Controlled Synthesis of Polyions of Heavy Main-Group Elements in Ionic Liquids

Until very recently, the term Lewis acidic ionic liquids (ILs) was nearly synonymous with halometallate ILs, with a strong focus on chloroaluminate(III) systems. The first part of this review covers the historical context in which these were developed, speciation of a range of halometallate ionic liquids, attempts to quantify their Lewis acidity, and selected recent applications: in industrial alkylation processes, in supported systems (SILPs/SCILLs) and in inorganic synthesis. In the last decade, interesting alternatives to halometallate ILs have emerged, which can be divided into two subsections: (1) liquid coordination complexes (LCCs), still based on halometallate species, but less expensive and more diverse than halometallate ionic liquids, and (2) ILs with main-group Lewis acidic cations. The two following sections cover these new liquid Lewis acids, also highlighting speciation studies, Lewis acidity measurements, and applications.

show abstract

“…Structural diversity of antimony-selenium heteropolycations accessible in haloaluminate(III) ILs under various reaction conditions[30] …”

mentioning

confidence: 99%

Lewis Acidic Ionic Liquids

Brown

Hogg

Swadźba‐Kwaśny

2017

Topics in Current Chemistry Collections

View full text Add to dashboard Cite

show abstract

“…Today, the polyhedral polycations Bi 5 + ,, Bi 5 3+ , Bi 6 2+ ,, Bi 8 2+ , Bi 9 5+ ,, and Bi 10 4+[23–38] are known, either as homoatomic entities or as parts of bismuth‐rich intermetalloid clusters additionally including electron‐rich transition metal atoms. This provided the basis for a detailed understanding of the structural and bonding principles in such clusters …”

Section: Introductionmentioning

confidence: 99%

The Subbromide Bi₅Br₄ – On the Existence of a Hidden Phase

Pabst

Chang

Finzel

et al. 2019

Zeitschrift anorg allge chemie

Self Cite

View full text Add to dashboard Cite

Black and irregularly shaped crystals of the bismuth‐rich bromide Bi5Br4 were obtained as a by‐product of the reaction of CsBr, Bi, and BiBr3. X‐ray diffraction on a single‐crystal revealed its orthorhombic structure with the space group Pmmn (no. 59) and lattice parameters a = 1800.0(2) pm, b = 1476.1(1) pm, and c = 924.5(2) pm at 296 K. The structure is composed of Bi82+ and Bi95+ polycations and bromidobismuthate(III) anions according to the structured formula Bi5Br4 = Bi20Br16 = Bi82+Bi95+[BiBr5]2–[Bi2Br11]5–. Bi5Br4 is the bismuth‐richest among the bismuth subhalides containing isolated polycations. Extensive differential scanning calorimetry studies indicate that Bi5Br4 decomposes at 262 °C, i.e. one degree below the bismuth‐rich eutectic at 263 °C. All attempts towards a rational synthesis yielded predominantly the neighboring phases BiBr and Bi6Br7.

show abstract

“…According reactions start out from either the respective elements, from binary chalcogenides, or from binary or ternary chalcogidometalate precursor salts, and they are usually carried out under addition of auxiliary amines. The product structures are based on polyanionic clusters or networks with different dimensionalities (1D strands, 2D layers, or 3D networks) …”

Section: Introductionmentioning

confidence: 99%

The Role of [BF₄]⁻ and [B(CN)₄]⁻ Anions in the Ionothermal Synthesis of Chalcogenidometalates

Santner

Sprenger

Finze

et al. 2018

Chemistry A European J

View full text Add to dashboard Cite

The role of borate anions in ionothermal syntheses of crystalline chalcogenidometalates was shown by the directed ionothermal synthesis of seven new selenidostannates in ionic liquids with either [BF ] or [B(CN) ] anions. Single crystal structures are presented of four compounds, (C C C Im) [Sn Se ][BF ] (1, Im=imidazolium), (DMMPH) [Sn Se ] (2, DMMP=2,6-dimethylmorpholine), (C C Im) (DMMPH) [Sn Se ] (3), and K [Sn Se ] (4), and how the chosen ionic liquid anion, and the reaction temperature, influences the product spectrum is discussed: Notably, 1 contains an entire formula unit of the ionic liquid, (C C C Im)[BF ], while 4 contains neither the cation nor the anion of the ionic liquid-both observations being very uncommon for ionothermal syntheses. Three further compounds were obtained that exhibit strong disorder in the crystal structures (I-III), for which only their anionic substructures are discussed herein. Compound 4 and I-III are based on the same layered selenidostannate substructure, 2D-{[Sn Se ] }, yet with different inter-layer distances, which is clearly reflected in the crystal colors and quantitative optical absorption properties.

show abstract

Controlled Synthesis of Polyions of Heavy Main-Group Elements in Ionic Liquids

Cited by 46 publications

References 111 publications

Lewis Acidic Ionic Liquids

Lewis Acidic Ionic Liquids

The Subbromide Bi₅Br₄ – On the Existence of a Hidden Phase

The Role of [BF₄]⁻ and [B(CN)₄]⁻ Anions in the Ionothermal Synthesis of Chalcogenidometalates

Contact Info

Product

Resources

About

Controlled Synthesis of Polyions of Heavy Main-Group Elements in Ionic Liquids

Cited by 46 publications

References 111 publications

Lewis Acidic Ionic Liquids

Lewis Acidic Ionic Liquids

The Subbromide Bi5Br4 – On the Existence of a Hidden Phase

The Role of [BF4]− and [B(CN)4]− Anions in the Ionothermal Synthesis of Chalcogenidometalates

Contact Info

Product

Resources

About

The Subbromide Bi₅Br₄ – On the Existence of a Hidden Phase

The Role of [BF₄]⁻ and [B(CN)₄]⁻ Anions in the Ionothermal Synthesis of Chalcogenidometalates