An Unusual Isomerization to Tetraazastiboles

Lehmann, Mathias; Schulz, Axel; Villinger, Alexander

doi:10.1002/anie.201100663

Cited by 36 publications

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“…[1][2][3] In particular,( pseudo)halogen-substituted cyclic dipnictadiazanes (B,Scheme 1) proved to be versatile starting materials for the synthesis of (transient) compounds with NPn multiple bonds (for example, A)g enerated by cycloreversion reactions, [4][5][6][7][8] larger ring systems by subsequent cycloaddition reactions or ring expansion, [4,9,10] as well as cationic species which are formed by abstraction of halogen atoms (C). [1][2][3] In particular,( pseudo)halogen-substituted cyclic dipnictadiazanes (B,Scheme 1) proved to be versatile starting materials for the synthesis of (transient) compounds with NPn multiple bonds (for example, A)g enerated by cycloreversion reactions, [4][5][6][7][8] larger ring systems by subsequent cycloaddition reactions or ring expansion, [4,9,10] as well as cationic species which are formed by abstraction of halogen atoms (C).…”

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“…Ring systems composed of Group 15 elements (pnictogens, Pn) are af ascinating aspect of main-group chemistry. [1][2][3] In particular,( pseudo)halogen-substituted cyclic dipnictadiazanes (B,Scheme 1) proved to be versatile starting materials for the synthesis of (transient) compounds with NPn multiple bonds (for example, A)g enerated by cycloreversion reactions, [4][5][6][7][8] larger ring systems by subsequent cycloaddition reactions or ring expansion, [4,9,10] as well as cationic species which are formed by abstraction of halogen atoms (C). [11][12][13][14][15] In this regard, we are currently interestedinthe reactivity of analogous ring systems solely based on phosphorus (that is, [XP(m-PR)] 2 )t oe valuate possible reaction routes to similar, unprecedented phosphorus species.F or example,r eports of cationic phosphorus ring systems include phosphinophosphonium frameworks (I-III,S cheme 2), [16][17][18][19][20] related cyclic and bicyclicpolyphosphorus frameworks (V, VI) [21] and, in awider sense,s everal cluster cations (IV), [22][23][24][25] as well as bicyclic systems with cationic substituents.…”

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Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*₂P₄Cl][GaCl₄]

et al. 2015

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The reaction of [ClP(μ-PMes*)]2 (1) with the Lewis acid GaCl3 yielded a hitherto unknown tetraphosphabicyclo[1.1.0]butan-2-ium salt, [Mes*P4(Cl)Mes*][GaCl4] (3[GaCl4]), which incorporates a positively charged phosphonium center within its bicyclic P4 scaffold. The formation of the title compound was studied by means of low-temperature NMR experiments. This led to the identification of an intermediate cyclotetraphosphenium cation, which was trapped by reaction with dimethylbutadiene (dmb). All of the compounds were fully characterized by experimental and computational methods.

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Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*₂P₄Cl][GaCl₄]

et al. 2015

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“…Since all attempts to synthesize the desired RN 4 Bi heterocycle using inter molecular [3+2] cycloaddition reactions failed, we changed our approach to intra molecular cycloaddition reactions. In analogy to the synthesis of tetrazastiboles, attempts were made to synthesize various azido derivatives of 1 , which might be isomerized to a tetrazabismuthole by Lewis‐acid induced Me 3 SiCl elimination and subsequent intramolecular [3+2] cycloaddition. For this reason, 1 was treated with NaN 3 in thf to generate the azido‐chloride or the diazido substituted compounds Mes*N(SiMe 3 )Bi(Cl)N 3 and Mes*N(SiMe 3 )Bi(N 3 ) 2 .…”

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“…The aim of these investigations was the synthesis of a bismadiazonium salt (R‐N≡Bi + ) and a tetrazabismuthole (R‐N 4 Bi) in a formal [3+2] cycloaddition reaction with a covalently bound azide, R‐N 3 . Tetrazapnictoles (R‐N 4 Pn, Pn = element of group 15 = pnictogen) are already known for the lighter congeners of bismuth (Pn = P, As, and Sb) . The formation of such compounds includes Me 3 SiX (X = Cl, [OTf]; OTf = OSO 2 CF 3 ) elimination and cyclisation reactions with azides (Scheme ).…”

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A Bismuth–Arene σ‐Complex – On the Edge of Menshutkin‐Type Complexes

et al. 2019

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Mes*N(SiMe 3 )BiCl 2 (1, Mes* = 2,4,6-tri-tert-butylphenyl) can be referred to as a hidden iminobismuthane, Mes*N=BiCl, which was thought to be generated in-situ upon Me 3 SiCl elimination triggered by a Lewis acid such as GaCl 3 . Therefore, the reactivity of aminobismuthane 1 was studied to find a synthesis route for the formation of a tetrazabismuthole in a [3+2] cycloaddition reaction with a covalently bound azide. However, reaction of 1 with GaCl 3 cleanly led to [Mes*N(SiMe 3 )-BiCl][GaCl 4 ] (2[GaCl 4 ]), a compound with a Bi-arene σ-complex. Utilizing Ag[WCA] salts (WCA = weakly coordinating anion) for [a]

