Organic Letters: Latest Articles (ACS Publications)
Authors: Andrii Varenikov, Evgeny Shapiro, and Mark Gandelman
feedproxy.google.com/~r/acs/orlef7/~3/hQ2WzQgglbM/acs.orglett.0c03673
The Journal of Organic Chemistry: Latest Articles (ACS Publications)
Authors: Ariela W. Kaspi-Kaneti, Jorge Barroso, Gabriel Merino, David Avnir, Ignacio L. Garzón, and Inbal Tuvi-Arad
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The Journal of Organic Chemistry: Latest Articles (ACS Publications)
Authors: Manickam Bakthadoss and Vishal Agarwal
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Journal of the American Chemical Society: Latest Articles (ACS Publications)
Authors: Majed S. Fataftah, Sam L. Bayliss, Daniel W. Laorenza, Xiaoling Wang, Brian T. Phelan, C. Blake Wilson, Peter J. Mintun, Berk D. Kovos, Michael R. Wasielewski, Songi Han, Mark S. Sherwin, David D. Awschalom, and Danna E. Freedman
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Journal of the American Chemical Society: Latest Articles (ACS Publications)
Authors: Koyel Banerjee-Ghosh, Shirsendu Ghosh, Hisham Mazal, Inbal Riven, Gilad Haran, and Ron Naaman
feedproxy.google.com/~r/acs/jacsat/~3/aYtU7QLz2QU/jacs.0c10105
Journal of the American Chemical Society: Latest Articles (ACS Publications)
Authors: Min-Chih Tang, Yu-Chen Wei, Yen-Chen Chu, Cai-Xin Jiang, Zhi-Xuan Huang, Chi-Chi Wu, Tzu-Hsuan Chao, Pei-Hsun Hong, Mu-Jeng Cheng, Pi-Tai Chou, and Yao-Ting Wu
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Organic Letters: Latest Articles (ACS Publications)
Authors: Ningning Lv, Shuling Yu, Chao Hong, De-Man Han, and Yuhong Zhang
feedproxy.google.com/~r/acs/orlef7/~3/MdWyTD4JbUc/acs.orglett.0c03535
Organic Letters: Latest Articles (ACS Publications)
Authors: Andrii Varenikov, Evgeny Shapiro, and Mark Gandelman
feedproxy.google.com/~r/acs/orlef7/~3/hQ2WzQgglbM/acs.orglett.0c03673
![Bioinspired Divergent Oxidative Cyclization from Strictosidine and Vincoside Derivatives: Second‐Generation Total Synthesis of (−)‐Cymoside and Access to an Original Hexacyclic‐Fused Furo[3,2‐b]indoline](https://d-bernier.fr/wp-content/uploads/2020/11/chem202003758-toc-0001-m.png)
The next generation: The oxidative cyclization of an enantiopure strictosidine derivative leads to the total synthesis of (−)‐cymoside, while the corresponding 3‐epimeric vincoside derivative delivers a new hexacyclic‐fused furo[3,2‐b]indoline framework.
The second‐generation synthesis of (−)‐cymoside as well as the formation of a new hexacyclic‐fused furo[3,2‐b]indoline framework is reported. After a Pictet–Spengler condensation between secologanin tetraacetate and tryptamine, the course of the cyclization of the 7‐hydroxyindolenine intermediate, generated by oxidation with an oxaziridine, depended on the stereochemistry of the 3‐position. The 3‐(S)‐strictosidine stereochemistry delivered efficiently the scaffold of cymoside via intramolecular coupling with the C16–C17 enol ether, while the 3‐(R)‐vincoside stereochemistry directed towards the reaction with the C18–C19 terminal alkene and the formation of the unexpected caged compound.
Wiley: Chemistry – A European Journal: Table of Contents
Authors: Yingchao Dou, Cyrille Kouklovsky, Guillaume Vincent
chemistry-europe.onlinelibrary.wiley.com/doi/abs/10.1002/chem.202003758
Doubly boron‐doped emitters based on a 9,10‐diboraanthracene (DBA) acceptor decorated with ortho‐donor groups were prepared and characterized. These emitters displayed strong thermally activated delayed fluorescence (TADF) with high PLQYs up to 100 %. Highly efficient green‐to‐red TADF‐OLEDs were realized with the emitters.
