Neuartige oligofunktionalisierte Amphiphile als LB-Filmbildner und flotationsaktive Reagenzien durch präorganisierende Strukturbildung

Müller, Petra Ulrike

25 November 2009

Gegenstand der vorliegenden Arbeit ist die Entwicklung, Synthese und Charakterisierung neuartiger oligofunktionalisierter Amphiphile mit potentiellen Sammler- und LB-Filmbildungseigenschaften. Basierend auf dem entwickelten Konzept der supramolekularen Strukturbildung zum Aufbau präorganisierter und gebündelter Sammleraggregate wurden zwei Typen neuartiger oligofunktioneller Tenside synthetisiert, die sich insbesondere in ihrer konformativen Flexibilität und Hydrophilie-Lipophilie-Balance unterscheiden. Ausgeprägte oberflächenaktive Eigenschaften wurden bei den bi-, tri- und tetrafunktionellen Aminosäure-analogen Zielverbindungen (Typ II) mit linearer, trigonaler und tetragonaler Molekülstruktur gefunden. Diese Verbindungen bilden auch stabile monomolekulare Filme geringer Heterogenität aus. Im mineralischen Flotationsprozess ergeben diese präorganisierten Tenside mit geometrisch kontrollierter Positionierung der lateralen Funktionseinheiten im Vergleich zu konventionellen Sammlern bei spezifischem Verhalten eine bemerkenswerte Steigerung der flotativen Effizienz.

Supramolekulare Chemie

Tenside

Gemini-Tenside

Präorganisation

Flotation

Langmuir-Blodgett-Filme

Brewsterwinkelmikroskopie

AFM

Gemini-Tensid

Langmuir-Blodgett-Film

Kraftmikroskopie

ddc:540

rvk:VH 5507

Room-Temperature Synthesis of Transition Metal Clusters and Main Group Polycations from Ionic Liquids

Ahmed, Ejaz

19 December 2011

Main group polycations and transition metal clusters had traditionally been synthesized via high-temperature routes by performing reactions in melts or by CTR, at room-temperature or lower temperature by using so-called superacid solvents, and at room-temperature in benzene–GaX3 media. Considering the major problems associated with higher temperature routes (e.g. long annealing time, risk of product decomposition, and low yield) and taking into account the toxicity of benzene and liquid SO2 in room-temperature or lower temperature synthesis, a soft and sustainable chemical approach has been developed, employing a Lewis-acidic IL [bmim]Cl/AlCl3. This new alternative reaction medium has proven to be an excellent solvent system for the single–step synthesis of main group polycations and transition metal clusters. X-ray diffraction and Raman spectroscopy have been used for the structural characterization of the isolated compounds. Physical properties and quantum chemical calculations of some of the compounds have also been carried out.

anorganische Synthese

Ionische Flüssigkeiten

Polykationen

Übergangsmetallcluster

umweltschonende Synthese

green chemistry

inorganic synthesis

ionic liquids

polycations

transition metal clusters

ddc:546

rvk:VH 5507

Anorganische Synthese

Ionische Flüssigkeit

Metallcluster

Polykation

Synthesis of Metal-Rich Compounds of Group 15 Elements in Lewis-Acidic Ionic Liquids

