Quantitative wave function analysis for excited states of transition metal complexes

Mai, Sebastian; Dorn, Johann; Fumanal, Maria; Daniel, Chantal; González, Leticia

doi:10.1016/j.ccr.2018.01.019

Cited by 126 publications

(169 citation statements)

References 194 publications

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“…For the potential diagrams, the two Ru−N bonds that are elongated in the 3 MC states were constrained to the respective averaged elongated values. The assignment of the state characters has been done dividing the molecule into three fragments (metal center and two ligands) and calculating charge transfer numbers, as implemented in the TheoDore software package …”

Section: Methodsmentioning

confidence: 99%

Green‐Light Activation of Push–Pull Ruthenium(II) Complexes

Moll

Wang

Päpcke

et al. 2020

Chemistry A European J

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Synthesis, characterization, electrochemistry,a nd photophysicso fh omo-a nd heteroleptic ruthenium(II) complexes [Ru(cpmp) 2 ] 2 + (2 2 + + )a nd [Ru(cpmp)(ddpd)] 2 + (3 2 + + ) bearing the tridentate ligands 6,2''-carboxypyridyl-2,2'-methylamine-pyridyl-pyridine( cpmp)a nd N,N'-dimethyl-N,N'-dipyridin-2-ylpyridine-2,6-diamine (ddpd) are reported. The complexes possess one (3 2 + + )o rt wo (2 2 + + )e lectron-deficient dipyridyl ketone fragments as electron-accepting sites enabling intraligand charget ransfer (ILCT), ligand-to-ligand charge transfer (LL'CT) and low-energy metal-to-ligand charge transfer (MLCT) absorptions. The latter peak around 544 nm (green light). Complex 2 2 + + shows 3 MLCT phosphor-escencei nthe red to near-infrared spectral region at room temperature in deaerated acetonitrile solution with an emission quantum yield of 1.3 %a nd a 3 MLCT lifetimeo f4 77 ns, whereas 3 2 + + is much less luminescent. This different behavior is ascribed to the energy gap law and the shape of the parasitic excited 3 MC state potential energy surface. This study highlights the importance of the excited-state energies and geometries for the actual excited-state dynamics. Aromatic and aliphatic amines reductively quench the excited state of 2 2 + + paving the way to photocatalytic applications using low-energyg reen light as exemplified with the green-light-sensitized thiol-ene click reaction.Scheme1.Benchmarkruthenium(II) complexesa nd their absorption/ emission band maxima.[a] J.Scheme3.Photocatalytic radical thiol-eneclick reaction utilizing the (green) light-induced reductive quenching pathway of [RuLL] 2 + = 2 2 + + , 3 2 + + and [Ru(bpy) 3 ] 2 + mediated by p-toluidine (Ar = p-C 6 H 4 -CH 3 )a ccordingt oref.[71] (R = CH 2 -CHNHBoc-COOCH 3 ).

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Section: Methodsmentioning

confidence: 99%

Green‐Light Activation of Push–Pull Ruthenium(II) Complexes

Moll

Wang

Päpcke

et al. 2020

Chemistry A European J

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“…Moreover,p otential energy surfaces can be mapped out along (a selection of) the vibrational normalm odes [82,[96][97][98][99] to be used as input for explicit excited-state dynamics simulations as further described in Section4.3. Among the critical points on the PES of the different spin states, the minimal energy crossingpoints (MECPs) are of special relevance not only for luminescent properties [12,100] and photochemical reactions in transition-metal complexes, [101] but also to spin-forbidden reactions. [102] In the latter case, MECPs determine the lowest energy at which two electronic states of different spin are degenerate, and hence,take us to the lowest energybarrier in two-state reactivity.…”