Doubly boron‐doped thermally activated delayed fluorescence (TADF) emitters based on a 9,10‐diboraanthracene (DBA) acceptor decorated with ortho‐donor groups (Cz2oDBA, 2; BuCz2oDBA, 3; DMAC2oDBA, 4) are prepared to realize high‐efficiency green‐to‐red organic light‐emitting diodes (OLEDs). X‐ray diffraction analyses of 2 and 4 reveal the symmetrical and highly twisted ortho‐donor–acceptor–donor (D‐A‐D) structure of the emitters. The twisted conformation leads to a very small energy splitting (ΔEST <0.08 eV) between the excited singlet and triplet states that gives rise to strong TADF, as supported by theoretical studies. Depending on the strength of the donor moieties, the emission color is fine‐tuned in the visible region from green (2) to yellow (3) to red (4). Carbazole‐containing 2 and 3 exhibit high photoluminescence quantum yields (PLQYs) approaching 100 %, whereas DMAC‐substituted 4 is moderately emissive (PLQY=44 %) in a doped host film. Highly efficient green‐to‐red TADF‐OLEDs are realized with the proposed ortho‐D‐A‐D compounds as emitters. The green and yellow OLEDs incorporating Cz2oDBA (2) and BuCz2oDBA (3) emitters exhibit high external quantum efficiencies (EQEs) of 26.6 % and 21.6 %, respectively. In particular, the green device shows an excellent power efficiency above 100 lm W−1. A red OLED fabricated with a DMAC2oDBA (4) emitter exhibits a maximum EQE of 10.1 % with an electroluminescence peak at 615 nm.
Wiley: Chemistry – A European Journal: Table of Contents
Authors: Ajay Kumar, Han Young Shin, Taehwan Lee, Jaehoon Jung, Byung Jun Jung, Min Hyung Lee
chemistry-europe.onlinelibrary.wiley.com/doi/abs/10.1002/chem.202002968
When one door closes: The post‐metalation modification method is utilized for a two‐step conversion of a dicobalt(III) macrocyclic metallohost. The starting open complex, [LCo2(pip)4]2+, is efficiently converted to the closed complex, [LCo2(hda)2]2+, which is then converted to the open complex [LCo2(hda)2(OAc)]+. The gate‐opening in the second step is dramatically accelerated by the addition of Na+, and the Na+ binding is also significantly enhanced by the gate‐opening.
Host–guest binding behavior of macrocyclic hosts is significantly influenced by the shapes and sizes of the hosts. In particular, closing/opening the apertures of the hosts controls the guest uptake/release. A post‐metalation modification method was used to achieve the open/close conversions. The starting open complex, [LCo2(pip)4](OTf)2, was efficiently converted to the closed complex, [LCo2(hda)2](OTf)2, which has a doubly bridged structure. The conversion of this closed complex to the open complex [LCo2(hda)2(OAc)]+ was too slow to be completed, but this gate‐opening was dramatically accelerated by the addition of Na+. The Na+ binding was also significantly enhanced by the gate‐opening, that is, conversion of [LCo2(hda)2]2+ to [LCo2(hda)2(OAc)]+.
Wiley: Chemistry – A European Journal: Table of Contents
Authors: Yoko Sakata, Masahiro Okada, Shigehisa Akine
chemistry-europe.onlinelibrary.wiley.com/doi/abs/10.1002/chem.202004487
Act later: This innovative work has developed a dimeric model to construct organometallic through‐space charge‐transfer thermally activated delayed fluorescence emitters, as well as single‐component multicolor luminescence, based on two‐coordinate carbene–metal–carbazole complexes.
A series of two‐coordinate AuI and CuI complexes (3 a, 3 b and 5 a, 5 b) are reported as new organometallic thermally activated delayed fluorescence (TADF) emitters, which are based on the carbene–metal–carbazole model with a pyridine‐fused 1,2,3‐triazolylidene (PyTz) ligand. PyTz features low steric hindrance and a low‐energy LUMO (LUMO=−1.47 eV) located over the π* orbitals of the whole ligand, which facilitates intermolecular charge transfer between a donor (carbazole) and an accepter (PyTz). These compounds exhibit efficient TADF with microsecond lifetimes. Temperature‐dependent photoluminescence kinetics of 3 a supports a rather small energy gap between S1 and T1 (ΔE=60 meV). Further experiments reveal that there are dual‐emission properties from a monomer–dimer equilibrium in solution, exhibiting single‐component multicolor emission from blue to orange, including white‐light emission.