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“…B. A), [4][5][6][7][8] grçßeren Ringsystemen durchC ycloadditionsreaktionen sowie Ringerweiterung [4,9,10] oder auch kationischen Spezies durch Abstraktion von Halogenen (C). [11][12][13][14][15] Infolgedessen interessieren wir uns momentan für die Chemie analoger Ringsysteme,d ie ausschließlich aus Phosphor aufgebaut sind (d. h. [XP(m-PR)] 2 ), um mçgliche Reaktionswege zu vergleichbaren, neuen Phosphorspezies aufzufinden.…”

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Tieftemperatur‐Isolierung des bicyclischen Phosphinophosphoniumsalzes [Mes*₂P₄Cl][GaCl₄]

et al. 2015

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Ringsysteme aus Elementen der Gruppe 15 (Pniktogene, Pn) sind ein faszinierender Aspekt der Hauptgruppenchemie. [1][2][3] Insbesondere (pseudo-)halogensubstituiertecyclische Dipniktadiazane (B,S chema 1) haben sich als vielseitige Edukte für Folgereaktionen herausgestellt, etwa zur Synthese von (kurzlebigen) Verbindungen mit NPn-Mehrfachbindungen durch Cycloreversionsreaktionen (z. B. A), [4][5][6][7][8] grçßeren Ringsystemen durchC ycloadditionsreaktionen sowie Ringerweiterung [4,9,10] oder auch kationischen Spezies durch Abstraktion von Halogenen (C). [11][12][13][14][15] Infolgedessen interessieren wir uns momentan für die Chemie analoger Ringsysteme,d ie ausschließlich aus Phosphor aufgebaut sind (d. h. [XP(m-PR)] 2 ), um mçgliche Reaktionswege zu vergleichbaren, neuen Phosphorspezies aufzufinden. Berichte über bekannte,k ationische Phosphorringsysteme umfassen beispielsweise Phosphinophosphoniumstrukturen (I-III,S chema 2), [16][17][18][19][20] verwandte cyclische und bicyclische Polyphosphorgerüste (V, VI) [21] und, im weiteren Sinne,d iverse Clusterkationen (IV) [22][23][24][25] sowie bicylische Systeme mit kationischen Substituenten. [25,26] Cyclische Tetraphospheniumkationen vergleichbar mit C wurden hingegen noch nicht beobachtet.Erst kürzlich entwickelten wir eine Synthesevorschrift für das Dichlorcyclotetraphosphan [ClP(m-PMes*)] 2 (1,M es* = 2,4,6-Tri-tert-butylphenyl), [27] das uns Untersuchungen der Reaktivität dieser wenig erforschten Substanzklasse ermçg-licht. [28,29] Hierbei fokussieren wir uns auf die selektive Funktionalisierung des P 4 -Gerüsts durch Substitution oder Abstraktion der Cl-Atome,i mG egensatz zur häufig verwendeten Methode der direkten Funktionalisierung von weißem Phosphor (P 4 )durch z. B. Lewis-Säure-Base-Systeme, Übergangsmetalle oder Singulettcarbene wie N-heterocyclische Carbene (NHCs) und cyclische Alkylaminocarbene (CAACs). [30][31][32][33] Während die Chemie von cyclischen Phosphanen mit kohlenstoff-oder stickstoffbasierten Substituenten gut untersucht ist, [34] gibt es keine Literaturberichte über die Reaktivität von halogensubstituierten cyclischen Te traphosphanen. Hier stellen wir daher Ergebnisse zur Reaktion von 1 mit der Lewis-Säure GaCl 3 vor.In Analogie zur Synthese cyclischer Dipniktadiazeniumsalze (C)w urde eine farblose Lçsung von 1·C 6 H 5 Fi nD ichlormethan bei tiefen Te mperaturen mit GaCl 3 umgesetzt, wobei eine sofortige tiefrote Färbung zu beobachten war.Insitu-31 P-NMR-Spektroskopie zeigte die intermediäre Bildung Schema 1. Ein formales Gleichgewicht zwischen monomerenI minopniktanen (A;Pn=P, As;X=(Pseudo-)Halogen) und cyclischen Dipniktadiazanen (B;P n=P, As, Sb, Bi)i nAbhängigkeitv om sterisch anspruchsvollen Rest Rermçglicht unterschiedliche Reaktionspfade, unter anderem die Bildung cyclischerD ipniktadiazeniumsalze (C; Pn = P, As, Sb, Bi).Schema 2. Strukturmotive in kationischen Phosphorringsystemen.

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An Unusual Isomerization to Tetraazastiboles

Cited by 36 publications

References 54 publications

Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*₂P₄Cl][GaCl₄]

Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*₂P₄Cl][GaCl₄]

A Bismuth–Arene σ‐Complex – On the Edge of Menshutkin‐Type Complexes

Tieftemperatur‐Isolierung des bicyclischen Phosphinophosphoniumsalzes [Mes*₂P₄Cl][GaCl₄]

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An Unusual Isomerization to Tetraazastiboles

Cited by 36 publications

References 54 publications

Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*2P4Cl][GaCl4]

Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*2P4Cl][GaCl4]

A Bismuth–Arene σ‐Complex – On the Edge of Menshutkin‐Type Complexes

Tieftemperatur‐Isolierung des bicyclischen Phosphinophosphoniumsalzes [Mes*2P4Cl][GaCl4]

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Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*₂P₄Cl][GaCl₄]

Low‐Temperature Isolation of the Bicyclic Phosphinophosphonium Salt [Mes*₂P₄Cl][GaCl₄]

Tieftemperatur‐Isolierung des bicyclischen Phosphinophosphoniumsalzes [Mes*₂P₄Cl][GaCl₄]