The Photochemical Route to Octahedral Iron(V). Primary Processes and Quantum Yields from Ultrafast Mid-Infrared Spectroscopy

Vennekate, Hendrik; Schwarzer, Dirk; Torres-Alacan, Joel; Vöhringer, Peter

doi:10.1021/ja5045133

Cited by 33 publications

(26 citation statements)

References 36 publications

(89 reference statements)

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“…[40][41][42][43][44][45][46][47][48] Figure 3a displays transient IR spectra of tetrabenzylazodicarboxamide in chloroform (c = 6.6 mm)i nt he 1600-1775 cm À1 range associated with the carbonyl stretch region after excitation at 350 nm. [40][41][42][43][44][45][46][47][48] Figure 3a displays transient IR spectra of tetrabenzylazodicarboxamide in chloroform (c = 6.6 mm)i nt he 1600-1775 cm À1 range associated with the carbonyl stretch region after excitation at 350 nm.…”

Section: Switchingbetweentwoormorestatesonthemolecularlevelmentioning

confidence: 99%

“…To determine the light-triggered properties of the azodicarboxamide functional group,w eh ave performed picosecond time-resolved IR absorption spectroscopy,w hich has been shown to provide ah igh temporal resolution and structural sensitivity. [40][41][42][43][44][45][46][47][48] Figure 3a displays transient IR spectra of tetrabenzylazodicarboxamide in chloroform (c = 6.6 mm)i nt he 1600-1775 cm À1 range associated with the carbonyl stretch region after excitation at 350 nm. In agreement with our DFT calculations that show that the first electronic transition with nonzero oscillator strength is expected at around 340 nm, no transient signals could be observed upon excitation at longer wavelengths.T his transition corresponds to the S 3 !…”

Section: Switchingbetweentwoormorestatesonthemolecularlevelmentioning

confidence: 99%

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Photoinduced Pedalo‐Type Motion in an Azodicarboxamide‐Based Molecular Switch

et al. 2017

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Well-defined structural changes of molecular units that can be triggered by light are crucial for the development of photoactive functional materials.Herein, we report on anovel switch that has azodicarboxamide as its photo-triggerable element. Time-resolved UV-pump/IR probe spectroscopyi n combination with quantum-chemical calculations shows that the azodicarboxamide functionality,i nc ontrast to other azobased chromophores,does not undergo trans-cis photoisomerization. Instead, ap hotoinduced pedalo-type motion occurs, which because of its volume-conserving properties enables the design of functional molecular systems with controllable motion in aconfined space.

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Section: Switchingbetweentwoormorestatesonthemolecularlevelmentioning

confidence: 99%

Section: Switchingbetweentwoormorestatesonthemolecularlevelmentioning

confidence: 99%

Photoinduced Pedalo‐Type Motion in an Azodicarboxamide‐Based Molecular Switch

et al. 2017

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“…[19,20] Later however, ultrafast experiments revealed the formation of iron nitrides at room temperature as well. [21][22][23] Here, we study photodissociation of iron(III) azides at molecular level with ion spectroscopy at variable temperature (3 K -310 K). [24][25][26][27] The experiments provide absorption spectra of mass-selected ions separated according to the individual dissociation pathways.…”

Section: Introductionmentioning

confidence: 99%

Spin‐State‐Controlled Photodissociation of Iron(III) Azide to an Iron(V) Nitride Complex

et al. 2017

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We address the generation of the iron(V) nitride complexes, targets of biomimetic chemistry. Temperature dependent ion spectroscopy demonstrate that generation of iron(V) nitrides is governed by the spin state population of their iron(III) azide precursors and can be tuned by temperature. Complex [(MePy2TACN)Fe(N3)] 2+ exists as a mixture of sextet and doublet spin states at 300 K, whereas only the doublet state is populated at 3 K. Photofragmentation of the sextet state complex leads to reduction of the iron center. The doublet state complex photodissociates to the desired iron(V) nitride complex. We show analogous behaviour also for complexes with cyclam-based ligands.

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“…[19,20] However,u ltrafast experiments have recently shown the formation of iron nitrides at room temperature. [21][22][23] Herein, we report the photodissociation of iron(III) azides studied at the molecular level by ion spectroscopy using different temperatures (3-310 K). [24][25][26][27] Photo-dissociation of mass-selected iron azide complexes 1 [28] in the visible range resulted in photoreduction associated with N 3 C elimination or photooxidation, forming the desired iron-(V) nitride complex 3,concomitantly with the elimination of N 2 (Scheme 1).…”

mentioning

confidence: 99%

Spin‐State‐Controlled Photodissociation of Iron(III) Azide to an Iron(V) Nitride Complex

et al. 2017

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The generation of iron(V) nitride complexes, which are targets of biomimetic chemistry, is reported. Temperature-dependent ion spectroscopy shows that this reaction is governed by the spin-state population of their iron(III) azide precursors and can be tuned by temperature. The complex [(MePy TACN)Fe(N )] (MePy TACN=N-methyl-N,N-bis(2-picolyl)-1,4,7-triazacyclononane) exists as a mixture of sextet and doublet spin states at 300 K, whereas only the doublet state is populated at 3 K. Photofragmentation of the sextet state complex leads to the reduction of the iron center. The doublet state complex photodissociates to the desired iron(V) nitride complex. To generalize these findings, we show results for complexes with cyclam-based ligands.

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The Photochemical Route to Octahedral Iron(V). Primary Processes and Quantum Yields from Ultrafast Mid-Infrared Spectroscopy

Cited by 33 publications

References 36 publications

Photoinduced Pedalo‐Type Motion in an Azodicarboxamide‐Based Molecular Switch

Photoinduced Pedalo‐Type Motion in an Azodicarboxamide‐Based Molecular Switch

Spin‐State‐Controlled Photodissociation of Iron(III) Azide to an Iron(V) Nitride Complex

Spin‐State‐Controlled Photodissociation of Iron(III) Azide to an Iron(V) Nitride Complex

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