Iron(II) Complexes of Chiral Tridentate Nitrogen Donors and their Application in Catalytic Hydrosilylation Reactions

Enantiomerically pure, C₂-symmetric 2,6-bis(pyrazol-3-yl) pyridine ligands were obtained by treatment of diethyl-2,6-pyridinedicarbonate with (1R,4R)-(+)-camphor in the presence of NaH followed by ring closure with hydrazine. After twofold N-alkylation at the pyrazole rings, the addition of iron(II) chloride led to the according pentacoordinate dichloridoiron(II) complexes. All intermediates of the ligand synthesis, the ligands bearing NCH₃ and NCH₂C₆H₅ groups and the derived iron(II) complexes were structurally characterized by means of X-ray structure analysis. In-situ reaction with iron(II) carboxylates resulted in the formation of iron(II) carboxylate complexes, which turned out to be highly active in the hydrosilylation of acetophenone. However, even at room temperature, the enantiomeric excess of the product 1-phenylethanol is poor. ⁵⁷Fe Mössbauer spectroscopy gave an insight into the species formed during catalysis.     

Supramolecular Block Copolymers from Tricarboxamides. Biasing Co-assembly by the Incorporation of Pyridine Rings

The synthesis of a series of triangular-shaped tricarboxamides endowed with three picoline or nicotine units (compounds 2 and 3 , respectively) or just one nicotine unit (compound 4 ) is reported, and their self-assembling features investigated. The pyridine rings make compounds 2 – 4 electronically complementary with our previously reported oligo(phenylene ethynylene)tricarboxamides (OPE-TA) 1 to form supramolecular copolymers. C₃-symmetric tricarboxamide 2 forms highly stable intramolecular five-membered pseudocycles that impede its supramolecular polymerization into poly-2 and the co-assembly with 1 to yield copolymer poly-1-co-2 . On the other hand, C₃-symmetric tricarboxamide 3 readily forms poly-3 with great stability but unable to form helical supramolecular polymers despite the presence of the peripheral chiral side chains. The copolymer poly-1-co-3 can only be obtained by a previous complete disassembly of the constitutive homopolymers in CHCl₃. Helical poly-1-co-3 arises in a process involving the transfer of the helicity from racemic poly-1 to poly-3 , and the amplification of asymmetry from chiral poly-3 to poly-1 . Importantly, C_2v-symmetric 4 , endowed with only one nicotinamide moiety and three chiral side chains, self-assembles into a P-type helical supramolecular polymer ( poly-4 ) in a thermodynamically controlled cooperative process. The combination of poly-1 and poly-4 generates chiral supramolecular copolymer poly-1-co-4 , whose blocky microstructure has been investigated by applying the previously reported supramolecular copolymerization model.     

Palladium complexes of bis(acyclic diaminocarbene) ligands with chiral N-substituents and 8-membered chelate rings

Reaction of cis-dichloridobis(p-trifluoromethylphenylisocyanide)palladium(II) with N,N′-bis[(R)-1-phenylethyl]-1,3-diaminopropane afforded an enantiomerically pure, C₁-symmetric bis(acyclic diaminocarbene)PdCl₂ complex in 41% yield. The X-ray crystal structure of the complex revealed that three of the four carbene nitrogens are twisted out of conjugation with the carbene units, apparently as a result of steric interactions between one phenyl group and the propylene backbone of the chelate. A similar reaction with N,N′-bis[(R)-1-(1-naphthyl)ethyl]-1,3-diaminopropane did not lead to an isolable bis(carbene) complex, instead forming significant amounts of bis(ammonium) salt as a decomposition product. However, reaction of the same palladium isocyanide precursor with a mixture of all diastereomers of N,N′-bis[1-(1-naphthyl)ethyl]-1,3-diaminopropane provided an achiral, C_s-symmetric palladium bis(acyclic diaminocarbene) complex derived exclusively from the (R,S) diamine in 20% yield. An X-ray structure showed that the (R,S) stereochemistry allows the bulky naphthyl groups to adopt an orientation that avoids steric interactions with the backbone that likely lead to the instability of the homochiral analogue. The two palladium carbene complexes catalyzed the aza-Claisen rearrangement of an allylic imidate to an allylic amide in 24–34% yield, with an enantiomeric excess of 8% ee for the [(R)-1-phenylethyl]-substituted complex.     