Wiley: Chemistry – A European Journal: Table of Contents
Authors: Lei Cao, Shiqing Huang, Wei Liu, Hongyan Zhao, Xiao‐Gen Xiong, Jian‐Ping Zhang, Li‐Min Fu, Xiaoyu Yan
chemistry-europe.onlinelibrary.wiley.com/doi/abs/10.1002/chem.202004106
Layered hydroxides: This study demonstrates how an advanced synthetic method, as the Epoxide Route, allows for the production of well‐defined 2D materials in which the tunable oxidation state of the transition metal cations can be designed and understood on a rational basis, in order to enhance the electrochemical performance of these layered materials.
Co‐ and Ni‐based layered hydroxides constitute a unique class of two‐dimensional inorganic materials with exceptional chemical diversity, physicochemical properties and outstanding performance as supercapacitors and overall water splitting catalysts. Recently, the occurrence of Co(III) in these phases has been proposed as a key factor that enhance their electrochemical performance. However, the origin of this centers and control over its contents remains as an open question. We employed the Epoxide Route to synthesize a whole set of α‐NiCo layered hydroxides. The PXRD and XAS characterization alert about the occurrence of Co(III) as a consequence of the increment in the Ni content. DFT+U simulation suggest that the shortening of the Co−O distance promotes a structural distortion in the Co environments, resulting in a double degeneration in the octahedral Co 3d orbitals. Hence, a strong modification of the electronic properties leaves the system prone to oxidation, by the appearance of Co localized electronic states on the Fermi level. This work combines a microscopic interpretation supported by a multiscale crystallochemical analysis, regarding the so‐called synergistic redox behavior of Co and Ni, offering fundamental tools for the controllable design of highly efficient electroactive materials. To the best of our knowledge, this is the first computational–experimental investigation of the electronic and structural details of α‐NiCo hydroxides, laying the foundation for the fine tuning of electronic properties in layered hydroxides.
Wiley: Chemistry – A European Journal: Table of Contents
Authors: Diego Hunt, Víctor Oestreicher, Martín Mizrahi, Félix G. Requejo, Matías Jobbágy
chemistry-europe.onlinelibrary.wiley.com/doi/abs/10.1002/chem.202001944
In the presence of luminescent [Pt(O^N^C^N)] complexes under visible light (410 nm) irradiation, aryl radicals derived from reductive aryl‐chloride/bromide bond cleavage were trapped by aryl alkenes and afforded a series of anti‐Markonikov hydroarylated compounds. [Pt(O^N^C^N)]‐catalyzed intramolecular photocyclization of acrylanilides gives structurally diverse 3,4‐dihydroquinolinones.
Photoinduced hydroarylation of alkenes is an appealing synthetic strategy for arene functionalization. Herein, we demonstrated that aryl radicals generated from electron‐deficient aryl chlorides/bromides could be trapped by an array of terminal/internal aryl alkenes in the presence of [Pt(O^N^C^N)] under visible‐light (410 nm) irradiation, affording anti‐Markonikov hydroarylated compounds in up to 95 % yield. Besides, a protocol for [Pt(O^N^C^N)]‐catalyzed intramolecular photocyclization of acrylanilides to give structurally diverse 3,4‐dihydroquinolinones has been developed.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Hanchao Cheng, Tsz‐Lung Lam, Yungen Liu, Zhou Tang, Chi‐Ming Che
doi.org/10.1002/anie.202011841
Currently, no calorimeters that are biocompatible and operate homogeneously are available. Herein, a new approach for the design of molecular calorimeters: an approach based on deliberate control over folding/unfolding rates in nucleic acid scaffolds is reported. The biocompatible calorimeters that operate homogeneously will reveal a new layer of information on molecular interactions in small open systems.
Thermodynamic characterization is crucial for understanding molecular interactions. However, methodologies for measuring heat changes in small open systems are extremely limited. We document a new approach for designing molecular sensors, that function as calorimeters: sensors based on memory. To design a memory‐based sensor, we take advantage of the unique kinetic properties of nucleic acid scaffolds. Particularly, we elaborate on the differences in folding and unfolding rates in nucleic acid quadruplexes. DNA‐based i‐motifs unfold fast in response to small heats but do not fold back when the system is equilibrated with surroundings. We translated this behavior into a molecular memory function that enables the measurement of heat changes in open environments. The new sensors are biocompatible, operate homogeneously, and measure small heats released over long time periods. As a proof‐of‐concept, we demonstrate how the molecular calorimeters report heat changes generated in water/propanol mixing and in ligand/protein binding.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Obianuju A. Nwokolo, Brant Kidd, Te’Kara Allen, Alexander S. Minasyan, Suchitra Vardelly, Kristopher D. Johnson, Irina V. Nesterova
doi.org/10.1002/anie.202011422
Under a proton acid/N‐chlorophthalimide (NCPI) system, two classes of important non‐aromatic heterocycles (1,3‐oxathiol‐2‐imine and thiazol‐2(3H)‐one) are selectively obtained from alkynes, isothiocyanates, and water by slightly changing the reaction conditions. Readily available starting materials, broad substrate scope, gram‐scale synthesis, late‐stage modification, and the potential of 1,3‐oxathiol‐2‐imine derivatives as Pd2+ sensors demonstrate the utility of this method.
