Photochemical α-Aminonitrile Synthesis Using Zn-Phthalocyanines as Near-Infrared Photocatalysts

Abstract: While photochemical transformations with sunlight almost exclusively utilize the UV–vis part of the solar spectrum, the majority of the photons emitted by the sun have frequencies in the near-infrared region. Phthalocyanines show high structural similarity to the naturally occurring light-harvesting porphyrins, chlorins, and mainly bacteriochlorins and are also known for being efficient and affordable near-infrared light absorbers as well as triplet sensitizers for the production of singlet oxygen. Although ha… Show more

“…With their photoactive 3 ILCT excited states, both [Zn­( m -L) 2 ] and [Zn­( p -L) 2 ] should in principle be able to sensitize triplet–triplet annihilation upconversion, which is an attractive process for the conversion of low-energy input light into higher energy output radiation. ,− In particular, upconversion from the visible to the ultraviolet spectral region has received increasing interest lately, − and our Zn II complexes with their relatively high 3 ILCT energies seemed promising for this purpose. Previous upconversion studies with Zn II sensitizers focused on red-to-blue upconversion and on near-infrared sensitization of photochemical reactions. − We identified the combination of [Zn­( m -L) 2 ] and (TMS) 2 napht (Figure e) as particularly promising for blue to UV upconversion. Unsubstituted naphthalene has a triplet energy of 2.62 eV, which is too high for both our Zn II complexes (Figure ).…”

“…Previous upconversion studies with Zn II sensitizers focused on red-to-blue upconversion and on near-infrared sensitization of photochemical reactions. 103 − 106 We identified the combination of [Zn( m -L) 2 ] and (TMS) 2 napht ( Figure 8 e) as particularly promising for blue to UV upconversion. Unsubstituted naphthalene has a triplet energy of 2.62 eV, 84 which is too high for both our Zn II complexes ( Figure 4 ).…”

Zinc(II) Complexes with Triplet Charge-Transfer Excited States Enabling Energy-Transfer Catalysis, Photoinduced Electron Transfer, and Upconversion

“…With their photoactive 3 ILCT excited states, both [Zn­( m -L) 2 ] and [Zn­( p -L) 2 ] should in principle be able to sensitize triplet–triplet annihilation upconversion, which is an attractive process for the conversion of low-energy input light into higher energy output radiation. ,− In particular, upconversion from the visible to the ultraviolet spectral region has received increasing interest lately, − and our Zn II complexes with their relatively high 3 ILCT energies seemed promising for this purpose. Previous upconversion studies with Zn II sensitizers focused on red-to-blue upconversion and on near-infrared sensitization of photochemical reactions. − We identified the combination of [Zn­( m -L) 2 ] and (TMS) 2 napht (Figure e) as particularly promising for blue to UV upconversion. Unsubstituted naphthalene has a triplet energy of 2.62 eV, which is too high for both our Zn II complexes (Figure ).…”

“…Previous upconversion studies with Zn II sensitizers focused on red-to-blue upconversion and on near-infrared sensitization of photochemical reactions. 103 − 106 We identified the combination of [Zn( m -L) 2 ] and (TMS) 2 napht ( Figure 8 e) as particularly promising for blue to UV upconversion. Unsubstituted naphthalene has a triplet energy of 2.62 eV, 84 which is too high for both our Zn II complexes ( Figure 4 ).…”

Zinc(II) Complexes with Triplet Charge-Transfer Excited States Enabling Energy-Transfer Catalysis, Photoinduced Electron Transfer, and Upconversion

“…The number of photocatalysts with suitable absorption properties in the red spectral range is somewhat limited, 31,[69][70][71][72] and we chose a well-known polypyridyl complex of osmium(II) from as class of robust sensitizers that have been used successfully for triplet-triplet annihilation previously. [73][74][75][76][77][78][79] In combination with DCA, the change from [Cu(dap) 2 ] + to [Os(bpy) 3 ] 2+ as a primary light absorber completely alters the photochemical reactivity of the system.…”

Sensitizer-controlled photochemical reactivityviaupconversion of red light

“…16 Consequently, they have been widely studied as photosensitizers in photodynamic therapy; however, they are only occasionally used as photocatalysts in red-light-induced processes. 13 Along this line, subphtalocyanines and phtalocyanines proved effective in the perfluoroalkylation of alkenes and alkynes, 17−19 the cyanation of tertiary amines, 19 and the photoreductive dehalogenation of α-bromo ketones. 20 The advantage of using porphyrinoids as photoredox catalysts was recently demonstrated by the MacMillan group, who developed a proximity labeling platform based on a red-lightexcited Sn(IV) chlorin e6 that enabled the generation of aminyl radicals both in vitro and in cellulo.…”

Porphyrins as Promising Photocatalysts for Red-Light-Induced Functionalizations of Biomolecules