Synthesis and Computational Study of a Pyridylcarbene Fe(II) Complex: Unexpected Effects of <i>fac</i>/<i>mer</i> Isomerism in Metal-to-Ligand Triplet Potential Energy Surfaces

Francés‐Monerris, Antonio; Magra, Kévin; Darari, Mohamed; Cebrián, Cristina; Beley, Marc; Domenichini, Edoardo; Haacke, S.; Pastore, Mariachiara; Assfeld, Xavier; Gros, P.; Monari, Antonio

doi:10.1021/acs.inorgchem.8b01695

Cited by 39 publications

(103 citation statements)

References 71 publications

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“…Figure S16. Coherently with what observed for fac-C1 and mer-C1, 23 the main coordinate driving the process is the enlargement of the Fe-N1 bond, which has a bond distance of 2.82 Å at the T 1 ( 3 MC) min geometry ( Fig. 4a).…”

Section: Excited-state Computational Studiessupporting

confidence: 72%

“…Recently, and to influence the angular strain, we have reported the first example of iron complex with bidentate pyridylcarbene ligands C1. 23 The asymmetric nature of the employed ligand led to different geometrical isomers. In fact, C1 was obtained as a mixture of mostly the meridional (mer) isomer with a concomitant fraction of the facial (fac) isomer in a 14:1 ratio.…”

Section: Introductionmentioning

confidence: 99%

“…In particular, the low-lying triplet PES of the mer isomer, leading to the MC population and deactivation, was found to be much steeper than the one of the corresponding fac isomer. 23 This aspect is intimately linked to the larger stabilization of the 3 MC state in the mer arrangement as compared to the fac one. Altogether, our molecular modelling results indicate a much faster deactivation for the mer isomer.…”

Section: Introductionmentioning

confidence: 99%

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Impact of the fac/mer Isomerism on the Excited-State Dynamics of Pyridyl-carbene Fe(II) Complexes

et al. 2019

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The control of photophysical properties of iron complexes and especially of their excited states decay is a great challenge in the search for sustainable alternatives to noble metals in photochemical applications. Herein we report the synthesis and investigations of the photophysics of mer and fac iron complexes bearing bidentate pyridyl-NHC ligands, coordinating the Fe with three ligand-field enhancing carbene bonds. Ultrafast transient absorption spectroscopy reveals two distinct excited state populations for both mer and fac forms, ascribed to the populations of the T1 and the T2 states, respectively, which decay to the ground state via parallel pathways. We find 3-4 ps and 15-20 ps excited state lifetimes, with respective amplitudes depending on the isomer. The longer lifetime exceeds the one reported for iron complexes with tridentate ligands analogues involving four iron-carbene bonds. By combining experimental and computational results, a mechanism based on the differential trapping of the triplet states in spin-crossover regions is proposed for the first time to explain the impact of the fac/mer isomerism on the overall excited-state lifetimes. Our results clearly highlight the impact of bidentate Pyridyl-NHC ligands on the photophysics of iron complexes, especially the paramount role of fac/mer isomerism in modulating the overall decay process, which can be potentially exploited in the design of new Fe(II)-based photoactive compound.

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Section: Excited-state Computational Studiessupporting

confidence: 72%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Impact of the fac/mer Isomerism on the Excited-State Dynamics of Pyridyl-carbene Fe(II) Complexes

et al. 2019

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“…[14,31] Recent computational work by Monaria nd co-workers demonstrated that there could be subtle but important differences in the 3 MLCT deactivation pathways for fac and mer isomers of the same Fe II -carbene complex, and they concluded that FeÀN bond elongation was the key normalc oordinate leading to triplet relaxation. [32] Their work underscores the importance of complete calculation of the potential-energy surfaces to adequately describe excited-state relaxation.…”

Section: Mlct States In Strained Low-spin Complexesmentioning

confidence: 99%

Is Iron the New Ruthenium?

Wenger

2019

Chemistry A European J

234

273

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Ruthenium complexes with polypyridine ligands are very popularc hoices for applications in photophysics and photochemistry,f or example, in lighting, sensing, solar cells, and photoredox catalysis. There is al ong-standing interest in replacing ruthenium with iron because ruthenium is rare and expensive, whereas iron is comparatively abundant and cheap.H owever,i ti sv ery difficult to obtain iron complexes with an electronic structure similart ot hat of ruthenium(II) polypyridines. The latter typicallyh ave al onglived excited state with pronounced charge-transferc haracter between the ruthenium metal and ligands. These metalto-ligand charge-transfer( MLCT) excited states can be luminescent, with typical lifetimesi nt he range of 100 to 1000 ns, and the electrochemical properties are drastically altered during this time. These properties make ruthenium(II) polypyridine complexes so well suited for the abovementioned applications. In iron(II) complexes, the MLCT states [a] Prof.

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“…The use of a bidentate pyridine-imidazole-derived ligand led to [Fe(mpi) 3 ] 2+ (mpi = 3-methyl-1-(pyridin-2-yl)-imidazol-2-ylidene) which exists in two different isomers with either meridional or facial coordination of the carbene/pyridine moieties (Figure 15) [54]. When synthesized the complex is obtained in a 14:1 mer/fac mixture that is inseparable.…”

Section: Fenhc Complexes With Bidentate Ligandsmentioning

confidence: 99%

Design and Synthesis of Photoactive Iron N-Heterocyclic Carbene Complexes

Kaufhold

Wärnmark

2020

Catalysts

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The use of iron in photoactive metal complexes has been investigated for decades. In this respect, the charge transfer (CT) states are of particular interest, since they are usually responsible for the photofunctionality of such compounds. However, only recently breakthroughs have been made in extending CT excited state lifetimes that are notoriously short-lived in classical polypyridine iron coordination compounds. This success is in large parts owed to the use of strongly σ-donating N-heterocyclic carbene (NHC) ligands that help manipulating the photophysical and photochemical properties of iron complexes. In this review we aim to map out the basic design principles for the generation of photofunctional iron NHC complexes, summarize the progress made so far and recapitulate on the synthetic methods used. Further, we want to highlight the challenges still existing and give inspiration for future generations of photoactive iron complexes.

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Synthesis and Computational Study of a Pyridylcarbene Fe(II) Complex: Unexpected Effects of fac/mer Isomerism in Metal-to-Ligand Triplet Potential Energy Surfaces

Cited by 39 publications

References 71 publications

Impact of the fac/mer Isomerism on the Excited-State Dynamics of Pyridyl-carbene Fe(II) Complexes

Impact of the fac/mer Isomerism on the Excited-State Dynamics of Pyridyl-carbene Fe(II) Complexes

Is Iron the New Ruthenium?

Design and Synthesis of Photoactive Iron N-Heterocyclic Carbene Complexes

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