A multicomponent strategy to achieve two different regioselectivities from alkynes, isothiocyanates and H2O with a proton acid/N‐chlorophthalimide (NCPI) system is described to selectively obtain non‐aromatic five‐membered sulfur heterocycles (1,3‐oxathiol‐2‐imines/thiazol‐2(3H)‐one derivatives) through multiple bond formations. The process features readily available starting materials, mild reaction conditions, broad substrate scope, good functional‐group tolerance, high regio‐ and chemo‐ selectivities, gram‐scale synthesis and late‐stage modifications. Mechanistic studies support the proposal that the transformation process includes a combination of H2O and isothiocyanate, free‐radical formation, carbonation and intramolecular cyclization to give the products. Furthermore, the 1,3‐oxathiol‐2‐imine derivatives possess unique fluorescence characteristics and can be used as Pd2+ sensors with a “turn‐off” response, demonstrating potential applications in environmental and biological fields.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Wentao Yu, Baiyao Zhu, Fuxing Shi, Peiqi Zhou, Wanqing Wu, Huanfeng Jiang
doi.org/10.1002/anie.202010889
The solvatochromic fluorescence properties of a subporphyrazine are used to control the rate of intramolecular Förster resonance energy transfer (i‐FRET) in a subporphyrazine–pentacene conjugate (SubPzPnc2) that undergoes intramolecular singlet fission (i‐SF). A simple selection of solvent serves to optimize the triplet quantum yield by enhancing the spectral overlap between the fluorescence of the SubPz and the absorption of the Pnc dimer.
Due its complementary absorptions in the range of 450 and 600 nm, an energy‐donating hexaaryl‐subporphyrazine has been linked to a pentacene dimer, which acts primarily as an energy acceptor and secondarily as a singlet fission enabler. In the corresponding conjugate, efficient intramolecular Förster resonance energy transfer (i‐FRET) is the modus operandi to transfer energy from the subporphyrazine to the pentacene dimer. Upon energy transfer, the pentacene dimer undergoes intramolecular singlet fission (i‐SF), that is, converting the singlet excited state, via an intermediate state, into a pair of correlated triplet excited states. Solvatochromic fluorescence of the subporphyrazine is a key feature of this system and features a red‐shift as large as 20 nm in polar media. Solvent is thus used to modulate spectral overlap between the fluorescence of subporphyrazine and absorption of the pentacene dimer, which controls the Förster rate constant, on one hand, and the triplet quantum yield, on the other hand. The optimum spectral overlap is realized in xylene, leading to Förster rate constant of 3.52×1011 s−1 and a triplet quantum yield of 171 % ±10 %. In short, the solvent polarity dependence, which is a unique feature of subporphyrazines, is decisive in terms of adjusting spectral overlap, ensuring a sizable Förster rate constant, and maximizing triplet quantum yields. Uniquely, this optimization can be achieved without a need for synthetic modification of the subporphyrazine donor.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: David Guzmán, Ilias Papadopoulos, Giulia Lavarda, Parisa R. Rami, Rik R. Tykwinski, M. Salomé Rodríguez‐Morgade, Dirk M. Guldi, Tomás Torres
doi.org/10.1002/anie.202011197
A new type of metallo‐polymer with helicoidal structure was constructed through the combination of covalent polymerization and intramolecular coordination‐driven self‐assembly. Owing to the positive charges on the inner rim of helicoid, double‐stranded DNA molecules (dsDNA) could interact with metallo‐helicoid (H) via electrostatic interactions. Notably, dsDNA allowed exclusive formation of H with right handedness by means of chiral induction.
