary states induced by boron substitution in graphene nanoribbons

Author

Friedrich, Niklas, Brandimarte, Pedro, Li, Jingcheng, Saito, Shohei, Yamaguchi, Shigehiro, Pozo, Iago, Peña, Diego, Frederiksen, Thomas, Garcia-Lekue, Aran, Sánchez-Portal, Daniel, and Pascual, José Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Graphene nanoribbons (GNRs), low-dimensional platforms for carbon-based electronics, show the promising perspective to also incorporate spin polarization in their conjugated electron system. However, magnetism in GNRs is generally associated to localized states around zigzag edges, difficult to fabricate and with high reactivity. Here we demonstrate that magnetism can also be induced away from physical GNR zigzag edges through atomically precise engineering topological defects in its interior. A pair of substitutional boron atoms inserted in the carbon backbone breaks the conjugation of their topological bands and builds two spin-polarized boundary states around. The spin state was detected in electrical transport measurements through boron-substituted GNRs suspended between tip and sample of a scanning tunneling microscope. First-principle simulations find that boron pairs induce a spin 1, which is modified by tuning the spacing between pairs. Our results demonstrate a route to embed spin chains in GNRs, turning them basic elements of spintronic devices., Comment: 6 pages in main manuscript plus 9 pages Supplementary Material, 5 figures

Published
2020
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11. Electronic structure tunability by periodic meta-ligand spacing in one-dimensional organic semiconductors

Author

Piquero-Zulaica, Ignacio, Garcia-Lekue, Aran, Colazzo, Luciano, Krug, Claudio K., Mohammed, Mohammed S. G., El-Fattah, Zakaria M. Abd, Gottfried, J. Michael, de Oteyza, Dimas G., Ortega, J. Enrique, and Lobo-Checa, Jorge

Subjects
Condensed Matter - Materials Science
Abstract

Designing molecular organic semiconductors with distinct frontier orbitals is key for the development of devices with desirable properties. Generating defined organic nanostructures with atomic precision can be accomplished by on-surface synthesis. We use this dry chemistry to introduce topological variations in a conjugated poly-para-phenylene chain in the form of meta-junctions. As evidenced by STM and LEED, we produce a macroscopically ordered, monolayer thin zigzag chain film on a vicinal silver crystal. These cross-conjugated nanostructures are expected to display altered electronic properties, which are now unravelled by highly complementary experimental techniques (ARPES and STS) and theoretical calculations (DFT and EPWE). We find that meta-junctions dominate the weakly dispersive band structure, while the bandgap is tunable by altering the linear segment's length. These periodic topology effects induce significant loss of the electronic coupling between neighboring linear segments leading to partial electron confinement in the form of weakly coupled Quantum Dots. Such periodic quantum interference effects determine the overall semiconducting character and functionality of the chains.

Published
2020
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13. Conductance channels of a platform molecule on Au(111) probed with shot noise

Author

Mohr, Michael, Jasper-Toennies, Torben, Frederiksen, Thomas, Garcia-Lekue, Aran, Ulrich, Sandra, Herges, Rainer, and Berndt, Richard

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The shot noise of the current $I$ through junctions to single trioxatriangulenium cations (TOTA$^+$) on Au(111) is measured with a low temperature scanning tunneling microscope using Au tips. The noise is significantly reduced compared to the Poisson noise power of $2eI$ and varies linearly with the junction conductance. The data are consistent with electron transmission through a single spin-degenerate transport channel and show that TOTA$^+$ in a Au contact does not acquire an unpaired electron. Ab initio calculations reproduce the observations and show that the current involves the lowest unoccupied orbital of the molecule and tip states close to the Fermi level., Comment: 5 pages, 5 figures

Published
2019
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14. Full-scale Simulation of Electron Transport in Nanoporous Graphene: Probing the Talbot Effect

Author

Calogero, Gaetano, Papior, Nick R., Kretz, Bernhard, Garcia-Lekue, Aran, Frederiksen, Thomas, and Brandbyge, Mads

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Chemical Physics, Physics - Computational Physics, Physics - Optics
Abstract

Designing platforms to control phase-coherence and interference of electron waves is a cornerstone for future quantum electronics, computing or sensing. Nanoporous graphene (NPG) consisting of linked graphene nanoribbons has recently been fabricated using molecular precursors and bottom-up assembly [Moreno et al., Science 360, 199 (2018)] opening an avenue for controlling the electronic current in a two-dimensional material. By simulating electron transport in real-sized NPG samples we predict that electron waves injected from the tip of a scanning tunneling microscope (STM) behave similarly to photons in coupled waveguides, displaying a Talbot interference pattern. We link the origins of this effect to the band structure of the NPG and further demonstrate how this pattern may be mapped out by a second STM probe. We enable atomistic parameter-free calculations beyond the 100 nm scale by developing a new multi-scale method where first-principles density functional theory regions are seamlessly embedded into a large-scale tight-binding., Comment: 11 pages, 10 figures, Supporting Information included