Section: Potential Energy Surfacesmentioning

confidence: 99%

“…However,i ti sn ot uncommon that the molecular orbitals are strongly delocalized over ligand and metal or that the wave function adopts ah igh multiconfigurational character andthat the character of the different electronic states is less evident. Among the different (semi-)automatic alternatives for the visual inspection, we mention here the orthogonal valence bond interpretation of the multiconfigurational wave function, [10,11] the analysis in terms of so-called charge-transfer numbers extracted from the one-electron transition density matrix recently presented by Mai et al, [12] and the density (difference) based indexes as descriptors for the character of the excited-state character by Ciofini and co-workers. [13] The photoinduced intramolecular electron transfer can be accompanied by important structural changes both in the molecular system and its nearest environment, which include cooperative effects, solvatione ffects or thermald istortions.T he extento ft he geometrical relaxation within the molecular complex as ar esult of the deactivation process relies on the particular system.…”

Section: Introductionmentioning

confidence: 99%

Deactivation of Excited States in Transition‐Metal Complexes: Insight from Computational Chemistry

Sousa

Alías-Rodríguez

Domingo

et al. 2018

Chemistry A European J

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Investigation of the excited-state decay dynamics of transition-metal systems is a crucial step for the development of photoswitchable molecular based materials with applications in growing fields as energy conversion, data storage, or molecular devices. The photophysics of these systems is an entangled problem arising from the interplay of electronic and geometrical rearrangements that take place on a short time scale. Several factors play a role in the process: various electronic states of different spin and chemical character are involved, the system undergoes important structural variations and several nonradiative processes can occur. Computational chemistry is a useful tool to get insight into the microscopic description of the photophysics of these materials, since it provides unique information about the character of the electronic spin states involved, the energetics and time evolution of the system. In this review article, we present an overview of the state of the art methodologies available to address the several aspects that have to be incorporated to properly describe the deactivation of excited states in transition-metal complexes. The most recent developments in theoretical methods are discussed and illustrated with examples.

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“…Depending on the method used for computing the electronic transitions, the objects derived from these calculations will not have the same structure and the same properties . As the analysis of the nature of the excited states generally relies on the use of these objects (in particular the transition and difference density matrices, that will both be at the center of this contribution), either from a qualitative point of view using exciton analysis or one‐particle charge density functions and their corresponding density matrices, or under a quantitative perspective using descriptors, a proper knowledge of their structure is required for selecting the right post‐processing strategy. Unfortunately, while the structure of the objects derived from the calculations are often known for the most common calculation methods, in most of the cases this structure is given without a demonstration.…”

Section: Introductionmentioning

confidence: 99%

A comprehensive, self‐contained derivation of the one‐body density matrices from single‐reference excited‐state calculation methods using the equation‐of‐motion formalism

Etienne

2020

Int J of Quantum Chemistry

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In this contribution, we review in a rigorous, yet comprehensive fashion the assessment of the one‐body reduced density matrices derived from the most used single‐reference excited‐state calculation methods in the framework of the equation‐of‐motion formalism. Those methods are separated into two types: those which involve the coupling of a deexcitation operator to a single‐excitation transition operator, and those which do not involve such a coupling. The case of many‐body auxiliary wave functions for excited states is also addressed. For each of these approaches we were interested in deriving the elements of the one‐body transition and difference density matrices, and to highlight their particular structure. This has been accomplished by applying a decomposition of integrals involving one‐determinant quantum electronic states on which two or three pairs of second quantization operators can act. Such a decomposition has been done according to a corollary to Wick's theorem, which is brought in a comprehensive and detailed manner. A comment is also given about the consequences of using the equation‐of‐motion formulation in this context, and the two types of excited‐state calculation methods (with and without coupling excitations to deexcitations) are finally compared from the point of view of the structure of their transition and difference density matrices.

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Quantitative wave function analysis for excited states of transition metal complexes

Cited by 126 publications

References 194 publications

Green‐Light Activation of Push–Pull Ruthenium(II) Complexes

Green‐Light Activation of Push–Pull Ruthenium(II) Complexes

Deactivation of Excited States in Transition‐Metal Complexes: Insight from Computational Chemistry

A comprehensive, self‐contained derivation of the one‐body density matrices from single‐reference excited‐state calculation methods using the equation‐of‐motion formalism

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