We discuss artificial photonic antenna systems that are built by incorporating chromophores into one-dimensional nanochannel materials and by organizing the latter in specific ways. Zeolite L (ZL) is an excellent host for the supramolecular organization of different kinds of molecules and complexes. The range of possibilities for filling its one-dimensional channels with suitable guests has been shown to be much larger than one might expect. Geometrical constraints imposed by the host structure lead to supramolecular organization of the guests in the channels. The arrangement of dyes inside the ZL channels is what we call the first stage of organization. It allows light harvesting within the volume of a dye-loaded ZL crystal and also the radiationless transport of energy to either the channel ends or center. One-dimensional FRET transport can be realized in these guest-host materials. The second stage of organization is realized by coupling either an external acceptor or donor stopcock fluorophore at the ends of the ZL channels, which can then trap or inject electronic excitation energy. The third stage of organization is obtained by interfacing the material to an external device via a stopcock intermediate. A possibility to achieve higher levels of organization is by controlled assembly of the host into ordered structures and preparation of monodirectional materials. The usually strong light scattering of ZL can be suppressed by refractive-index matching and avoidance of microphase separation in hybrid polymer/dye-ZL materials. The concepts are illustrated and discussed in detail on a bidirectional dye antenna system. Experimental results of two materials with a donor-to-acceptor ratio of 33:1 and 52:1, respectively, and a three-dye system illustrate the validity and challenges of this approach for synthesizing dye-nanochannel hybrid materials for light harvesting, transport, and trapping.
Functionalization
at the α-position of carbonyl compounds
has classically relied on enolate chemistry. As a result, the generation
of a new C–X bond, where X is more electronegative than carbon
requires an oxidation event. Herein we show that, by rendering the
α-position of amides electrophilic through a mild and chemoselective
umpolung transformation, a broad range of widely available oxygen,
nitrogen, sulfur, and halogen nucleophiles can be used to generate
α-functionalized amides. More than 60 examples are presented
to establish the generality of this process, and calculations of the
mechanistic aspects underline a fragmentation pathway that accounts
for the broadness of this methodology.
A new approach for
the synthesis of 1,4-dicarbonyl compounds is
reported. Chemoselective activation of amide carbonyl functionality
and subsequent umpolung viaN-oxide
addition generates an electrophilic enolonium species that can be
coupled with a wide range of nucleophilic enolates. The method conveys
broad functional group tolerance on both components, does not suffer
from formation of homocoupling byproducts and avoids the use of transition
metal catalysts.
Phosphonates have garnered considerable attention for years owing to both their singular biological properties and their synthetic potential. State‐of‐the‐art methods for the preparation of mixed phosphonates, phosphonamidates, phosphonothioates, and phosphinates rely on harsh and poorly selective reaction conditions. We report herein a mild method for the modular preparation of phosphonylated derivatives, several of which exhibit interesting biological activities, that is based on chemoselective activation with triflic anhydride. This procedure enables flexible and even iterative substitution with a broad range of O, S, N, and C nucleophiles.
α‐Amino vinylphosphonates were prepared by chemo‐ and stereoselective reduction of α‐amino allenephosphonates. Our results showed that the substituents on the allene, phosphonate, and nitrogen moieties affected the stereoselectivity of the reduction. Z‐α‐Amino vinylphosphonates were prepared with good selectivities up to > 95:5.
We report a method for the selective α,β‐dehydrogenation of amides in the presence of other carbonyl moieties under mild conditions. Our strategy relies on electrophilic activation coupled to in situ selective selenium‐mediated dehydrogenation. The α,β‐unsaturated products were obtained in moderate to excellent yields, and their synthetic versatility was demonstrated by a range of transformations. Mechanistic experiments suggest formation of an electrophilic SeIV species.
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