Photoswitchable stable charge-distributed states in a new cobalt complex exhibiting photo-induced valence tautomerism

Slota, Michael; Blankenhorn, Marian; Heintze, Eric; Vu, Minh Duy; Hübner, Ralph; Bogani, Lapo

doi:10.1039/c5fd00088b

Cited by 14 publications

(9 citation statements)

References 50 publications

(109 reference statements)

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“…Due to advances in fabrication methods, it is now possible to synthesize ultra-clean GNRs via an bottom-up approach [271][272][273]. This allows us to chemically bond molecules, carrying a spin centre or photoswitchable unit [23,248,274,275], and directly integrate into spintronic devices for which fabrication methods exist [276]. Recently, it has been able to clearly observe the topological edge state in graphene nanoribbons [277], which represented a mainly theoretical concept thus far and experimental hints were scarce until then.…”

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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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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“…52 It is well known that solvation effects play a key role in the valence tautomerization process, and can either change the transition temperature or entirely deactivate the process. 9,[53][54][55][56] This has been attributed to intermolecular factors such as a change in polarity or lattice softness in crystalline VT compounds, which either changes the barrier or the energy difference between the two tautomers. It is likely that annealing produces one or both effects.…”

Section: Discussionmentioning

confidence: 99%

“…This class of compounds includes well studied materials such as Co-Fe Prussian Blue analogues and Co dioxolene complexes. [5][6][7][8][9] Dioxolene ligands have valence orbitals close in energy to those of third-row transition metal d orbitals, and can exist in multiple oxidation states. Previous results showed that the electronic structure of the two valence tautomers are localized, and can be thought of as electron transfer between the ligand and metal, with the metal center changing from LS Co III ↔ HS Co II .…”

Section: Introductionmentioning

confidence: 99%

Photoinduced Valence Tautomerism of a Cobalt-Dioxolene Complex Revealed with Femtosecond M-Edge XANES

Ash¹,

Zhang²,

Vura‐Weis

2019

Preprint

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Cobalt complexes that undergo charge-transfer induced spin-transitions (CTIST) or valence tautomerism (VT) from low spin (LS) Co(III) to high spin (HS) Co(II) are potential candidates for magneto-optical switches. We use M-edge XANES spectroscopy with 40 fs time resolution to measure the excited-state dynamics of Co(III)(Cat-N-SQ)(Cat-N-BQ), where Cat-N-BQ and Cat-N-SQ are the singly and doubly reduced forms of the 2-(2-hydroxy-3,5-di-tert-butylphenyl-imino)-4,6-di-tert-butylcyclohexa-3,5-dienone ligand. The extreme ultraviolet probe pulses, produced using a tabletop high-harmonic generation light source, measure 3p3d transitions and are sensitive to the spin and oxidation state of the Co center. Photoexcitation at 525 nm produces a low-spin Co(II) ligand-to-metal charge transfer state which undergoes intersystem crossing to high-spin Co(II) in 67 fs. Vibrational cooling from this hot HS Co(II) state competes on the hundreds-of-fs timescale with back-intersystem crossing to the ground state, with 60% of the population trapped in a cold HS Co(II) state for 24 ps. Ligand field multiplet simulations accurately reproduce the ground-state spectra and support the excited-state assignments. This work demonstrates the ability of M-edge XANES to measure ultrafast photophysics of molecular Co complexes.<br><br><br>

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“…Molecular magnetic materials offer a particularly rich experimental ground, 1 where sophisticated effects can be observed with particular clarity and tuned by the means of molecular synthetic chemistry. [2][3][4][5][6][7] They have allowed, for example the observation of magnetic quantum tunnelling, [8][9][10][11] Berry phase interference, 12 and permit controlling the spin degrees of freedom by light [13][14][15][16][17][18][19][20] or via other external stimuli. [21][22][23][24][25] Recent work has highlighted in particular the relevance of molecular magnetic materials for spintronics.…”

Section: Introductionmentioning

confidence: 99%

“…, within experimental error. These compounds also dis-13 play a wider dispersion of behaviours, with a few cases14 showing exponents up to 3. This effect is actually to 15 be linked to a more limited experimental accuracy, pro-16 duced by the presence of other mechanisms, such as traps see Section V) and the limited voltage range between C and the breakdown voltage of the crystals.…”

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confidence: 99%

Conduction mechanism of nitronyl-nitroxide molecular magnetic compounds

et al. 2016

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We investigate the conduction mechanisms of nitronyl-nitroxide molecular radicals, as useful for the creation of nanoscopic molecular spintronic devices, finding that it does not correspond to standard Mott behaviour, as previously postulated. We provide a complete investigation using transport measurements, low-energy, sub-THz spectroscopy and introducing differently-substituted phenyl appendages. We show that a non-trivial surface-charge limited regime is present in addition to the standard low-voltage ohmic conductance. Scaling analysis allows determining all the main transport parameters for the compounds, and highlights the presence of charge trapping effects. Comparison among the different compounds shows the relevance of intermolecular stacking between the aromatic ring of the phenyl appendix and the NIT motif in the creation of useful electron transport channels. The importance of intermolecular pathways is further highlighted by electronic structure calculations, which clarify the nature of the electronic channels and their effect on the Mott character of the compounds.

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Photoswitchable stable charge-distributed states in a new cobalt complex exhibiting photo-induced valence tautomerism

Cited by 14 publications

References 50 publications

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

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

Photoinduced Valence Tautomerism of a Cobalt-Dioxolene Complex Revealed with Femtosecond M-Edge XANES

Conduction mechanism of nitronyl-nitroxide molecular magnetic compounds

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