Synthesis and structures of monocyclic 1,4-diaza-2,3-diborine species

Söyleyici, Hakan Can; Uyanık, Sultan; Sevinçek, Resul; Fırıncı, Erkan; Bursalı, Banu; Burgaz, Osman; Aygün, Muhıttın; Şahin, Yüksel

doi:10.1016/j.inoche.2015.09.016

Cited by 9 publications

(8 citation statements)

References 26 publications

(23 reference statements)

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“…The 1 H NMR spectrum of 4 a displayed a characteristic 2H singlet for the ligand vinylene bridge at 5.23 ppm and a 12H singlet for the two dimethyl amino methyl groups at 2.15 ppm. These data are comparable to those reported for the analogous N‐( 2,4‐dimethylphenyl)‐ substituted species . However, the appearance at room temperature of the dimethylamino methyl protons as a single 12H resonance is surprising given the high B−N bond‐rotation barrier usually observed in dimethylaminoboron species (59–84 kJ mol −1 ) and the crystallographically determined B−N bond lengths of approximately 1.43 Å in 4 a , which suggest multiple bond character (Figure S29 in the Supporting Information).…”

Section: Resultssupporting

confidence: 81%

“…The driving force of the reaction is presumably the formation of unreactive dimeric [BH 2 NMe 2 ] 2 and dimethylsulfide (Scheme , bottom). To enforce a cis ‐configuration, bridging N , N′ ‐dimesityl‐1,2‐(diamino)ethene and ‐ethane ligands were chosen to provide electronic and steric stabilization to an endocyclic diborane moiety (Scheme ) …”

Section: Introductionmentioning

confidence: 99%

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Facile Access to Unprecedented Electron‐Precise Monohydrodiboranes(4), cis‐1,2‐Dihydrodiboranes(4), and a 1,1‐Dihydrodiborane(5)

Arrowsmith

Braunschweig

Radacki

et al. 2017

Chemistry A European J

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2,3-Bis(dimethylamino)-substituted B N C heterocycles underwent selective dimethylamino/hydride exchange with either one or two equivalents of BH ⋅SMe to give the corresponding cyclic monohydrido- or (cis)1,2-dihydridodiboranes(4), respectively. Upon either heating or irradiation in solution, the latter underwent ring contraction to the corresponding five-membered BN C heterocycles, whereas irradiation of the 1,2-dimethylaminoethene-supported 1,2-dihydridodiborane(4) in the presence of PEt gave an unprecedented unsymmetrical 1,1-dihydrodiborane(5) phosphine adduct.

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Section: Resultssupporting

confidence: 81%

Section: Introductionmentioning

confidence: 99%

Facile Access to Unprecedented Electron‐Precise Monohydrodiboranes(4), cis‐1,2‐Dihydrodiboranes(4), and a 1,1‐Dihydrodiborane(5)

Arrowsmith

Braunschweig

Radacki

et al. 2017

Chemistry A European J

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“…Compounds 1 b – d are readily identified by their 11 B NMR chemical shifts of δ =33.5 ( 1 b : 11 B{ 1 H}; ω 1/2 =1027 Hz), 34.1 ( 1 c : 11 B{ 1 H}; ω 1/2 =941 Hz), and 36.7 ppm ( 1 d : ω 1/2 =347 Hz) in [D 6 ]benzene solutions, which strongly resemble those found for 1 a ( δ =33.5 ppm) and the 2,4‐xylyl derivative of Sahin ( δ =32 ppm) . In the solid state however, these species feature marked differences with respect to the planarity of the B 2 N 2 C 2 heterocyclic core, which are caused by the nature and the sterics of the groups attached to the backbone nitrogen atoms.…”

Section: Resultsmentioning

confidence: 58%

“…By contrast, the B 2 N 2 C 2 rings of 1c ( Figure 2) and 1d ( Figure S64) deviate significantlyf rom planarity (N1-C1-C2-N2: 1c 6.7(2)8; 1d 8.8(2)8.N 1-B1-B2-N2: 1c 45.0(2)8; 1b 52.0(1)8), similar to the data reported by Sahin (N1-C10-C9-N2: À5.58.N 1-B1-B2-N2: À41.78). [15] For 1a and 1b,s teric repulsion between the NMe 2 and Mes/Xyl units entails twisting of the aryl groups to adopt an orthogonal arrangement with respectt ot he heterocyclic core structure, which generates sufficient space for the NMe 2 groups in a planar B 2 N 2 C 2 environment. In 1d,r epulsive sterici nteractions between theN Me 2 and the tBu groups within ap lanar geometry would be inevitable, thus the B 2 N 2 C 2 ring displays af lattened chair conformation.…”