Published
2018
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15. Electronic Properties of Substitutionally Boron-doped Graphene Nanoribbons on a Au(111) Surface

Author

Carbonell-Sanromà, Eduard, Garcia-Lekue, Aran, Corso, Martina, Vasseur, Guillaume, Brandimarte, Pedro, Lobo-Checa, Jorge, de Oteyza, Dimas G., Li, Jingcheng, Kawai, Shigeki, Saito, Shohei, Yamaguchi, Shigehiro, Ortega, J. Enrique, Sánchez-Portal, Daniel, and Pascual, Jose Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

High quality graphene nanoribbons (GNRs) grown by on-surface synthesis strategies with atomic precision can be controllably doped by inserting heteroatoms or chemical groups in the molecular precursors. Here, we study the electronic structure of armchair GNRs substitutionally doped with di-boron moieties at the center, through a combination of scanning tunneling spectroscopy, angle-resolved photoemission, and density functional theory simulations. Boron atoms appear with a small displacement towards the surface signaling their stronger interaction with the metal. We find two boron-rich flat bands emerging as impurity states inside the GNR band gap, one of them particularly broadened after its hybridization with the gold surface states. In addition, the boron atoms shift the conduction and valence bands of the pristine GNR away from the gap edge, and leave unaffected the bands above and below, which become the new frontier bands and have negligible boron character. This is due to the selective mixing of boron states with GNR bands according to their symmetry. Our results depict that the GNRs band structure can be tuned by modifying the separation between di-boron moieties., Comment: 12 pages, 5 Figures

Published
2018
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16. Switching From Reactant to Substrate Engineering in the Selective Synthesis of Graphene Nanoribbons

Author

Merino-Díez, Néstor, Lobo-Checa, Jorge, Nita, Pawel, Garcia-Lekue, Aran, Basagni, Andrea, Vasseur, Guillaume, Tiso, Federica, Sedona, Francesco, Das, Pranab K., Fujii, Jun, Vobornik, Ivana, Sambi, Mauro, Pascual, José Ignacio, Ortega, J. Enrique, and de Oteyza, Dimas G.

Subjects
Condensed Matter - Materials Science
Abstract

The challenge of synthesizing graphene nanoribbons (GNRs) with atomic precision is currently being pursued along a one-way road, based on the synthesis of adequate molecular precursors that react in predefined ways through self-assembly processes. The synthetic options for GNR generation would multiply by adding a new direction to this readily successful approach, especially if both of them can be combined. We show here how GNR synthesis can be guided by an adequately nanotemplated substrate instead of by the traditionally designed reactants. The structural atomic precision, unachievable to date through top-down methods, is preserved by the self-assembly process. This new strategy s proof-of-concept compares experiments using 4,4 -dibromo-para-terphenyl as molecular precursor on flat Au(111) and stepped Au(322) substrates. As opposed to the former, the periodic steps of the latter drive the selective synthesis of 6 atom-wide armchair GNRs, whose electronic properties have been further characterized in detail by scanning tunneling spectroscopy, angle resolved photoemission and density functional theory calculations.

Published
2018
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17. Bottom up synthesis of multifunctional nanoporous graphene

Author

Moreno, César, Vilas-Varela, Manuel, Kretz, Bernhard, Garcia-Lekue, Aran, Costache, Marius V., Paradinas, Marcos, Panighel, Mirco, Ceballos, Gustavo, Valenzuela, Sergio O., Peña, Diego, and Mugarza, Aitor

Subjects
Condensed Matter - Materials Science
Abstract

Nanosize pores can turn semimetallic graphene into a semiconductor and from being impermeable into the most efficient molecular sieve membrane. However, scaling the pores down to the nanometer, while fulfilling the tight structural constraints imposed by applications, represents an enormous challenge for present top-down strategies. Here we report a bottom-up method to synthesize nanoporous graphene comprising an ordered array of pores separated by ribbons, which can be tuned down to the one nanometer range. The size, density, morphology and chemical composition of the pores are defined with atomic precision by the design of the molecular precursors. Our measurements further reveal a highly anisotropic electronic structure, where orthogonal one-dimensional electronic bands with an energy gap of ~1 eV coexist with confined pore states, making the nanoporous graphene a highly versatile semiconductor for simultaneous sieving and electrical sensing of molecular species.

Published
2018
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18. Tailoring magnetism in silicon-doped zigzag graphene edges

Author

Andoni Ugartemendia, Aran Garcia−Lekue, and Elisa Jimenez−Izal

Subjects
Medicine, Science
Abstract

Abstract Recently, the edges of single-layer graphene have been experimentally doped with silicon atoms by means of scanning transmission electron microscopy. In this work, density functional theory is applied to model and characterize a wide range of experimentally inspired silicon doped zigzag-type graphene edges. The thermodynamic stability is assessed and the electronic and magnetic properties of the most relevant edge configurations are unveiled. Importantly, we show that silicon doping of graphene edges can induce a reversion of the spin orientation on the adjacent carbon atoms, leading to novel magnetic properties with possible applications in the field of spintronics.