2,5‐O‐Methyl­ene‐d‐mannitol: two polymorphs and the NaI complex

Two polymorphs of the title compound, (4R,5R,6R,7R)‐4,7‐bis­(hydroxy­methyl)‐1,3‐dioxepane‐5,6‐diol, C₇H₁₄O₆, both have Z′ = 2 at 100 K, and differ in their hydrogen‐bonding patterns. The sodium iodide complex, NaI·C₇H₁₄O₆, is isomorphous with the NaCl complex, and has the mannitol, cation and anion all lying on twofold axes. The dioxepane rings of all three mol­ecules are in the twist‐chair conformation.     

Two-directional synthesis of the non-adjacent bis(tetrahydrofuran) core of cis-sylvaticin

Synthesis of the C₂-symmetric, non-adjacent bis(tetrahydrofuran) core of cis-sylvaticin in seven steps and 24% overall yield from (2R,3S)-1,2-epoxy-4-penten-3-ol is reported. A strategy involving assembly of the central 1,4-diol unit by silicon-tethered ring-closing metathesis and subsequent two-directional functionalization, including establishment of the cis/threo stereochemical relationships of the tetrahydrofuran rings by Sharpless asymmetric dihydroxylation/S_N2 cyclization, is employed.     

Hierarchical Microtubular Covalent Organic Frameworks Achieved by COF-to-COF Transformation

Pore environment and aggregated structure play a vital role in determining the properties of porous materials, especially regarding the mass transfer. Reticular chemistry imparts covalent organic frameworks (COFs) with well-aligned micro/mesopores, yet constructing hierarchical architectures remains a great challenge. Herein, we reported a COF-to-COF transformation methodology to prepare microtubular COFs. In this process, the C₃-symmetric guanidine units decomposed into C₂-symmetric hydrazine units, leading to the crystal transformation of COFs. Moreover, the aggregated structure and conversion degree varied with the reaction time, where the hollow tubular aggregates composed of mixed COF crystals could be obtained. Such hierarchical architecture leads to enhanced mass transfer properties, as proved by the adsorption measurement and chemical catalytic reactions. This self-template strategy was successfully applied to another four COFs with different building units.     

(4‐Nitrophenylsulfanylmethyl)triphenylstannane and (4‐nitrophenylsulfonylmethyl)triphenylstannane: R(X) rings (X is 10, 18 or 24) and C—H⋯π interactions

In the crystal structures of (4‐nitro­phenyl­sulfanyl­methyl)­tri­phenyl­stannane, [Sn(C₆H₅)₃(C₇H₆NO₂S)], (I), and (4‐nitro­phenyl­sulfonyl­methyl)­tri­phenyl­stannane, [Sn(C₆H₅)₃­(C₇H₆NO₄S)], (II), the mol­ecules are linked by paired C—H?O hydrogen bonds into centrosymmetric dimers which combine to form sheets. In (I), two such dimers form to give R(10) and R(24) rings. In (II), similar dimers form, here with R(10) and R(18) rings, but with an additional dimer due to the presence of the sulfone group, giving R(10) rings. In both structures, C—H?π interactions lead to a doubling of the width of the sheets.     

Rasagiline ethanedisulfonate: an inhibitor for monoamine oxygenase B (MAOB)

Rasagiline is a selective and potent drug used for the treatment of Parkinson's disease. The first crystal structure of a salt of rasagiline, the title compound, bis[(1R)‐N‐prop‐2‐ynyl‐2,3‐dihydro‐1H‐inden‐1‐aminium] ethanedisulfonate, 2C₁₂H₁₄N⁺·C₂H₄O₆S₂⁻, was determined from crystals grown by gas diffusion. The compound has monoclinic (C2) symmetry. The ethane group of the ethanedisulfonate anion is disordered over three positions. The C₂‐symmetric ethanedisulfonate anions are connected by four N—H...O hydrogen bonds to four rasagiline cations. This leads to large 18‐membered rings which are arranged in ladders in the [010] direction. The extended hydrogen‐bonding architecture may explain the stability of the structure. Rasagiline ethanedisulfonate is nonhygroscopic. During a polymorph screen, no hydrates, solvates or polymorphs were found.     