In this study, we established a feasible strategy to construct a new type of metallo‐polymer with helicoidal structure through the combination of covalent polymerization and intramolecular coordination‐driven self‐assembly. In the design, a tetratopic monomer (M) was prepared with two terminal alkynes in the outer rim for polymerization, and two terpyridines (TPYs) in the inner rim for subsequent folding by selective intramolecular coordination. Then, the linear covalent polymer (P) was synthesized by polymerization of M via Glaser‐Hay homocoupling reaction. Finally, intramolecular coordination interactions between TPYs and Zn(II) folded the backbone of P into a right‐ or left‐handed metallo‐helicoid (H) with double rims. Owing to multiple positive charges on the inner rim of helicoid, double‐stranded DNA molecules (dsDNA) could interact with H through electrostatic interactions. Remarkably, dsDNA allowed exclusive formation of H with right handedness by means of chiral induction.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Guang‐Qiang Yin, Sneha Kandapal, Chung‐Hao Liu, Heng Wang, Jianxiang Huang, Shu‐Ting Jiang, Tan Ji, Yu Yan, Sandra Khalife, Ruhong Zhou, Libin Ye, Bingqian Xu, Hai‐Bo Yang, Mu‐Ping Nieh, Xiaopeng Li
doi.org/10.1002/anie.202010696
Panchromatic push–pull systems comprised of one or two entities of high‐energy absorbing TPAδ+‐TCBDδ− charge‐transfer complexes covalently linked to a near‐IR sensitizer, azaBODIPY, have been synthesized. Excited‐state electron transfer upon CT or near‐IR excitation is demonstrated.
Push–pull systems comprising of triphenylamine–tetracyanobutadiene (TPA‐TCBD), a high‐energy charge‐transfer species, are linked to a near‐IR sensitizer, azaBODIPY, for promoting excited‐state CS. These systems revealed panchromatic absorption owing to intramolecular CT and near‐IR absorbing azaBODIPY. Using electrochemical and computational studies, energy levels were established to visualize excited state events. Fs‐TA studies were performed to monitor excited state CT events. From target analysis, the effect of solvent polarity, number of linked CT entities, and excitation wavelength dependence in governing the lifetime of CS states was established. Electron exchange between two TPA‐TCBD entities in 3 seem to prolong lifetime of the CS state. We have been successful in demonstrating efficient CS upon both high‐energy CT and low‐energy near‐IR excitations, signifying importance of these push–pull systems for optoelectronic applications operating in the wide optical window.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Dilip Pinjari, Ajyal Z. Alsaleh, Yuvraj Patil, Rajneesh Misra, Francis D’Souza
doi.org/10.1002/anie.202013036
Dynamics in complexes of porphyrin cage compounds and viologen‐derived guest molecules are investigated by selective exchange NMR spectroscopy (1D EXSY). These studies explore the mechanism of host–guest exchange, how steric and electronic properties influence the rate of exchange, and whether the exchange process is governed by kinetic or thermodynamic factors.
Dynamics in complexes of porphyrin cage compounds and viologen‐derived guest molecules are investigated by selective exchange NMR spectroscopy (1D EXSY). Exchange rates were found to be independent of excess guest concentration, revealing a dissociative exchange mechanism, which is accompanied by negative activation entropies, indicating significant reorganization of the host–guest complex during dissociation. Nonsymmetric viologen guests with bulky head groups had more unidirectional binding and slower exchange rates than guests with less‐bulky head groups. Thermodynamic and kinetic studies revealed that the exchange process is primarily driven by the thermodynamics of binding and that guest binding can be influenced by introducing steric and electronic groups on the host . Exchange studies with guests bearing a polymer chain revealed that both slippage and full dissociation takes place and the rate constants for both processes were determined. The slippage rate constant revealed that for smaller guests exchange takes place nearly exclusively under thermodynamic control.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Anne Swartjes, Paul B. White, Marijn Lammertink, Johannes A. A. W. Elemans, Roeland J. M. Nolte
doi.org/10.1002/anie.202010335
The twin‐bromodomain‐containing BET proteins, BRD2‐4 and T, are important drug targets for inflammation, cancer, and heart disease. However, potent and selective inhibitors for a single BET bromodomain are lacking. Here we describe the structure‐based design of inhibitors with preferred binding for the first bromodomain of BRD4, and provide design rules for future inhibitors. Cell‐based studies identify differential effects relative to pan‐BET inhibitors.