Published
2022
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20. Width-Dependent Band Gap in Armchair Graphene Nanoribbons Reveals Fermi Level Pinning on Au(111)

Author

Merino-Díez, Néstor, Garcia-Lekue, Aran, Carbonell-Sanromà, Eduard, Li, Jingcheng, Corso, Martina, Colazzo, Luciano, Sedona, Francesco, Sánchez-Portal, Daniel, Pascual, Jose I., and de Oteyza, Dimas G.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on the energy level alignment evolution of valence and conduction bands of armchair-oriented graphene nanoribbons (aGNR) as their band gap shrinks with increasing width. We use 4,4-dibromo-para-terphenyl as molecular precursor on Au(111) to form extended poly-para-phenylene nanowires, which can be fused sideways to form atomically precise aGNRs of varying widths. We measure the frontier bands by means of scanning tunneling spectroscopy, corroborating that the nanoribbons band gap is inversely proportional to their width. Interestingly, valence bands are found to show Fermi level pinning as the band gap decreases below a threshold value around 1.7 eV. Such behavior is of critical importance to understand the properties of potential contacts in graphene nanoribbon-based devices. Our measurements further reveal a particularly interesting system for studying Fermi level pinning by modifying an adsorbates band gap while maintaining an almost unchanged interface chemistry defined by substrate and adsorbate.

Published
2017
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21. On-surface route for producing planar nanographenes with azulene moieties

Author

Hieulle, Jeremy, Carbonel-Sanromà, Eduard, Vilas-Varela, Manuel, Garcia-Lekue, Aran, Guitián, Enrique, Peña, Diego, and Pascual, Jose Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Large aromatic carbon nanostructures are cornerstone materials due to their increasingly active role in functional devices, but their synthesis in solution encounters size and shape limitations. New on-surface strategies facilitate the synthesis of large and insoluble planar systems with atomic-scale precision. While dehydrogenation is usually the chemical zipping reaction building up large aromatic carbon structures, mostly benzenoid structures are being produced. Here, we report on a new cyclodehydrogenation reaction transforming a sterically stressed precursor with conjoined cove regions into planar carbon platform by incorporating azulene moieties in their interior. Submolecular resolution STM is used to characterize this exotic large polycyclic aromatic compound on Au(111) yielding unprecedented insight into a dehydrogenative intramolecular aryl-aryl coupling reaction. The resulting polycyclic aromatic carbon structure shows a [18]annulene core hosting peculiar pore states confined at the carbon cavity., Comment: Accepted for publication in Nanoletters

Published
2017
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22. Submolecular resolution by variation of IETS amplitude and its relation to AFM/STM signal

Author

de la Torre, Bruno, Švec, Martin, Foti, Giuseppe, Krejčí, Ondřej, Hapala, Prokop, Garcia-Lekue, Aran, Frederiksen, Thomas, Zbořil, Radek, Arnau, Andrés, Vázquez, Héctor, and Jelínek, Pavel

Subjects
Condensed Matter - Materials Science
Abstract

Here we show scanning tunnelling microscopy (STM), non-contact atomic force microscopy (AFM) and inelastic electron tunnelling spectroscopy (IETS) measurements on organic molecule with a CO- terminated tip at 5K. The high-resolution contrast observed simultaneously in all channels unam- biguously demonstrates the common imaging mechanism in STM/AFM/IETS, related to the lateral bending of the CO-functionalized tip. The IETS spectroscopy reveals that the submolecular con- trast at 5K consists of both renormalization of vibrational frequency and variation of the amplitude of IETS signal. This finding is also corroborated by first principles simulations. We extend accord- ingly the probe-particle AFM/STM/IETS model to include these two main ingredients necessary to reproduce the high-resolution IETS contrast. We also employ the first principles simulations to get more insight into different response of frustrated translation and rotational modes of CO-tip during imaging.

Published
2017
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23. Unraveling the electronic structure of narrow atomically-precise chiral graphene nanoribbons

Author

Merino-Díez, Néstor, Li, Jingcheng, Garcia-Lekue, Aran, Vasseur, Guillaume, Vilas-Varela, Manuel, Carbonell-Sanromà, Eduard, Corso, Martina, Ortega, J. Enrique, Peña, Diego, Pascual, Jose I., and de Oteyza, Dimas G.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Recent advances in graphene nanoribbon-based research have demonstrated the controlled synthesis of chiral graphene nanoribbons (cGNR) with atomic precision using strategies of on-surface chemistry. However their electronic characterization, including typical figures of merit like band gap or frontier bands effective masses, has not yet been reported. In this work, we provide a detailed characterization of (3,1)-cGNRs on Au(111). The structure and epitaxy, as well as the electronic band structure of the ribbons, are analyzed by means of scanning tunneling microscopy and spectroscopy, angle resolved photoemission and density functional theory.