3‐Nitrophenol–4,4′‐bipyridyl N,N′‐dioxide (2/1): a DFT study and CSD analysis of DPNO molecular complexes

The title 2:1 complex of 3‐nitrophenol (MNP) and 4,4′‐bipyridyl N,N′‐dioxide (DPNO), 2C₆H₅NO₃·C₁₀H₈N₂O₂ or 2MNP·DPNO, crystallizes as a centrosymmetric three‐component adduct with a dihedral angle of 59.40 (8)° between the planes of the benzene rings of MNP and DPNO (the DPNO moiety lies across a crystallographic inversion centre located at the mid‐point of the C—C bond linking its aromatic rings). The complex owes its formation to O—H...O hydrogen bonds [O...O = 2.605 (3) Å]. Molecules are linked by intermolecular C—H...O and C—H...N interactions forming R₂¹(6) and R₂²(10) rings, and R₆⁶(34) and R₄⁴(26) macro‐rings, all of which are aligned along the [01] direction, and R₂²(10) and R₂¹(7) rings aligned along the [010] direction. The combination of chains of rings along the [01] and [010] directions generates the three‐dimensional structure. A total of 27 systems containing the DNPO molecule and forming molecular complexes of an organic nature were analysed and compared with the structural characteristics of the dioxide reported here. The N—O distance [1.325 (2) Å] depends not only on the interactions involving the O atom at the N—O group, but also on the structural ordering and additional three‐dimensional interactions in the crystal structure. A density functional theory (DFT) optimized structure at the B3LYP/6‐311G(d,p) level is compared with the molecular structure in the solid state.     

The natural diterpenoid kamebanin

Kamebanin, alternatively called rel‐(?)‐(1R,4R,8S,9R,10S,13S,16R)‐2,8,16‐tri­hydroxy‐5,5,9‐tri­methyl‐14‐methyl­enetetra­cyclo­[11.2.1.0^1,10.0^4,9]­hexadecan‐15‐one, C₂₀H₃₀O₄, is a natural diterpenoid which has cytotoxic and antibacterial activity. The mol­ecule is composed of three six‐membered rings, which all adopt chair conformations, and one five‐membered ring, which adopts an envelope conformation. The conjugated α‐­methyl­ene­cyclo­pentanone ring is the active part in the mol­ecule due to the ring strain. All three hydroxy groups serve as hydrogen‐bond donors and acceptors, forming a continuous two‐dimensional network.     

Bis­[(R)‐3,5‐di­chloro‐N‐(1‐phenyl­ethyl)­salicyl­idene­aminato‐κ2N,O]­copper(II) and bis­[(R)‐3‐ethoxy‐N‐(1‐phenyl­ethyl)­salicyl­idene­aminato‐κ2N,O]copper(II)

The title compounds, [Cu(C₁₅H₁₂Cl₂NO)₂], (I), and [Cu(C₁₇­H₁₈NO₂)₂], (II), both adopt a compressed tetrahedral trans‐[CuN₂O₂] coordination geometry, the mol­ecules having an umbrella conformation overall. These complexes differ from one another with respect to the 1‐phenyl­ethyl­amine moieties, the direction of the benzene rings being either inside [in (I)] or inside and outside [in (II)] of the mol­ecules. The crystals of (I) and (II) have Δ(R,R) and Λ(R,R) absolute configurations, respectively.     

Self-assembly of tris(2-ureidobenzyl)amines with <Emphasis Type="Italic">C</Emphasis><Subscript>1</Subscript> symmetry

Abstract  

Tris(2-ureidobenzyl)amines bearing three differentially substituted arms have been synthesized. They possess an asymmetric nitrogen atom, the pivotal one, and thus they feature C ₁ symmetry. The self-assembly of these C ₁-symmetric tris(2-ureidobenzyl)amines may potentially lead to multiple regio- and diastereoisomeric capsules coming from the pairing of the four stereoisomeric monomers with configurations (R, P), (S, P), (R, M) and (S, M). The ¹H- and ¹⁹F{¹H}-NMR spectra confirm the presence of dimeric aggregates, as a mixture of several regio- and diastereoisomeric species.     

Regioselective cleavage of the bis-benzylidene acetal of d-mannitol under oxidative and reductive conditions: a new approach to C2-symmetric chiral ligands

A highly regioselective oxidative cleavage of 1,3:4,6-di-O-benzylidene-d-mannitol was carried out using NBS and the resultant product was readily converted to the C₂-symmetric chiral ligand, (R,R)-3,4-dihydroxy-1,5-hexadiene. On the other hand, reductive cleavage of 1,3:4,6-di-O-benzylidene-d-mannitol was achieved in a highly regioselective manner using BF₃·OEt₂ and Et₃SiH to give a highly functionalized benzyl ether, which was converted to a synthetically useful C₂-symmetric bis-amino alcohol derivative.     

