Growth mechanism and surface chemistry of II-VI 2D nanomaterials / Mécanisme de croissance et chimie de surface des nanomatériaux bidimensionnel II-VI

Jiang, Ye

05 March 2018

Grâce à leurs propriétés optiques et électroniques uniques, les nanocristaux de semi-conducteurs colloïdaux bidimensionnels tels que les nanoplaquettes de chalcogénure de cadmium ont émergé comme une nouvelle classe de nanomatériaux. Tout comme les puits quantiques, ces nanocristaux ont un confinement electronique limité à une seule direction, l'épaisseur qui est contrôlée au niveau atomique. Ces nanoplaquettes colloïdales apparaissent ainsi comme de bons candidats pour la fabrication de dispositifs optoélectroniques. Cependant, leur mécanisme de formation reste sujet à discussion. Ainsi, cette thèse se concentre tout d’abord sur l'étude de la synthèse de nanoplaquettes de CdSe zinc blende et l’effet de la longueur de la chaine aliphatique des carboxylates sur ces dernières, ouvrant ainsi la voie à une meilleure compréhension de la croissance des nanocristaux bidimensionnels.Par la suite, la nature et la localisation de ces ligands carboxylates en surface des nanoplaquettes a été étudié par des techniques de RMN. Cette étude semble confirmer l’effet de la gêne stérique sur la croissance des nanoplaquettes. La RMN du solide en corrélation 13C-1H 2D, se basant sur l’interaction dipolaire, indique que les acétates et les carboxylates à longue chaîne sont très probablement distribués de manière homogène à la surface des nanoplaquettes de CdSe. Dans une dernière partie, j’explore la possibilité d’améliorer les propriétés optiques de nanoplaquettes synthetisées par déposition de couches atomiques en voie colloïdale (c-ALD) en utilisant des recuits, visant à améliorer la structure et la surface des matériaux. / Colloidal two-dimensional semiconductor nanocrystals such as nanoplatelets of cadmium chalcogenides, have emerged as a new class of nanomaterials due to their unique optical and electronic properties. These nanocrystals possess exciton confinement along one direction in analogy to quantum wells, with their thickness controlled at atomic level.Although colloidal two-dimensional nanoplatelets have been considered as potential candidates for the fabrication of optoelectronic devices, their formation mechanism e.g. zinc blende CdSe nanoplatelets is still under debate. Thereby this thesis first focuses on the study of CdSe nanoplatelets synthesis and size of the aliphatic chain in the carboxylate, paving the way to a better understanding of two-dimensional nanocrystals’ growth.Successively surface carboxylate ligands are investigated by NMR techniques which gives us an idea of how surface ligands are composed and relocated. Our study of ligand quantification on nanoplatelets’ surface appears to support the proposed effect from steric hinderance on NPLs growth. 13C-1H 2D correlation solid state NMR based on the dipolar interaction indicates that acetates and long alkyl chain carboxylates should be distributed homogenously on the surface of the CdSe NPLs. In the last part, I explore the possibility of improving the optical features of nanoplatelets synthesized from colloidal atomic-layer-deposition technique through optimizing both interior and surface structures by an annealing process.

Nanocristaux

Nanoplaquettes

Synthèse

Mécanisme de croissance

Ligands de surface

Propriétés optiques

Nanocrystals

Nanoplatelets

Synthesis

620.5

Organic ligand complexation reactions on aluminium-bearing mineral surfaces studied via in-situ multiple internal reflection infrared spectroscopy, adsorption experiments, and surface complexation modelling

Assos, Charalambos

January 2010

Organic ligand complexation reactions at the mineral-water interface play an important role in several environmental and geochemical processes such as adsorption, dissolution, precipitation, pollutant transport, nutrient cycling, and colloidal stability. Although organic ligand surface complexation reactions have been extensively studied, a molecular level understanding regarding the mechanisms underlying the adsorption of such compounds is still limited. The purpose of the current study was to investigate the interactions between some common naturally occurring organic ligands and a common aluminosilicate clay mineral, kaolinite, using a combination of macroscopic and microscopic experimental methods. Molecular level information regarding the structure and binding mode of adsorbed species was obtained using in situ MIR-FTIR spectroscopy. Other experimental techniques including adsorption experiments, surface titrations, and surface complexation modelling were also employed in order to quantify and describe the macroscopic adsorption properties of the organic ligands examined. Three low molecular weight organic acids (oxalic, salicylic, and phthalic acid) and humic acid were chosen as representative organic ligands. Spectroscopic evidence revealed that low molecular weight organic acids are able to form both inner and outer sphere complexes on kaolinite, and the relative concentrations of these surface complexes varies with solution chemistry. Inner sphere coordination modes inferred are a mononuclear bidentate for oxalate (five-membered chelate ring) and phthalate (seven-membered chelate ring); and a mononuclear monodenate (six-membered pseudochelate ring) for salicylic acid. Similar coordination modes were shown to form on simpler mineral (hyrd)oxides. Elucidation of the coordination chemistry of these ligands can provide insights into the dissolution mechanisms of silicate minerals In contrast to low molecular weight organic acids, there was no evidence of inner sphere complexation by humic acid acids on kaolinite or gibbsite. The combined spectroscopic and macroscopic adsorption results suggest that cation bridging and van der Waals interactions are the two most probable mechanisms for the adsorption of humic acid by these mineral substrates. This finding casts doubts over the use of low molecular weight organic acids as humic acid analogs.