Published
2017
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24. Orbital-selective spin excitation of a magnetic porphyrin

Author

Rubio-Verdú, Carmen, Sarasola, Ane, Choi, Deung-Jang, Majzik, Zsolt, Ebeling, René, Calvo, M. Reyes, Ugeda, Miguel M., Garcia-Lekue, Aran, Sánchez-Portal, Daniel, and Pascual, José Ignacio

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Scattering of electrons by localized spins is the ultimate process enabling electrical detection and control of the magnetic state of a spin-doped material. At the molecular scale, this scattering is mediated by the electronic orbitals hosting the spin. Here we report the selective excitation of a molecular spin by electrons tunneling through different molecular orbitals. Spatially-resolved tunneling spectra on iron porphyrins on Au(111) reveal that the inelastic spin excitation extends beyond the iron site. The inelastic features also change shape and symmetry along the molecule. Combining DFT simulations with a phenomenological scattering model, we show that the extension and lineshape variations of the inelastic signal are due to excitation pathways assisted by different frontier orbitals, each of them with a different degree of hybridization with the surface. By selecting the intramolecular site for electron injection, the relative weight of iron and pyrrole orbitals in the tunneling process is modified. In this way, the spin excitation mechanism, reflected by its spectral lineshape, changes depending on the degree of localization and energy alignment of the chosen molecular orbital., Comment: 13 pages, 5 figures, Supplemental Material

Published
2017
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25. A tunable electronic beam splitter realized with crossed graphene nanoribbons

Author

Brandimarte, Pedro, Engelund, Mads, Papior, Nick, Garcia-Lekue, Aran, Frederiksen, Thomas, and Sánchez-Portal, Daniel

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Graphene nanoribbons (GNRs) are promising components in future nanoelectronics due to the large mobility of graphene electrons and their tunable electronic band gap in combination with recent experimental developments of on-surface chemistry strategies for their growth. Here we explore a prototype 4-terminal semiconducting device formed by two crossed armchair GNRs (AGNRs) using state-of-the-art first-principles transport methods. We analyze in detail the roles of intersection angle, stacking order, inter-GNR separation, and finite voltages on the transport characteristics. Interestingly, when the AGNRs intersect at $\theta= 60^\circ$, electrons injected from one terminal can be split into two outgoing waves with a tunable ratio around 50% and with almost negligible back-reflection. The splitted electron wave is found to propagate partly straight across the intersection region in one ribbon and partly in one direction of the other ribbon, i.e., in analogy of an optical beam splitter. Our simulations further identify realistic conditions for which this semiconducting device can act as a mechanically controllable electronic beam splitter with possible applications in carbon-based quantum electronic circuits and electron optics. We rationalize our findings with a simple model that suggests that electronic beam splitters can generally be realized with crossed GNRs.

Published
2016
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26. Search for a Metallic Dangling-Bond Wire on $n$-doped H-passivated Semiconductor Surfaces

Author

Engelund, Mads, Papior, Nick, Brandimarte, Pedro, Frederiksen, Thomas, Garcia-Lekue, Aran, and Sanchez-Portal, Daniel

Subjects
Condensed Matter - Materials Science
Abstract

We have theoretically investigated the electronic properties of neutral and $n$-doped dangling bond (DB) quasi-one-dimensional structures (lines) in the Si(001):H and Ge(001):H substrates with the aim of identifying atomic-scale interconnects exhibiting metallic conduction for use in on-surface circuitry. Whether neutral or doped, DB lines are prone to suffer geometrical distortions or have magnetic ground-states that render them semiconducting. However, from our study we have identified one exception -- a dimer row fully stripped of hydrogen passivation. Such a DB-dimer line shows an electronic band structure which is remarkably insensitive to the doping level and, thus, it is possible to manipulate the position of the Fermi level, moving it away from the gap. Transport calculations demonstrate that the metallic conduction in the DB-dimer line can survive thermally induced disorder, but is more sensitive to imperfect patterning. In conclusion, the DB-dimer line shows remarkable stability to doping and could serve as a one-dimensional metallic conductor on $n$-doped samples., Comment: 8 pages, 5 figures

Published
2016
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27. {\Pi} Band Dispersion along Conjugated Organic Nanowires Synthesized on a Metal Oxide Semiconductor

Author

Vasseur, Guillaume, Abadia, Mikel, Miccio, Luis A., Brede, Jens, Garcia-Lekue, Aran, de Oteyza, Dimas G., Rogero, Celia, Lobo-Checa, Jorge, and Ortega, J. Enrique