Bromodomain and extra‐terminal (BET) family proteins, BRD2‐4 and T, are important drug targets; however, the biological functions of each bromodomain remain ill‐defined. Chemical probes that selectively inhibit a single BET bromodomain are lacking, although pan inhibitors of the first (D1), and second (D2), bromodomain are known. Here, we develop selective BET D1 inhibitors with preferred binding to BRD4 D1. In competitive inhibition assays, we show that our lead compound is 9–33 fold selective for BRD4 D1 over the other BET bromodomains. X‐ray crystallography supports a role for the selectivity based on reorganization of a non‐conserved lysine and displacement of an additional structured water in the BRD4 D1 binding site relative to our prior lead. Whereas pan‐D1 inhibitors displace BRD4 from MYC enhancers, BRD4 D1 inhibition in MM.1S cells is insufficient for stopping Myc expression and may lead to its upregulation. Future analysis of BRD4 D1 gene regulation may shed light on differential BET bromodomain functions.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Huarui Cui, Anand Divakaran, Anil K. Pandey, Jorden A. Johnson, Huda Zahid, Zachariah J. Hoell, Mikael O. Ellingson, Ke Shi, Hideki Aihara, Daniel A. Harki, William C. K. Pomerantz
doi.org/10.1002/anie.202008625
An enantioselective protonation through hydrophosphinylation of diarylphosphine oxides with 2‐vinyl azaheterocycle N‐oxide derivatives was demonstrated using chiral bis(guanidino)iminophosphorane. The enantioselective protonation by a weak conjugate acid generated from the higher‐order organosuperbase is promising in enantioselective catalysis because of the utilization of less acidic pronucleophiles.
Enantioselective protonation by hydrophosphinylation of diarylphosphine oxides with 2‐vinyl azaheterocycle N‐oxide derivatives was demonstrated using chiral bis(guanidino)iminophosphorane as the higher‐order organosuperbase catalyst. It was confirmed by several control experiments that a chiral weak conjugate acid of the chiral bis(guanidino)iminophosphorane, instead of achiral diarylphosphine oxides, directly functioned as the proton source to afford the corresponding product in a highly enantioselective manner in most cases. Enantioselective protonation by a weak conjugate acid generated from the higher‐order organosuperbase would broaden the scope of enantioselective reaction systems because of utilization of a range of less acidic pronucleophiles. This method is highlighted by the valuable synthesis of a series of chiral P,N‐ligands for chiral metal complexes through the reduction of phosphine oxide and N‐oxide units of the corresponding product without loss of enantiomeric purity.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Saikat Das, Qiupeng Hu, Azusa Kondoh, Masahiro Terada
doi.org/10.1002/anie.202012492
1,2‐Alkynylallylation of a specific C−C σ bond in cyclopropenes was realized by a simple, neutral, low‐cost palladium catalytic system with high TONs. This decarboxylative reorganization reaction is an efficient way to construct highly functionalized dienynes in excellent regio‐ and stereoselectivity. A nonclassical β‐C elimination promoted by 1,4‐palladium migration was described herein for the first time.
A Pd‐catalyzed regio‐ and stereoselective alkynylallylation of a specific C−C σ bond in cyclopropenes, using allyl propiolates as both allylation and alkynylation reagents, has been achieved for the first time. By merging selective C(sp2)‐C(sp3) bond scission with conjunctive cross‐couplings, this decarboxylative reorganization reaction features fascinating atom and step economy and provides an efficient approach to highly functionalized dienynes from readily available substrates. Without further optimization, gram‐scale products can be easily obtained by such a simple, neutral, and low‐cost catalytic system with high TONs. DFT calculations afford a rationale toward the formation of the products and indicate that the selective insertion of the double bond of cyclopropenes into the C‐Pd bond of ambidentate Pd complex and the subsequent nonclassical β‐C elimination promoted by 1,4‐palladium migration are critical for the success of the reaction.
Wiley: Angewandte Chemie International Edition: Table of Contents
Authors: Zeqi Jiang, Sheng‐Li Niu, Qiang Zeng, Qin Ouyang, Ying‐Chun Chen, Qing Xiao
doi.org/10.1002/anie.202008886
Organic Letters: Latest Articles (ACS Publications)
Authors: Quynh Thuy Le, Lihui Guo, Seung Lyeol Lee, Junseong Lee, and Chang Ho Oh
feedproxy.google.com/~r/acs/orlef7/~3/oxVrd9U_T10/acs.orglett.0c03415
Organic Letters: Latest Articles (ACS Publications)
Authors: Emilie Wheatley, Joseph M. Zanghi, and Simon J. Meek
feedproxy.google.com/~r/acs/orlef7/~3/NG3rOBe5SlA/acs.orglett.0c03495
