@phdthesis{Meyer2015, author = {Meyer, Larissa Valerie}, title = {D{\"u}nne Filme, Detektoren sowie Co-Dotierungen und Mischbarkeiten auf Basis von lumineszierenden Erdalkali-/Selten-Erd-Imidazolat-Ger{\"u}stverbindungen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-121501}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {This thesis deals with the formation of thin films and luminescence based detectors as well as co-dopings and larger miscibilities in luminescent alkaline earth / rare earth imidazolate coordination polymers and MOFs (metal organic frameworks). The formation of luminescent thin films of the coordination polymers 3∞[Sr1-xEux(Im)2] (x = 0 - 1) and the MOFs 3∞[Tb(Im)3] and 3∞[Ce(Im)3ImH]·ImH on nanostructured alumina substrates (AAO-substrates) was enabled by a new in-situ coating method based on a solvent free melt synthesis. Various layer thicknesses as well as different degrees of coverage were achieved. For the in-situ deposition of 3∞[Sr0.95Eu0.05(Im)2] two different coating strategies for the AAO substrates were established. In addition to the melt approach an electride induced coating method was carried out. Extraordinary baryte rose analogue crystals were observed on the AAO surface for the electride induced coating method. The deposition of the MOFs 3∞[Tb(Im)3] and 3∞[Ce(Im)3ImH]·ImH also took place via CVD processes (chemical vapor deposition). Thin luminescent films of the framework 3∞[Eu(Im)2] on (0001)-sapphire sub-strates were created by a new femto-PLD-process (femto-pulsed-laser-deposition). The films displayed a switchable transparency depending on the wavelength of the incoming light. 3∞[Sr0.95Eu0.05(Im)2], 3∞[Tb(Im)3] and 3∞[Ce(Im)3ImH]·ImH were examined as potential sensors or detectors regarding eight solvents and four gases. The exposure of the networks to water lead to a complete loss of luminescence intensity. MeOH-exposure is followed by a batho-chromic shift of the chromaticity of 3∞[Sr0.95Eu0.05(Im)2] from turquoise to orange. Acetone, pyridine, toluene, hexane, acetonitrile and dichloromethane increase the luminescence in-tensity of 3∞[Sr0.95Eu0.05(Im)2] and 3∞[Tb(Im)3]. The luminescence intensity of 3∞[Ce(Im)3ImH]·ImH is increased by acetonitrile as well as dichloromethane, but decreased under the influence of the other investigated solvents. The interaction of O2 and CO2 lead to a decrease of luminescence intensity by a turn-off-effect with the compounds 3∞[Tb(Im)3] and 3∞[Ce(Im)3ImH]·ImH, whereas no influence on the luminescence intensity of 3∞[Sr0.95Eu0.05(Im)2] was observed during exposure to N2, Ar, O2 and CO2. New coordination polymers 3∞[La4(Im)12(ImH)5]∙xImH (x = 2 - 3) and 3∞[Gd(Im)3] were synthe-sized as missing parts in the field of rare earth imidazolates. Both networks and the known alkaline earth imidazolates 2∞[Ca(Im)2(ImH)2], 3∞[Sr(Im)2] and 3∞[Ba(Im)2] as well as the rare earth imidazolates 3∞[Y(Im)3], 3∞[Ln(Im)3ImH]·ImH (Ln = Ce, Pr, Nd, Sm), 3∞[Gd2(Im)6(ImH)1.5]·0.5 ImH and 3∞[Tb(Im)3] were used as host lattice for the intrinsic luminescence of the Ln-ions Ce3+, Sm3+, Eu2+, Tb3+, Dy3+ and Yb3+. In addition to co-doping, larger miscibilities and possible phase boundaries were investigated. The correlation be-tween structure and luminescence as well as the possibility of color tuning based on additive color mixing of the emission colors were explored with the obtained bulk materials. Furthermore, the solvent free approach was expanded to alkaline earth and lanthanide met-als and the bicyclic ligand 1H-benzimidazole. The monomeric complexes [M(BIm)2(BImH)4] (M = Ca, Sr, Eu) and the two dimensional coordination polymers ²[AE(BIm)2] (AE = Mg, Ba) and ²[Eu(BIm)2(BImH)2] were synthesized and fully characterized. In the case of the Ba con-taining network two polymorphic forms of the network were obtained.}, subject = {Metallorganisches Netzwerk}, language = {de} }