Chiroptical and conformational properties of (R)-1-phenylethylamine derivatives of persubstituted benzene

Chiral derivatives of 2,4,5,6-tetrachloro-1,3-dicyanobenzene 1 with one, two and three (R)-1-phenylethylamino ((R)-PEA) units 2–4 are prepared and their chiroptical and conformational properties discussed on the bases of the UV/CD, NMR and MM2 data. High polarity of the persubstituted benzene ring leads to peculiar UV and IR spectra of achiral model compounds 5–7, whereas relatively rigid conformations of the chiral analogues 2–4 are reflected in the CD spectra. Strong exciton coupling (EC) appears in the CD spectrum of pseudo-C₃-symmetric 4; this type of interaction seems not to be present in the C₁-symmetric 2 and C₂-symmetric 3. The absence of a molecular cleft in the chiral structures 2–4 could explain their inability to recognise the enantiomers of some racemates in the NMR experiment.     

Synthesis of C 1- and C 3ν-Symmetric Porphyrin Trimers Based on Triphenylmethane Cores

Summary.  This work describes the synthesis of a new class of tripodaphyrin derivatives with a triphenylmethane core. Both C ₁- and C _3ν-symmetric tetrahedral large molecules with covalently linked rigid elements were obtained.     

Synthesis of the non-adjacent bis(tetrahydrofuran) core of squamostanin C by silicon-tethered,size-selective triple ring-closing metathesis

Synthesis of the C₂-symmetric, non-adjacent bis(tetrahydrofuran) core of squamostanin C in seven steps and 24% overall yield from (R,R)-1,5-hexadiene-3,4-diol is reported. Silicon-tethered, size-selective triple ring-closing metathesis of an acyclic hexaene is employed for assembly of the central 1,4-diol unit and concurrent chain extension via lactone formation. Stereoselective construction of both tetrahydrofuran rings is achieved in one step through the use of two-directional Mukaiyama aerobic alkenol cyclization.     

Channel‐forming solvates of 6‐chloro‐2,5‐dihydroxypyridine and its solvent‐free tautomer 6‐chloro‐5‐hydroxy‐2‐pyridone

On crystallization from CHCl₃, CCl₄, CH₂ClCH₂Cl and CHCl₂CHCl₂, 6‐chloro‐5‐hydroxy‐2‐pyridone, C₅H₄ClNO₂, (I), undergoes a tautomeric rearrangement to 6‐chloro‐2,5‐dihydroxypyridine, (II). The resulting crystals, viz. 6‐chloro‐2,5‐dihydroxypyridine chloroform 0.125‐solvate, C₅H₄ClNO₂·0.125CHCl₃, (IIa), 6‐chloro‐2,5‐dihydroxypyridine carbon tetrachloride 0.125‐solvate, C₅H₄ClNO₂.·0.125CCl₄, (IIb), 6‐chloro‐2,5‐dihydroxypyridine 1,2‐dichloroethane solvate, C₅H₄ClNO₂·C₂H₄Cl₂, (IIc), and 6‐chloro‐2,5‐dihydroxypyridine 1,1,2,2‐tetrachloroethane solvate, C₅H₄ClNO₂·C₂H₂Cl₄, (IId), have I4₁/a symmetry, and incorporate extensively disordered solvent in channels that run the length of the c axis. Upon gentle heating to 378 K in vacuo, these crystals sublime to form solvent‐free crystals with P2₁/n symmetry that are exclusively the pyridone tautomer, (I). In these sublimed pyridone crystals, inversion‐related molecules form R²₂(8) dimers via pairs of N—H...O hydrogen bonds. The dimers are linked by O—H...O hydrogen bonds into R⁴₆(28) motifs, which join to form pleated sheets that stack along the a axis. In the channel‐containing pyridine solvate crystals, viz. (IIa)–(IId), two independent host molecules form an R²₂(8) dimer via a pair of O—H...N hydrogen bonds. One molecule is further linked by O—H...O hydrogen bonds to two 4₁ screw‐related equivalents to form a helical motif parallel to the c axis. The other independent molecule is O—H...O hydrogen bonded to two related equivalents to form tetrameric R⁴₄(28) rings. The dimers are π–π stacked with inversion‐related dimers, which in turn stack the R⁴₄(28) rings along c to form continuous solvent‐accessible channels. CHCl₃, CCl₄, CH₂ClCH₂Cl and CHCl₂CHCl₂ solvent molecules are able to occupy these channels but are disordered by virtue of the site symmetry within the channels.     