Groh, Matthias Friedrich

12 January 2017

Chemical synthesis of materials is facing enormous challenges at the present time. The necessary transition toward more sustainable economic processes requires new materials as well as optimized production of well-established materials. However, inorganic materials (e.g., ceramics or alloys) are typically produced industrially by high-temperature processes at up to 2000 °C. A relatively new approach for inorganic synthesis is based on so-called ionic liquids. Ionic liquids (ILs) — often defined as salts with melting points below 100 °C[1] — are usually composed of sterically demanding organic cations and (often) polyatomic anions, which can be selected in order to tune the properties of the IL. Owing to the distinctive physicochemical properties of ILs (e.g., wide liquidus range, high redox and thermal stability, (usually) negligible vapor pressure, tunable polarity), they have gained interest for a wide range of applications. Among the numerous inorganic materials accessible in ILs have been remarkable examples, especially in main-group element chemistry. For instance, a new metastable modification of germanium in the clathrate-II structure[2] or the largest known naked, main-group element cluster [Sn36Ge24Se132]24– (“Zeoball”).[3] The introduction of Lewis-acidic ILs has enhanced the convenience of polycation syntheses and enabled substitution of carcinogenic or toxic substances like benzene, SO2, or AsF5.[4] A considerable number of polycations of group 15 or 16 elements has been synthesized in ILs. The utilization of an IL as reaction medium can be decisive for the composition, structure, and physical properties of the (polycationic) reaction product.[5] In order to broaden the knowledge on synthesis techniques for inorganic materials near ambient temperature based on ILs, this thesis aimed at two goals: • Explorative synthesis of new inorganic compounds in ILs • Elucidating the influence of ILs on product formation For these two goals, metal-rich (polycationic) compounds of group 15 were chosen as promising chemical system, owing to the effectiveness of alkylimidazolium-based Lewis-acidic ILs for the synthesis of this class of compounds. A variety of new polycationic compounds has been successfully synthesized in Lewis-acidic ILs based on 1-n-butyl-3-methylimidazolium (or 1-ethy-3-methylimidazolium) halides and halogenido-aluminates. Determination of the crystal structures by single-crystal X-ray diffraction enabled analysis of their bonding situation supported by quantum-chemical calculations. In general, the employed ILs enabled syntheses with a high selectivity for the yielded polycation. Depending on the investigated chemical system, the following parameters were pinpointed to have significant influence: • Choice of starting materials • Choice of cation as well as anion of the IL • Reaction temperature • Concentration of starting materials in the IL The investigations were supported by NMR spectroscopy, which led to the discovery of nanoparticles of red phosphorus. This finding may stimulate the development of an easily accessible, reactive form of phosphorus without the hazardous drawbacks of the white allotrope. In addition, in situ NMR measurements in ILs were proven a viable option for mechanistic investigations. Conventional solid-state reaction as well as ionothermal syntheses yielded the new layered compounds M2Bi2S3(AlCl4)2 (M = Cu, Ag), which can be interpreted as Bi2S3 molecules embedded in MAlCl4 salts. The choice of starting materials was found to have a crucial influence on the crystallized polytype. Omitting the IL hindered the formation of crystals suitable for single-crystal structure determination. The three new main-group element heteropolycations [Bi6Te4Br2]4+, [Bi3S4AlCl]3+, and [Sb13Se16]7+ as well as known [Bi4Te4]4+ has been synthesized under ionothermal conditions. The Lewis-acidic ILs proved to be exceptional solvents for elements and their halides, and likewise for Bi2S3 and Bi2Te3. Hence, these solvents are not only advantageous reaction media for pnictogen and chalcogen chemistry but also potential (selective but expensive) ore-processing agents. These excellent solvent capabilities extend to complex ternary compounds including heavy transition metals such as Bi16PdCl22 and elemental platinum. This gave rise to the synthesis of metal-rich salts containing [Bi10]4+ antiprisms with an endohedral palladium or, for the first time, platinum atom. Furthermore, the filled bismuth polycation [Rh@Bi9]4+ or the complex cluster [Rh2Bi12]4+ could be obtained from dissolution and conversion of Bi12−xRhX13–x (X = Cl, Br) depending on the employed IL. Real-space bonding analysis revealed that [Rh2Bi12]4+ acquires a unique standing between dative bonding by bismuth polyions and mixed clusters following Wade-Mingos rules. References [1] J. S. Wilkes, P. Wasserscheid, T. Welton, in Ionic Liquids in Synthesis (Eds.: P. Wasserscheid, T. Welton), Wiley-VCH Verlag GmbH & Co. KGaA, 2007, pp. 1–6. [2] A. M. Guloy, R. Ramlau, Z. Tang, W. Schnelle, M. Baitinger, Y. Grin, Nature 2006, 443, 320–323. [3] Y. Lin, W. Massa, S. Dehnen, J. Am. Chem. Soc. 2012, 134, 4497–4500. [4] E. Ahmed, D. Köhler, M. Ruck, Z. Anorg. Allg. Chem. 2009, 635, 297–300. [5] E. Ahmed, J. Beck, J. Daniels, T. Doert, S. J. Eck, A. Heerwig, A. Isaeva, S. Lidin, M. Ruck, W. Schnelle, et al., Angew. Chem. 2012, 124, 8230–8233; Angew. Chem. Int. Ed. 2012, 51, 8106–8109.

Ionische Flüssigkeiten

Polykationen

Hauptgruppenelemente

Bismut

Metallreiche Verbindungen

Niedertemperatursynthesen

Ionic liquids

polycations

main-group elements

bismuth

metal-rich compounds

low temperature syntheses

ddc:540

rvk:VH 5507