Subjects
Condensed Matter - Materials Science
Abstract

Surface confined dehalogenation reactions are versatile bottom-up approaches for the synthesis of carbon-based nanostructures with predefined chemical properties. However, for devices generally requiring low conductivity substrates, potential applications are so far severely hampered by the necessity of a metallic surface to catalyze the reactions. In this work we report the synthesis of ordered arrays of poly(p-phenylene) chains on the surface of semiconducting TiO2(110) via a dehalogenative homocoupling of 4,4"-dibromoterphenyl precursors. The supramolecular phase is clearly distinguished from the polymeric one using low energy electron diffraction and scanning tunneling microscopy as the substrate temperature used for deposition is varied. X ray photoelectron spectroscopy of C 1s and Br 3d core levels traces the temperature of the onset of dehalogenation to around 475 K. Moreover, angle-resolved photoemission spectroscopy and tight-binding calculations identify a highly dispersive band characteristic of a substantial overlap between the precursor's {\pi} states along the polymer, considered as the fingerprint of a successful polymerization. Thus, these results establish the first spectroscopic evidence that atomically precise carbon based nanostructures can readily be synthesized on top of a transition-metal oxide surface, opening the prospect for the bottom-up production of novel molecule-semiconductor devices.

Published
2016
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28. Susbtrate-Induced Stabilization and Reconstruction of Zigzag Edges in Graphene Nanoislands on Ni(111)

Author

Garcia-Lekue, A., Olle, M., Sanchez-Portal, D., Palacios, J. J., Mugarza, A., Ceballos, G., and Gambardella, P.

Subjects
Condensed Matter - Materials Science
Abstract

We combine experimental observations by scanning tunneling microscopy (STM) and density functional theory (DFT) to reveal the most stable edge structures of graphene on Ni(111) as well as the role of stacking-driven activation and suppression of edge reconstruction. Depending on the position of the outermost carbon atoms relative to hollow and on-top Ni sites, zigzag edges have very different energies. Triangular graphene nanoislands are exclusively bound by the more stable zigzag hollow edges. In hexagonal nanoislands, which are constrained by geometry to alternate zigzag hollow and zigzag top edges along their perimeter, only the hollow edge is stable whereas the top edges spontaneously reconstruct into the (57) pentagon-heptagon structure. Atomically-resolved STM images are consistent with either top-fcc or top-hcp epitaxial stacking of graphene and Ni sites, with the former being favored by DFT. Finally, we find that there is a one-to-one relationship between the edge type, graphene stacking, and orientation of the graphene islands.

Published
2015

29. Kondo effect of co-porphyrin: Remarkable sensitivity to adsorption sites and orientations

Author

Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia e Innovación (España), Eusko Jaurlaritza, European Commission, Ikerbasque Basque Foundation for Science, Donostia International Physics Center, Meng, Xiangzhi, Möller, Jenny, Menchón, Rodrigo E., Weismann, Alexander, Sánchez-Portal, Daniel, Garcia-Lekue, Aran, Herges, Rainer, Berndt, Richard, Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia e Innovación (España), Eusko Jaurlaritza, European Commission, Ikerbasque Basque Foundation for Science, Donostia International Physics Center, Meng, Xiangzhi, Möller, Jenny, Menchón, Rodrigo E., Weismann, Alexander, Sánchez-Portal, Daniel, Garcia-Lekue, Aran, Herges, Rainer, and Berndt, Richard

Abstract

We investigated the Kondo effect of cobalt(II)-5-15-bis(4′-bromophenyl)-10,20-bis(4′-iodophenyl)porphyrin (CoTPPBr2I2) molecules on Au(111) with low-temperature scanning tunneling microscopy under ultrahigh vacuum conditions. The molecules exhibit four adsorption configurations at the top and bridge sites of the surface with different molecular orientations. The Kondo resonance shows extraordinary sensitivity to the adsorption configuration. By switching the molecule between different configurations, the Kondo temperature is varied over a wide range from ≈8 up to ≈250 K. Density functional theory calculations reveal that changes of the adsorption configuration lead to distinct variations of the hybridization between the molecule and the surface. Furthermore, we show that surface reconstruction plays a significant role for the molecular Kondo effect.

Published
2024

31. Synthesis and reactivity of a trigonal porous nanographene on a gold surface

Author

Zuzak, Rafal, Pozo, Iago, Engelund, Mads, Garcia-Lekue, Aran, Vilas-Varela, Manuel, Alonso,José M., Szymonski,Marek, Guitián, Enrique, Pérez, Dolores, Godlewski,Szymon, Peña, Diego, Zuzak, Rafal, Pozo, Iago, Engelund, Mads, Garcia-Lekue, Aran, Vilas-Varela, Manuel, Alonso,José M., Szymonski,Marek, Guitián, Enrique, Pérez, Dolores, Godlewski,Szymon, and Peña, Diego

Abstract

The synthesis of porous nanographenes is a challenging task for solution chemistry, and thus, on-surface synthesis provides an alternative approach. Here, we report the synthesis of a triporous nanographene with 102 sp2 carbon atoms by combining solution and surface chemistry. The carbon skeleton was obtained by Pd-catalyzed cyclotrimerization of arynes in solution, while planarization of the molecule was achieved through two hierarchically organized on-surface cyclodehydrogenation reactions, intra- and inter-blade. Remarkably, the three non-planar 14]annulene pores of this nanographene further evolved at higher temperatures showing interesting intra-porous on-surface reactivity., Depto. de Química Orgánica, Fac. de Ciencias Químicas, TRUE, pub

