5 research outputs found
Chemoselective, Practical Synthesis of Cobaltocenium Carboxylic Acid Hexafluorophosphate
Cobaltocenium carboxylic acid (carboxycobaltocenium)
hexafluorophosphate, a key compound for other monofunctionalized cobaltocenium
salts, has been synthesized in >70% overall yield starting from
cobaltocenium hexafluorophosphate by a synthetic sequence involving
(i) nucleophilic addition of lithium (trimethylsilyl)ethynide, (ii)
hydride removal by tritylium hexafluorophosphate, and (iii) oxidative
cleavage of the alkynyl substituent by potassium permanganate
Chemoselective, Practical Synthesis of Cobaltocenium Carboxylic Acid Hexafluorophosphate
Cobaltocenium carboxylic acid (carboxycobaltocenium)
hexafluorophosphate, a key compound for other monofunctionalized cobaltocenium
salts, has been synthesized in >70% overall yield starting from
cobaltocenium hexafluorophosphate by a synthetic sequence involving
(i) nucleophilic addition of lithium (trimethylsilyl)ethynide, (ii)
hydride removal by tritylium hexafluorophosphate, and (iii) oxidative
cleavage of the alkynyl substituent by potassium permanganate
Monofunctionalized Cobaltocenium Compounds by Dediazoniation Reactions of Cobaltoceniumdiazonium Bis(hexafluorophosphate)
Monofunctionalized
cobaltocenium salts are obtained for the first time from cobaltoceniumdiazonium
bis(hexafluorophosphate) with various nucleophiles via Sandmeyer-type
and related reactions. For successful conversions, reaction conditions
are quite critical: either standard solution chemistry in nitromethane
or solvent-free ball milling proved necessary, depending on the type
of reactant. By this synthetic approach valuable synthons such as
iodocobaltocenium and azidocobaltocenium salts are accessible that
open up new vistas in cobaltocenium chemistry. Spectroscopic characterization
by NMR, IR, HRMS, and single-crystal structure analysis as well as
the results of electrochemical studies are reported. Derivatives with
two reversible reductions show the expected relation of the half-wave
potentials with the Hammett substituent parameter σ<sub>p</sub> of the respective substituent with a slightly larger slope for the
first reduction. The carboxylic acid (reductive deprotonation of the
−COOH functionality), the iodo (protodehalogenation), and the
azido derivatives undergo irreversible subsequent reactions after
primary reduction
Monofunctionalized Cobaltocenium Compounds by Dediazoniation Reactions of Cobaltoceniumdiazonium Bis(hexafluorophosphate)
Monofunctionalized
cobaltocenium salts are obtained for the first time from cobaltoceniumdiazonium
bis(hexafluorophosphate) with various nucleophiles via Sandmeyer-type
and related reactions. For successful conversions, reaction conditions
are quite critical: either standard solution chemistry in nitromethane
or solvent-free ball milling proved necessary, depending on the type
of reactant. By this synthetic approach valuable synthons such as
iodocobaltocenium and azidocobaltocenium salts are accessible that
open up new vistas in cobaltocenium chemistry. Spectroscopic characterization
by NMR, IR, HRMS, and single-crystal structure analysis as well as
the results of electrochemical studies are reported. Derivatives with
two reversible reductions show the expected relation of the half-wave
potentials with the Hammett substituent parameter σ<sub>p</sub> of the respective substituent with a slightly larger slope for the
first reduction. The carboxylic acid (reductive deprotonation of the
−COOH functionality), the iodo (protodehalogenation), and the
azido derivatives undergo irreversible subsequent reactions after
primary reduction
π‑Complexes of Tropolone and Its N‑Derivatives: Ambidentate [O,O]/[N,O]/[N,N]-Cycloheptatrienyl Pentamethylcyclopentadienyl Ruthenium Sandwich Complexes
Tropolone and its N-derivatives isopropylaminotropone
and diisopropylaminotroponimine
react with [Cp*Ru(CH<sub>3</sub>CN)<sub>3</sub>]PF<sub>6</sub> as
the source of the electron-rich Cp*Ru<sup>+</sup> synthon in a simple
“capping reaction” to the first cyclopentadienyl/cycloheptatrienyl
sandwich complexes containing two vicinal oxo or amino substituents.
These heteroleptic, cationic C<sub>5</sub>/C<sub>7</sub> π-complexes,
[Cp*Ru(C<sub>7</sub>H<sub>5</sub>)O<sub>2</sub>H]<sup>+</sup> (<b>4</b>), [Cp*Ru(C<sub>7</sub>H<sub>5</sub>)O(N<sup>i</sup>Pr)H]<sup>+</sup> (<b>5</b>), and [Cp*Ru(C<sub>7</sub>H<sub>5</sub>)(N<sup>i</sup>Pr)<sub>2</sub>H]<sup>+</sup> (<b>6</b>), are air-stable
18-electron metallocenes without precedence. In solution, NMR spectroscopy
proves the principal π-coordination of the substituted η<sup>7</sup>-cycloheptatrienyl ligands, whereas in the solid state a η<sup>5</sup>-cycloheptatrienyl coordination mode with bent oxo/imino moieties
prevails, as shown by X-ray single-crystal structure analyses. Chemically,
these compounds are the conjugate Brønsted acids of neutral [O,O]-,
[N,O]-, or [N,N]-metalloligands. Reaction with metal acetates or acetylacetonates
by <i>in situ</i> deprotonation and complex formation gives
access to trimetallic (M = Cu<sup>2+</sup>, <b>10</b>–<b>12</b>) or tetrametallic (M = Fe<sup>3+</sup>, <b>13</b>) complex cations. Their single-crystal structure analyses show square-planar
or square-pyramidal (M = Cu<sup>2+</sup>) or octahedral (M = Fe<sup>3+</sup>) coordination motifs with peripheral, η<sup>5</sup>-coordinated Cp*Ru moieties. Electrochemical studies on the trorucenes <b>4</b>–<b>6</b> showed a likely metal-based chemically
reversible (<b>4</b>) or irreversible one-electron reduction
(<b>5</b>, <b>6</b>) as well as an irreversible one-electron
oxidation for the N-substituted compounds <b>5</b> and <b>6</b>. The behavior of the heterotri- and tetrametallic complexes <b>10</b>, <b>11</b>, and <b>13</b> was rationalized
by a combination of cyclic and square-wave voltammetry as well as
the combination of chronocoulometry and linear-sweep voltammetry and
by comparison with the mononuclear copper or iron tropolone and topolonimine
precursors <b>14</b>–<b>16</b>. These studies indicate
that in <b>10</b> and <b>11</b> the trorucene moieties
are reduced first in two coincident or slightly separated one-electron
reductions with the Cu<sup>2+</sup> reduction at very negative potential,
whereas in <b>13</b> the central Fe(III)-tris(troponolato) moiety
is reduced prior to the trorucene appendices. An <i>in vitro</i> anticancer screening in MDA-MB-231 breast adenocarcinoma and HT-29
colon carcinoma cell lines showed enhanced antiproliferative activity
for the [O,O]-coordinated iron and copper complexes