Azo-dimethylaminopyridine-functionalized Ni(II)-porphyrin as a photoswitchable nucleophilic catalyst

Ludwig, Jannis; Helberg, Julian; Zipse, Hendrik; Herges, Rainer

doi:10.3762/bjoc.16.179

Cited by 13 publications

(41 citation statements)

References 32 publications

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“…On the other hand, specific designs are desired in metal-based molecular systems, which give additional advantages in modulating inherent physicochemical properties such as the electrocatalytic, magnetic, redox and biological behaviour of these complexes by light. Such complexes find applications in light-induced ligand-driven spin crossover complexes, 5–7 redox switches, 8,9 photoswitchable catalysts, 10–12 nonlinear optics, 13,14 logics and memories, 15 supramolecular chemistry, 16–18 etc . Indeed, phototunability can be introduced into transition metal complexes by incorporating different organic photochromes within the ligand frameworks.…”

Section: Introductionmentioning

confidence: 99%

Solid-state photochromic arylazopyrazole-based transition metal complexes

Gupta

Gaur

Chauhan

et al. 2022

Inorg. Chem. Front.

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Section: Introductionmentioning

confidence: 99%

Solid-state photochromic arylazopyrazole-based transition metal complexes

Gupta

Gaur

Chauhan

et al. 2022

Inorg. Chem. Front.

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“…A fundamentally different approach toward achieving switchable catalysis is coupling of organic photoswitches with catalytically active organometallic complexes. [55][56][57][58][59][60][97][98][99][100][101][102][103][104][105][106] Similar to the purely-organic systems described above, photochromic organometallic complexes can take advantage of significant changes in geometric parameters or physicochemical properties of the complex upon isomerization of a photochromic ligand. Moreover, access to d-orbitals from transition metals expands the scope of geometries available for photoswitch integration in comparison with many organic systems.…”

Section: Organometallic Catalysismentioning

confidence: 99%

“…Rather than geometric control of reaction rate or yield, a different approach to switchable catalysis can be achieved through modulation of the electronic properties of the metal center for catalytically active organometallic complexes. [57][58][59][60]103] For example, change in a metal center's oxidation state could significantly alter the catalytic activity. Subtle shifts in ligand field strength, as well as LMCT, MLCT, or PET could be utilized to affect the metal oxidation states.…”

Section: Changes In Electronic Properties Of Catalysts As a Function ...mentioning

confidence: 99%

Traffic Lights for Catalysis: Stimuli‐Responsive Molecular and Extended Catalytic Systems

et al. 2023

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The advances made in the field of stimuli-responsive catalysis during the last five years with a focus on the novel recently-emerged directions and applications have been surveyed. Metal-free catalysts and organometallic complexes, as well as biomimetic systems and extended structures, which display switchable catalytic activity for a variety of organic transformations, are discussed. Light-activated systems comprised of photochromic molecules capable of modulating reaction rate, yield, or enantioselectivity based on geometric and electronic changes associated with photoisomerization are the focus of the detailed discussion. Alternative stimuli, including pH and temperature, which could be applied either alone or in combination with light, are also addressed. Recent advances clearly demonstrate that the capability to finely tune catalyst behavior via an external stimulus is a powerful tool that could alter the landscape of sustainable chemistry.

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“…The few examples reported to date in the literature involve a quite limited number of transition metals, namely, Fe(II), 27−29 Mn(V), 30 or Ni-(II), 24,25,31−38 selected for their ability to undergo HS ↔ LS transitions following the addition or removal of ligand(s) from the metal center (Figure 1a). 31,39 All of these achievements involve the use of chemicals (pH) 27,40,41 or light 24,[31][32][33][34][35]38,42,43 as triggers for molecular motions, leading to an increase or decrease in the coordination number of the metal. In contrast, far less progress has been made in these directions with electron-responsive systems, even though electricity stands as a particularly attractive, controllable, and clean trigger in the perspective of applications in solid-state devices.…”

Section: ■ Introductionmentioning

confidence: 99%

“…, from a high-spin (HS) to a low-spin (LS) state, are triggered by rational/drastic modifications of the first coordination sphere of a given metal center upon stimulation. The few examples reported to date in the literature involve a quite limited number of transition metals, namely, Fe(II), − Mn(V), or Ni(II), ,,− selected for their ability to undergo HS ↔ LS transitions following the addition or removal of ligand(s) from the metal center (Figure a). , All of these achievements involve the use of chemicals (pH) ,, or light ,− ,,, as triggers for molecular motions, leading to an increase or decrease in the coordination number of the metal. In contrast, far less progress has been made in these directions with electron-responsive systems, even though electricity stands as a particularly attractive, controllable, and clean trigger in the perspective of applications in solid-state devices. − The few examples of redox-triggered magnetic switching reported so far in literature are based on Prussian blue analogues or transition-metal complexes exhibiting valence tautomerism. − …”

Section: Introductionmentioning

confidence: 99%

Ni-Centered Coordination-Induced Spin-State Switching Triggered by Electrical Stimulation

et al. 2022

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We herein report the synthesis and magnetic properties of a Ni(II)-porphyrin tethered to an imidazole ligand through a flexible electron-responsive mechanical hinge. The latter is capable of undergoing a large amplitude and fully reversible folding motion under the effect of electrical stimulation. This redox-triggered movement is exploited to force the axial coordination of the appended imidazole ligand onto the square-planar Ni(II) center, resulting in a change in its spin state from low spin (S = 0) to high spin (S = 1) proceeding with an 80% switching efficiency. The driving force of this reversible folding motion is the π-dimerization between two electrogenerated viologen cation radicals. The folding motion and the associated spin state switching are demonstrated on the grounds of NMR, (spectro)electrochemical, and magnetic data supported by quantum calculations.

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Azo-dimethylaminopyridine-functionalized Ni(II)-porphyrin as a photoswitchable nucleophilic catalyst

Cited by 13 publications

References 32 publications

Solid-state photochromic arylazopyrazole-based transition metal complexes

Solid-state photochromic arylazopyrazole-based transition metal complexes

Traffic Lights for Catalysis: Stimuli‐Responsive Molecular and Extended Catalytic Systems

Ni-Centered Coordination-Induced Spin-State Switching Triggered by Electrical Stimulation

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