Quantum units from the topological engineering of molecular graphenoids

Lombardi, Federico; Lodi, Alessandro; Ma, Ji; Liu, Junzhi; Slota, Michael; Narita, Akimitsu; Myers, William K.; Müllen, Kläus; Feng, Xinliang; Bogani, Lapo

doi:10.1126/science.aay7203

Cited by 132 publications

(118 citation statements)

References 46 publications

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“…Moreover, the introduction of nonplanarity by the incorporation of nonhexagonal rings into sp 2 -carbon frameworks may provide an alternative pathway. [140][141][142][143][144] Only by overcoming the stability obstacle will further integration of these exotic materials in carbon-based nanoelectronic devices become possible.…”

Section: Discussionmentioning

confidence: 99%

Synthetic Tailoring of Graphene Nanostructures with Zigzag‐Edged Topologies: Progress and Perspectives

2020

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Experimental and theoretical investigations have revealed that the chemical and physical properties of graphene are crucially determined by their topological structures. Therefore, the atomically precise synthesis of graphene nanostructures is essential. A particular example is graphene nanostructures with zigzag‐edged structures, which exhibit unique (opto)electronic and magnetic properties owing to their spin‐polarized edge state. Recent progress in the development of synthetic methods and strategies as well as characterization methods has given access to this class of unprecedented graphene nanostructures, which used to be purely molecular objectives in theoretical chemistry. Thus, clear insight into the structure–property relationships has become possible as well as new applications in organic carbon‐based electronic and spintronic devices. In this Minireview, we discuss the recent progress in the controlled synthesis of zigzag‐edged graphene nanostructures with different topologies through a bottom‐up synthetic strategy.

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Section: Discussionmentioning

confidence: 99%

Synthetic Tailoring of Graphene Nanostructures with Zigzag‐Edged Topologies: Progress and Perspectives

2020

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“…The method of choice to investigate spin phenomena is EPR. Using advanced techniques, we can decouple the spins from the nuclear spin bath yielding competing quantum coherence times nearly reaching milliseconds, as it has been shown for graphenoids [282,283]. Addressing single molecules via EPR can then happen using magnetic scanning tunnelling tips [284].…”

Section: Discussionmentioning

confidence: 99%

Combining Molecular Spintronics with Electron Paramagnetic Resonance: The Path Towards Single-Molecule Pulsed Spin Spectroscopy

Slota¹,

Bogani²

2020

Appl Magn Reson

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We provide a perspective on how single-molecule magnets can offer a platform to combine quantum transport and paramagnetic spectroscopy, so as to deliver time-resolved electron paramagnetic resonance at the single-molecule level. To this aim, we first review the main principles and recent developments of molecular spintronics, together with the possibilities and limitations offered by current approaches, where interactions between leads and single-molecule magnets are important. We then review progress on the electron quantum coherence on devices based on molecular magnets, and the pulse sequences and techniques necessary for their characterization, which might find implementation at the single-molecule level. Finally, we highlight how some of the concepts can also be implemented by including all elements into a single molecule and we propose an analogy between donor–acceptor triads, where a spin center is sandwiched between a donor and an acceptor, and quantum transport systems. We eventually discuss the possibility of probing spin coherence during or immediately after the passage of an electron transfer, based on examples of transient electron paramagnetic resonance spectroscopy on molecular materials.

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“…207 Pulsed EPR spectroscopy of 88 measured in the group of Lapo Bogani provides the spin lattice and coherence times as characteristic features of the high-spin structure. 208 The significance of high coherence times will be reconsidered for spin-bearing GNRs below. An example of a diradical structure that follows from topological frustration rather than from five-or seven-membered defects is the case of 90, the so-called Clar goblet with the shape of a bowtie, which was introduced by Roman Fasel and Xinliang Feng ( Figure 15A).…”

Section: Synthesis and Opportunities In Physicsmentioning

confidence: 99%

Spiers Memorial Lecture : Carbon nanostructures by macromolecular design – from branched polyphenylenes to nanographenes and graphene nanoribbons

2021

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Quantum units from the topological engineering of molecular graphenoids

Cited by 132 publications

References 46 publications

Synthetic Tailoring of Graphene Nanostructures with Zigzag‐Edged Topologies: Progress and Perspectives

Synthetic Tailoring of Graphene Nanostructures with Zigzag‐Edged Topologies: Progress and Perspectives

Combining Molecular Spintronics with Electron Paramagnetic Resonance: The Path Towards Single-Molecule Pulsed Spin Spectroscopy

Spiers Memorial Lecture : Carbon nanostructures by macromolecular design – from branched polyphenylenes to nanographenes and graphene nanoribbons

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