Here we present a structural design aimed at the control of phosphorescence emission as the result of changes in molecular rotation in a crystalline material. The proposed strategy includes the use of aurophilic interactions, both as a crystal engineering tool and as a sensitive emission probe, and the use of a dumbbell-shaped architecture intended to create a low packing density region that permits the rotation of a central phenylene. Molecular rotor 1, with a central 1,4-diethynylphenylene rotator linked to two gold(I) triphenylphosphane complexes, was prepared and its structure confirmed by single-crystal X-ray diffraction, which revealed chains mediated by dimeric aurophilic interactions. We showed that green-emitting crystals exhibit reversible luminescent color changes between 298 and 193 K, which correlate with changes in rotational motion determined by variable-temperature solid-state H NMR spin-echo experiments. Fast two-fold rotation with a frequency of ca. 4.00 MHz (τ = 0.25 μs) at 298 K becomes essentially static below 193 K as emission steadily changes from green to yellow in this temperature interval. A correlation between phosphorescence lifetimes and rotational frequencies is interpreted in terms of conformational changes arising from rotation of the central phenylene, which causes a change in electronic communication between the gold-linked rotors, as suggested by DFT studies. These results and control experiments with analogue 2, possessing a hindered tetramethylphenylene that is unable to rotate in the crystal, suggest that the molecular rotation can be a useful tool for controlling luminescence in the crystalline state.
AbstractΕniminium ions were prepared from the corresponding α,β‐unsaturated carbonyl compounds (enones and enals), and were found to be promoted to their respective triplet states by energy transfer. The photoexcited intermediates underwent intra‐ or intermolecular [2+2] photocycloaddition in good yields (50–78 %) upon irradiation at λ=433 nm or λ=457 nm. Iridium or ruthenium complexes with a sufficiently high triplet energy were identified as efficient catalysts (2.5 mol % catalyst loading) for the reaction. The intermolecular [2+2] photocycloaddition of an eniminium ion derived from a chiral secondary amine proceeded with high enantioselectivity (88 % ee).
Chiral eniminium salts, prepared from α,β‐unsaturated aldehydes and a chiral proline derived secondary amine, underwent, upon irradiation with visible light, a ruthenium‐catalyzed (2.5 mol %) intermolecular [2+2] photocycloaddition to olefins, which after hydrolysis led to chiral cyclobutanecarbaldehydes (17 examples, 49–74 % yield), with high diastereo‐ and enantioselectivities. Ru(bpz)3(PF6)2 was utilized as the ruthenium catalyst and laser flash photolysis studies show that the catalyst operates exclusively by triplet‐energy transfer (sensitization). A catalytic system was devised with a chiral secondary amine co‐catalyst. In the catalytic reactions, Ru(bpy)3(PF6)2 was employed, and laser flash photolysis experiments suggest it undergoes both electron and energy transfer. However, experimental evidence supports the hypothesis that energy transfer is the only productive quenching mechanism. Control experiments using Ir(ppy)3 showed no catalysis for the intermolecular [2+2] photocycloaddition of an eniminium ion.
Safety culture is often divided into three domains, which include personal, environmental, and behavioral factors. In order to improve the behavioral components of the safety culture in the research group of the authors (the Garcia-Garibay group, or GG research group), we implemented three safety practices intended to sensitize group members on the importance of best practices that depend on simple actions taken by individual researchers. These best practices include (1) a rotating twice-daily safety inspection to enhance an appreciation for the value of safety regulations that may be considered less significant and are frequently overlooked, (2) frequent safety discussions followed by quizzes to give researchers an opportunity to assess their safety knowledge on a range of topics, and (3) the use of an overnight reaction form that is posted on lab entryways as a safety communication best practice to ensure that other researchers in the laboratory and emergency responders are aware of the potential hazards associated with ongoing chemical reactions that do not require continual monitoring. To determine the impact of these measures we analyzed the UCLA Office of Environment, Health and Safety (EH&S) laboratory safety inspection records from the GG research group and compared the findings with those of all other experimental research groups in the Department of Chemistry and Biochemistry at UCLA from the period of 2011 to 2013. We propose that in the absence of any other (either punitive or rewarding) actions, an accelerated improvement in the reduction of the number of inspection findings in the GG research group can be associated with behavioral components of a safety culture addressed by those measures.
We present here dielectric properties and rotational dynamics of cocrystals formed with either triphenylacetic acid (cocrystal I) or 9,10-triptycene dicarboxylic acid (cocrystal II), as hydrogen-bonding donors, and diazabicyclo[2.2.2]octane (DABCO), as a ditopic hydrogen-bond acceptor. While cocrystal I forms discrete 2:1 complexes with one nitrogen of DABCO hydrogen bonded and the other fully proton transferred, cocrystal II consists of 1:1 complexes forming infinite 1-D hydrogen-bonded chains capable of exhibiting a thermally activated response in the form of a broad asymmetric peak at ca. 298 K that extends from ca. 200 to 375 K in both the real and imaginary parts of its complex dielectric. The state of protonation in cocrystal II at 298 and 386 K was established by CPMAS 15N NMR, which showed signals typical of a neutral hydrogen-bonded complex. Taken together, these observations suggest a dielectric response that results from a small population of transient dipoles thermally generated when acidic protons are transiently transferred to either side of the DABCO base. A potential order–disorder transition further explored by taking advantage of the highly sensitive rotational dynamics of the DABCO group using line-shape analysis of solid-state spin echo 2H NMR and 1H NMR T1 spin–lattice relaxation showed no breaks in the Arrhenius plot or Kubo-Tomita 1H T1 fittings, indicating the absence of large structural changes. This was confirmed by variable-temperature single-crystal X-ray diffraction analysis, which showed a fairly symmetric hydrogen bond in cocrystal II at all temperatures, suggesting that both nitrogen atoms may be able to adopt a protonated state.
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