572.51

On the ligand shell complexity of strongly emitting, water-soluble semiconductor nanocrystals

Leubner, Susanne

06 March 2015

Colloidal semiconductor nanocrystals (NCs) have attracted a great deal of interest as bright and stable chromophores for a variety of applications. Their superior physicochemical properties depend on characteristics of the inorganic core, as well as on the chemical nature and structure of the stabilizing organic ligand shell. To evaluate the promising material, a thorough knowledge of structure-property relationships is still demanded. The present work addresses this challenge to three water-soluble NC systems, namely thiol-capped CdTe, thiol-capped CdHgTe, and DNA-functionalized CdTe NCs with special emphasis on the investigation of structure, modification, and influence of the ligand shell. Remarkably, CdTe NCs show bright emission in the visible spectral region and can be synthesized in high quality directly in water. It was shown that the aqueous synthesis also facilitates the preparation of strongly near-infrared (NIR) emitting CdHgTe NCs. The current work presents a detailed study on parameters, by which the emission can be tuned, such as the growth time, the initial Cd : Hg ratio, and the choice of ligand. These insights contribute to the knowledge, which is essential for the design of highly emissive and long-term stable NIR emitting NCs. Further variations of the NC/ligand system include the modification of the ligand shell of CdTe NCs with oligonucleotides based on the strong attachment of DNA molecules to the NC. The successful functionalization of NCs with single-stranded DNA molecules is very promising for the precise and programmable assembly of NCs using DNA origami structures as templates. For both, functionality and optical properties, the surface chemistry of the NCs plays a substantial role and was subject to an extensive investigation. As there is no generally applicable technique to determine the amount of stabilizers and the structure of the ligand shell, the presented study is based on a combination of various methods particularly tailored to the analysis of water-soluble CdTe NCs capped by short-chain thiols. CdTe NCs served as a model system for the described analysis of the ligand shell, since they are thoroughly studied regarding synthesis and features of the core. Aiming for the quantification of thiols, a straightforward colorimetric assay, the Ellman\'s test, is for the first time introduced for the analysis of NCs. Accompanied by elemental analysis an approximate number of thiols per NC becomes accessible. Moreover, theoretical calculations were performed to estimate the amount of ligand that would cover the NC in a monolayer of covalently bound molecules. In contrast to these results, the experimental values point to a larger amount of thiols immobilized on the NC. Attempts to remove the ligand indicate the presence of Cd in the ligand shell and thermogravimetric studies show that the ligands are not loosely assembled in the ligand shell. The outstanding conclusion of these findings involves the presence of Cd-thiol complexes in the ligand shell. Further results unambiguously show that the amount of Cd-thiol complexes present in the NC solution strongly influences the concentration-dependent emission yield of the NCs. Additional studies dedicated to the considerable influence of the ligand shell highlight a strong effect of pH, NC concentration, type and purity of the solvent, and the number of precipitation steps on the emission of water-soluble semiconductor NCs. These substantial investigations emphasize the need to carefully control the conditions applied for handling, optical measurements, and application of NCs. In order to gain a deeper insight into the complex structure of the native ligand shell, techniques deliberately chosen for the in situ analysis were applied for thioglycolic acid-capped CdTe NCs. Information from dynamic light scattering (DLS) regarding the stability and the shell thickness are consistent with previous results showing a large ligand network on the NC surface and a decreasing stability of the NCs upon dilution. Importantly, nuclear magnetic resonance (NMR) spectroscopy allows for the distinction of bound and free ligands directly in solution and proves the presence of these species for the NCs studied. In particular, the results indicate that the ligands are not strongly bound to the NC core and that both, free and bound ligand species, consist of modified thiol molecules, such as Cd-thiol complexes. These findings support previous assumptions and allow to establish a distinct picture of the ligand shell of water-soluble semiconductor NCs. Further insights were obtained from small-angle X-ray scattering (SAXS), which facilitates the identification and the determination of the composition of NC core as well as ligand shell. Element-specific SAXS yields the final proof of the presence of Cd in the ligand shell. The model developed for the optimal fitting of the experimental scattering curves additionally confirms the findings from the other methods. In conclusion, the present work contributes to the challenging goal of a comprehensive knowledge of interactions between the NC core and the ligands. The fundamental development of a structural model of water-soluble CdTe NCs including information on stoichiometries is accomplished by the combination of the techniques presented and emphasizes the challenge to assign a clear border between the ligand shell and the Cd-thiol complexes in solution. Altogether, CdTe NCs capped by thioglycolic acid are best described by a crystalline core surrounded by a water-swollen Cd-thiolate shell that considerably affects the optical properties of the system. Notably, the results of the versatile study provide the opportunity to control the overall properties and to evaluate water-soluble semiconductor NCs for particular applications in photonics and optoelectronics.

info:eu-repo/classification/ddc/540

ddc:540