Published
2024

32. Simulation of inelastic electron tunneling spectroscopy of single molecules with functionalized tips

Author

Garcia-Lekue, Aran, Sanchez-Portal, Daniel, Arnau, Andres, and Frederiksen, Thomas

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The role of the tip in inelastic electron tunneling spectroscopy (IETS) performed with scanning tunneling microscopes (STM) is theoretically addressed via first-principles simulations of vibrational spectra of single carbon monoxide (CO) molecules adsorbed on Cu(111). We show how chemically functionalized STM tips modify the IETS intensity corresponding to adsorbate modes on the sample side. The underlying propensity rules are explained using symmetry considerations for both the vibrational modes and the molecular orbitals of the tip and sample. This suggests that single-molecule IETS can be optimized by selecting the appropriate tip orbital symmetry., Comment: 11 pages, 6 figures

Published
2011
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36. Electronic transport in planar atomic-scale structures measured by two-probe scanning tunneling spectroscopy

Author

Marek Kolmer, Pedro Brandimarte, Jakub Lis, Rafal Zuzak, Szymon Godlewski, Hiroyo Kawai, Aran Garcia-Lekue, Nicolas Lorente, Thomas Frederiksen, Christian Joachim, Daniel Sanchez-Portal, and Marek Szymonski

Subjects
Science
Abstract

Measuring electronic transport at the atomic scale requires atom precise contacts. Here, the authors demonstrate quasi-one-dimensional electronic transport along a single dimer row on a germanium surface using a two probe scanning tunneling microscopy protocol.

Published
2019
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37. High-Level Correlated Approach to the Jellium Surface Energy, Without Uniform-Electron-Gas Input

Author

Constantin, Lucian A., Pitarke, J. M., Dobson, J. F., Garcia-Lekue, A., and Perdew, John P.

Subjects
Condensed Matter - Materials Science
Abstract

We resolve the long-standing controversy over the surface energy of simple metals: Density functional methods that require uniform-electron-gas input agree with each other at many levels of sophistication, but not with high-level correlated calculations like Fermi Hypernetted Chain and Diffusion Monte Carlo (DMC) that predict the uniform-gas correlation energy. Here we apply a very high-level correlated approach, the inhomogeneous Singwi-Tosi-Land-Sj\"olander (ISTLS) method, and find that the density functionals are indeed reliable (because the surface energy is "bulk-like"). ISTLS values are close to recently-revised DMC values. Our work also vindicates the previously-disputed use of uniform-gas-based nonlocal kernels in time-dependent density functional theory., Comment: 4 pages, 1 figure

Published
2007
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38. Atom Transfer and Single-Adatom Contacts

Author

Limot, L., Kröger, J., Berndt, R., Garcia-Lekue, A., and Hofer, W. A.

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The point contact of a tunnel tip approaching towards Ag(111) and Cu(111) surfaces is investigated with a low temperature scanning tunneling microscope. A sharp jump-to-contact, random in nature, is observed in the conductance. After point contact, the tip-apex atom is transferred to the surface, indicating that a one-atom contact is formed during the approach. In sharp contrast, the conductance over single silver and copper adatoms exhibits a smooth and reproducible transition from tunneling to contact regime. Numerical simulations show that this is a consequence of the additional dipolar bonding between the homoepitaxial adatom and the surface atoms., Comment: 4 pages, 4 figures

Published
2004
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39. Novel low-energy collective excitation at metal surfaces

Author

Silkin, V. M., Garcia-Lekue, A., Pitarke, J. M., Chulkov, E. V., Zaremba, E., and Echenique, P. M.

Subjects
Condensed Matter - Materials Science
Abstract

A novel collective excitation is predicted to exist at metal surfaces where a two-dimensional surface-state band coexists with the underlying three-dimensional continuum. This is a low-energy acoustic plasmon with linear dispersion at small wave vectors. Since new modern spectroscopies are especially sensitive to surface dynamics near the Fermi level, the existence of surface-state induced acoustic plasmons is expected to play a key role in a large variety of new phenomena and to create situations with potentially new physics., Comment: 6 pages, 3 figures, to appear in Europhys. Lett

Published
2004
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41. Role of occupied d bands in the dynamics of excited electrons and holes in Ag

Author

Garcia-Lekue, A., Pitarke, J. M., Chulkov, E. V., Liebsch, A., and Echenique, P. M.