Section: Resultsmentioning

confidence: 99%

“…The first DADBs were isolated in 1963 as benzannulated derivatives by exchange amination of B 2 R 2 (NMe 2 ) 2 with aromatic amines ( A , R=alkyl, Figure ), while it was not until 1997 that a monocyclic oxygen‐bridged DADB dimer was reported as a byproduct ( B , Figure ) . Very recently, a general and more selective route to monomeric DADBs ( C , Figure ) through salt elimination reactions of Li 2 [dab] salts (dab=1,4‐diazabutadiene) with dihalodiboranes(4) has been established independently by Sahin and by our group . So far, reactivity studies on type C DADBs are scarce and limited to the transformation of the NMe 2 ‐substituted derivative 1 a to its dihydrido analog and subsequent ring contraction/expansion reactions .…”

Section: Introductionmentioning

confidence: 99%

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Facile Access to Substituted 1,4‐Diaza‐2,3‐Diborinines

Thiess

Ernst

Kupfer

et al. 2020

Chemistry A European J

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Several bis(dimethylamino)‐substituted 1,4‐diaza‐2,3‐diborinines (DADBs) were synthesized with variable substituents at the backbone nitrogen atoms. By reaction with HCl or BX3 (X=Br, I), these species were successfully converted into their synthetically more useful halide congeners. The high versatility of the generated B−X bonds in further functionalization reactions at the boron centers was demonstrated by means of salt elimination (MeLi) and commutation (NMe2 DADBs) reactions, thus making the DADB system a general structural motif in diborane(4) chemistry. A total of 18 DADB derivatives were characterized in the solid state by X‐ray diffraction, revealing a strong dependence of the heterocyclic bonding parameters from the exocyclic substitution pattern at boron. According to our experiments towards the realization of a Dipp‐substituted, sterically encumbered DADB, the mechanism of DADB formation proceeds via a transient four‐membered azadiboretidine intermediate that subsequently undergoes ring expansion to afford the six‐membered DADB heterocycle.

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Boron‐Doped Polycyclic Aromatic Hydrocarbons (B‐PAHs): Synthesis, Properties, and Applications

Lorenzo-Garcia

Fasano

Bonifazi

2021

Patai's Chemistry of Functional Groups

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Inspired by the doping approach used in silicon technology to building inorganic semiconductors, in this chapter we tackle the emerging approach in organic synthesis of exploiting the replacement of carbon atoms with isolobal heteroatoms. Capitalizing on the idea for which the insertion of heteroatoms of graphitic nanostructure preserves the planar geometry of the π‐scaffold, one could envisage to tune the optoelectronic properties of π‐conjugated molecular materials by the only insertion of heteroatoms. Herein, we discuss all B‐containing rings that can be envisaged to construct doped π‐conjugated structures integrating a graphenoid framework. In the first section, we guide the reader through the synthesis, properties, and applications of the most relevant examples of B‐doped PAHs, in which one or more sp 2 ‐hybridized carbon atoms have been replaced by B atoms through the formation of the CB bond. Past and recent synthetic developments of aromatic and nonaromatic B‐doped ring, i.e., boracycle, are discussed. B‐PAHs are amenable to be classified by ring size of the boracycle, that is, three‐, four‐, five‐, six‐, or seven‐membered rings. In a second avenue, we focused the attention on the use of the boron–nitrogen (BN) pair site as isoelectronic and isostructural doping units replacing CC bonds in PAHs. While three‐ and four‐membered rings containing BN couples are known but not extensively explored, five‐ and six‐membered rings are certainly the most studied structural π‐conjugated motifs. In the last section, the heart of the discussion is centered on B‐PAHs containing BO bonds, mainly in five‐ and six‐membered rings.

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Synthesis and structures of monocyclic 1,4-diaza-2,3-diborine species

Cited by 9 publications

References 26 publications

Facile Access to Unprecedented Electron‐Precise Monohydrodiboranes(4), cis‐1,2‐Dihydrodiboranes(4), and a 1,1‐Dihydrodiborane(5)

Facile Access to Unprecedented Electron‐Precise Monohydrodiboranes(4), cis‐1,2‐Dihydrodiboranes(4), and a 1,1‐Dihydrodiborane(5)

Facile Access to Substituted 1,4‐Diaza‐2,3‐Diborinines

Boron‐Doped Polycyclic Aromatic Hydrocarbons (B‐PAHs): Synthesis, Properties, and Applications

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