Channel‐forming solvate crystals and isostructural solvent‐free powder of 5‐hydroxy‐6‐methyl‐2‐pyridone

Crystals of 5‐hydroxy‐6‐methyl‐2‐pyridone, (I), grown from a variety of solvents, are invariably trigonal (space group R); these are 5‐hydroxy‐6‐methyl‐2‐pyridone acetone 0.1667‐solvate, C₆H₇NO₂·0.1667C₃H₆O, (Ia), and 6‐methyl‐5‐hydroxy‐2‐pyridone propan‐2‐ol 0.1667‐solvate, C₆H₇NO₂·0.1667C₃H₈O, (Ib), and the forms from methanol, (Ic), water, (Id), benzonitrile, (Ie), and benzyl alcohol, (If). They incorporate channels running the length of the c axis that contain extensively disordered solvent molecules. A solvent‐free sublimed powder of 5‐hydroxy‐6‐methyl‐2‐pyridone microcrystals is essentially isostructural. Inversion‐related host molecules interact via pairs of N—H...O hydrogen bonds to form R₂²(8) dimers. Six of these dimers form large R₁₂⁶(42) puckered rings, in which the O atom of each N—H...O hydrogen bond is also the acceptor in an O—H...O hydrogen bond that involves the 5‐hydroxy group. The large R₁₂⁶(42) rings straddle the axes and form stacked columns viaπ–π interactions between inversion‐related molecules of (I) [mean interplanar spacing = 3.254 Å and ring centroid–centroid distance = 3.688 (2) Å]. The channels are lined by methyl groups, which all point inwards to the centre of the channels.     

Functionalized Hydrocarbon Belts: Synthesis,Structure and Properties

Hydrocarbon belts have drawn great attention because of their unique structures and tantalizing properties. Although a few belts and heteroatom-doped analogs have been synthesized, belt molecules containing non-hexagonal rings remain rare. Herein we report the construction and application of unprecedented zigzag-type hydrocarbon belts which contain functionalized eight-membered rings. The synthesis features fourfold intramolecular acylation reactions of resorcin[4]arene-derived intermediates, which affords C₄-symmetric tetrabenzobelt[4]arene[4]cyclooctatrienones. Stereoselective ketone reduction with LiAlH₄ and nucleophilic addition with alkynyllithiums provide the corresponding tetrahydroxylated belts. The tetraol and its methyl ether are powerful and selective hosts to form 2 : 1 and 1 : 1 complexes with cesium ion, respectively, with binding constants up to (1.71±0.33)×10¹¹ M⁻² and (1.50±0.16)×10⁶ M⁻¹. In addition, enantiopure C₄-symmetric belts can emit CPL with |g_lum| being around 0.01.     

Oligosaccharide analogues of polysaccharides. Part 14:. Carbocyclic cyclodextrin analogues. Synthesis of all trimeric and tetrameric isomers by homo- and heterocoupling of 1,4-cis-diethynylated 1,5-anhydroglucitols

Hetero- or homocoupling of protected 1,4-cis-diethynylated 1,5-anhydroglucitols leads to two isomeric cyclotrimers and to four isomeric cyclotetramers. The C₃-symmetric cyciotrimer 31 , the C₄-symmetric cyclotetramer 35 , and the D₂-symmetric cyclotetramer 6 have been prepared before. We have now synthesized the C₁-symmetric cyciotrimer 13 , and the C₁- and the C₂-symmetric cyclotetramers 22 and 27 , respectively. The cyclotrimer 13 was prepared by intramolecular, oxidative homocoupling and, alternatively, by a one-pot trimerization/cyclization of the monomer 36 (Schemes 1 and 5, resp.). Oxidative homocoupling was used for the cyclization of the tetramers 19 and 25 , leading to 22 and 27. The tetramer 19 was made by sequential Cadiot-Chod-kiewicz coupling (Scheme 2)and the tetramer 25 by a combination of a Cadiot-Chodkiewicz reaction and an intermolecular, oxidalive homocoupling (Scheme 3). The acetates 34 and 38 , corresponding to 35 and 27 , respectively, were also made by a one-pot dimerization/cyclization of the dimer 37 (Scheme 5). Intramolecular oxidative heterocoupling is also feasible and results in an alternative, more convenient synthesis of the acetylated cyclotrimer 30 and the acetylated cyclotetramer 34 (corresponding to 31 and 35 , resp.; Scheme 4). The solid-state conformation of the C₄-symmetric cyclotetramer 34 corresponds well to the one predicted by force-field calculations. We compared the water-solubilities of the cyclotrimers 13 and 31 and the tetramers 6, 22, 27 , and 35 , their calculated conformations (MM3*), and the D -adenosine binding properties of the cyclotetramers 6, 27 , and 35 .