Subjects
Condensed Matter - Materials Science
Abstract

The role that occupied $d$ bands play in the inelastic lifetime of bulk and surface states in Ag is investigated from the knowledge of the quasiparticle self-energy. In the case of bulk electrons, $sp$ bands are taken to be free-electron like. For surface states, the surface band structure of $sp$ states is described with the use of a realistic one-dimensional hamiltonian. The presence of occupied $d$ states is considered in both cases by introducing a polarizable background. We obtain inelastic lifetimes of bulk electrons that are in good agreement with first-principles band-structure calculations. Our surface-state lifetime calculations indicate that the agreement with measured lifetimes of both crystal-induced and image-potential induced surface states on Ag(100) and Ag(111) is considerably improved when the screening of $d$ electrons is taken into account., Comment: 9 pages, 9 figures, to appear in Phys. Rev. B

Published
2003
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42. Surface effects on the electronic energy loss of charged particles entering a metal surface

Author

Garcia-Lekue, A. and Pitarke, J. M.

Subjects
Condensed Matter - Materials Science
Abstract

Surface effects on the electronic energy loss of charged particles entering a metal surface are investigated within linear-response theory, in the framework of time-dependent density functional theory. Interesting phenomena occur in the loss spectra originated by the boundary (bregenzung) effect, which is as a consequence of the orthogonality of surface and bulk excitation modes. Our calculations indicate that the presence of a non-abrupt electron-density profile at the surface severely affects the nature of surface excitations, as deduced from comparison with simplified models., Comment: 7 pages, 3 figures, to appear in J. Electron Spectrosc

Published
2002

43. The role of surface plasmons in the decay of image-potential states on silver surfaces

Author

Garcia-Lekue, A., Pitarke, J. M., Chulkov, E. V., Liebsch, A., and Echenique, P. M.

Subjects
Condensed Matter - Materials Science
Abstract

The combined effect of single-particle and collective surface excitations in the decay of image-potential states on Ag surfaces is investigated, and the origin of the long-standing discrepancy between experimental measurements and previous theoretical predictions for the lifetime of these states is elucidated. Although surface-plasmon excitation had been expected to reduce the image-state lifetime, we demonstrate that the subtle combination of the spatial variation of s-d polarization in Ag and the characteristic non-locality of many-electron interactions near the surface yields surprisingly long image-state lifetimes, in agreement with experiment., Comment: 4 pages, 2 figures, to appear in Phys. Rev. Lett

Published
2002
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44. Energy loss of charged particles interacting with simple metal surfaces

Author

Garcia-Lekue, A. and Pitarke, J. M.

Subjects
Condensed Matter - Materials Science
Abstract

Self-consistent calculations of the energy-loss spectra of charged particles moving near a plane-bounded free electron gas are reported. Energy-loss probabilities are obtained, within linear-response theory, from the knowledge of the density-response function of the inhomogeneous electron system. Self-consistent single-particle wave functions and energies are obtained by solving the Kohn-Sham equation of density-functional theory, and the electronic response is then computed either in the random-phase approximation or with the use of an adiabatic local-density approximation. Special emphasis is placed on the various contributions from collective and electron-hole excitations to the energy loss of charged particles moving parallel with the surface. The effect of the electronic selvage at a metal surface on the energy-loss spectra is also discussed, by comparing our full self-consistent calculations with those obtained for electron densities that drop abruptly to zero at the surface., Comment: 10 pages, 9 figures, to appear in Phys. Rev. B

Published
2001
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45. An inhomogeneous and anisotropic Jastrow function for non-uniform many-electron systems

Author

Garcia-Lekue, A., Nekovee, M., Pitarke, J. M., and Gaudoin, R.

Subjects
Condensed Matter - Materials Science
Abstract

Quantum Monte Carlo simulations of interacting electrons in solids often use Slater-Jastrow trial wave functions. The Jastrow function takes into account correlations between pairs of electrons. In simulations of solids, it is common to use a Jastrow function which is both homogeneous and isotropic. The use of a homogeneous and isotropic Jastrow factor is questionable in applications to systems with strong density inhomogeneities, such as surfaces and multilayers. By generalizing the original derivation of the RPA Jastrow factor for the homogeneous electron gas [Gaskell] to inhomogeneous systems we derive an scheme for generating inhomogeneous and anisotropic Jastrow factors for use in nonuniform systems, from the non-interacting static structure factor and density of the system. We discuss aspects of our scheme and illustrate it with a first application to an inhomogeneous electron gas., Comment: 9 pages, 2 figures, to appear in Comp. Mater. Sci

Published
2001

46. Thin-film effects on the surface stopping power of a free electron gas

Author

Garcia-Lekue, A. and Pitarke, J. M.

Subjects
Condensed Matter - Materials Science
Abstract

The electronic properties of thin films present quantum-size effects, which are a consequence of the finite size of the system. Here we focus on the investigation of these effects on the electronic energy loss of charged particles moving parallel with thin metallic films. The energy loss is calculated, within linear-response theory, from the knowledge of the density-response function of the inhomogeneous electron system, which we evaluate either in the random-phase approximation or with the use of an adiabatic and local exchange-correlation kernel., Comment: 7 pages, 6 figures, to appear in Nucl. Instrum. Methods B

Published
2000
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47. Derivative-free optimization methods for surface structure determination of nanosystems

Author

Meza, Juan C., Garcia-Lekue, Arantzazu, Abramson, Mark A., and Dennis, John E.

Subjects
General and miscellaneous//mathematics, computing, and information science, optimization direct search nanostructure
Abstract

Many properties of nanostructures depend on the atomic configuration at the surface. One common technique used for determining this surface structure is based on the low energy electron diffraction (LEED) method, which uses a high-fidelity physics model to compare experimental results with spectra computed via a computer simulation. While this approach is highly effective, the computational cost of the simulations can be prohibitive for large systems. In this work, we propose the use of a direct search method in conjunction with an additive surrogate. This surrogate is constructed from a combination of a simplified physics model and an interpolation that is based on the differences between the simplified physics model and the full fidelity model.

Published
2007

49. Molecular Bridge Engineering for Tuning Quantum Electronic Transport and Anisotropy in Nanoporous Graphene

Author

Moreno, César, Diaz de Cerio, Xabier, Vilas-Varela, Manuel, Tenorio, Maria, Sarasola, Ane, Brandbyge, Mads, Peña, Diego, Garcia-Lekue, Aran, Mugarza, Aitor, Moreno, César, Diaz de Cerio, Xabier, Vilas-Varela, Manuel, Tenorio, Maria, Sarasola, Ane, Brandbyge, Mads, Peña, Diego, Garcia-Lekue, Aran, and Mugarza, Aitor

Abstract

Recent advances on surface-assisted synthesis have demonstrated that arrays of nanometer wide graphene nanoribbons can be laterally coupled with atomic precision to give rise to a highly anisotropic nanoporous graphene structure. Electronically, this graphene nanoarchitecture can be conceived as a set of weakly coupled semiconducting 1D nanochannels with electron propagation characterized by substantial interchannel quantum interferences. Here, we report the synthesis of a new nanoporous graphene structure where the interribbon electronic coupling can be controlled by the different degrees of freedom provided by phenylene bridges that couple the conducting channels. This versatility arises from the multiplicity of phenylene cross-coupling configurations, which provides a robust chemical knob, and from the interphenyl twist angle that acts as a fine-tunable knob. The twist angle is significantly altered by the interaction with the substrate, as confirmed by a combined bond-resolved scanning tunneling microscopy (STM) and ab initio analysis, and should accordingly be addressable by other external stimuli. Electron propagation simulations demonstrate the capability of either switching on/off or modulating the interribbon coupling by the corresponding use of the chemical or the conformational knob. Molecular bridges therefore emerge as efficient tools to engineer quantum transport and anisotropy in carbon-based 2D nanoarchitectures.

Published
2023

50. Molecular Bridge Engineering for Tuning Quantum Electronic Transport and Anisotropy in Nanoporous Graphene [Dataset]

Author

Moreno, César [cesar.moreno@unican.es], Peña, Diego [diego.pena@usc.es], García-Lekue, Aran [wmbgalea@ehu.eus], Mugarza, Aitor [aitor.mugarza@icn2.cat], Moreno, César, Díaz de Cerio, Xabier, Vilas-Varela, Manuel, Tenorio, Maria, Sarasola, Ane, Brandbyge, Mads, Peña, Diego, Garcia-Lekue, Aran, Mugarza, Aitor, Moreno, César [cesar.moreno@unican.es], Peña, Diego [diego.pena@usc.es], García-Lekue, Aran [wmbgalea@ehu.eus], Mugarza, Aitor [aitor.mugarza@icn2.cat], Moreno, César, Díaz de Cerio, Xabier, Vilas-Varela, Manuel, Tenorio, Maria, Sarasola, Ane, Brandbyge, Mads, Peña, Diego, Garcia-Lekue, Aran, and Mugarza, Aitor

Abstract

Recent advances on surface-assisted synthesis have demonstrated that arrays of nanometer wide graphene nanoribbons can be laterally coupled with atomic precision to give rise to a highly anisotropic nanoporous graphene structure. Electronically, this graphene nanoarchitecture can be conceived as a set of weakly coupled semiconducting 1D nanochannels with electron propagation characterized by substantial interchannel quantum interferences. Here, we report the synthesis of a new nanoporous graphene structure where the interribbon electronic coupling can be controlled by the different degrees of freedom provided by phenylene bridges that couple the conducting channels. This versatility arises from the multiplicity of phenylene cross-coupling configurations, which provides a robust chemical knob, and from the interphenyl twist angle that acts as a fine-tunable knob. The twist angle is significantly altered by the interaction with the substrate, as confirmed by a combined bond-resolved scanning tunneling microscopy (STM) and ab initio analysis, and should accordingly be addressable by other external stimuli. Electron propagation simulations demonstrate the capability of either switching on/off or modulating the interribbon coupling by the corresponding use of the chemical or the conformational knob. Molecular bridges therefore emerge as efficient tools to engineer quantum transport and anisotropy in carbon-based 2D nanoarchitectures.

Published
2023

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