Buffered Coordination Modulation as a Means of Controlling Crystal Morphology and Molecular Diffusion in an Anisotropic Metal-Organic Framework

Significant advances have been made in the synthesis of chemically selective environments within metal-organic frameworks, yet materials development and industrial implementation have been hindered by the inability to predictively control crystallite size and shape. One common strategy to control crystal growth is the inclusion of coordination modulators, which are molecular species designed to compete with the linker for metal coordination during synthesis. However, these modulators can simultaneously alter the pH of the reaction solution, an effect that can also significantly influence crystal morphology. Herein, noncoordinating buffers are used to independently control reaction pH during metal-organic framework synthesis, enabling direct interrogation of the role of the coordinating species on crystal growth. We demonstrate the efficacy of this strategy in the synthesis of low-dispersity single-crystals of the framework Co-2(dobdc) (dobdc(4-) = 2,5-dioxido-1,4-benzenedicarboxylate) in a pH 7-buffered solution using cobalt(II) acetate as the metal source. Density functional theory calculations reveal that acetate competitively binds to Co during crystallization, and by using a series of cobalt(II) salts with carboxylate anions of varying coordination strength, it is possible to control crystal growth along the c-direction. Finally, we use zero length column chromatography to show that crystal morphology has a direct impact on guest diffusional path length for the industrially important hydrocarbon m-xylene. Together, these results provide molecular-level insight into the use of modulators in governing crystallite morphology and a powerful strategy for the control of molecular diffusion rates within metal-organic frameworks.

Self-assembly of multiligand supramolecular architectures at metal surfaces

Alexander Langner

Self-assembly of organic molecules represents an efficient and convenient bottom-up approach for the structural functionalization of surfaces at the nanometer scale. The great potential of assembling supramolecular architectures from organic molecules lies in the vast choice of building blocks that are accessible. This allows to predefine and to direct the molecular organization through the steric and electronic information stored in the molecules. A large variety of homotopic supramolecular structures can be achieved, however limited in complexity. The full realization of highly developed surface architectures for designable chemical functions and physical properties may depend critically on a higher level of complexity, which could be satisfied by utilizing a mixture of different molecular building blocks. Within this thesis, the self-organization of multi-component systems at well-defined metal surfaces is investigated by scanning tunneling microscopy. The mixtures consist of different representatives of linear polyaromatic ligands with carboxylate or pyridyl derived functional groups. The assembly is directed by hydrogen bonding, metal-organic complex formation or a combination of both, i.e. a hierarchical interaction scheme. The aim of this thesis is threefold: First, the homotopic self-assembly of different pyridyl ligands is investigated as a basis for the multi-component systems. One-dimensional chains as well as two dimensional (2D) networks can be formed by copper-pyridyl coordination motifs. The influence of the substrate on these structures will be discussed in detail. Moreover, the self-organization process of multi-components is investigated at the fundamental level. Since functional groups primarily discriminate the different molecular species during the assembly and with that assure a distinguished arrangement, selective bonding schemes are essential for the design of highly ordered supramolecular architectures. Two suitable selective coordination motifs are identified, an iron-carboxylate and a copper-pyridyl complex node. In ligand mixtures, strong preference of one metal species is observed at surfaces, which would not be expected in solution. In addition, redundant mixtures (i.e. ligands of different size but same functional group) serve as model systems to investigate the dynamic self-organization process of modular multicomponent systems, e.g. self-selection or error tolerance, directly with nanometer accuracy. Self-selection is observed if the molecular recognition is steered by a highly reversible coordination bond, while a more robust bonding fosters structural adaption and tolerance to the introduced error (i.e. redundant mixture). These experiments underline the importance of reversibility of the interactions steering the self-assembly process into highly ordered structures. Finally, the extended possibilities due to the multi-component approach for the construction of advanced architectures and structural control are explored: Complex and sophisticated supramolecular networks can be directly synthesized out of simple molecules at the surface. A hierarchical assembly is presented, where a coordination motif defines a primary unit, while hydrogen bonding steers the 2D organization. The secondary level of interaction (hydrogen bonding) can be exclusively addressed, leading to distinct 2D arrangement of the undisturbed primary coordination units. A concept of structural control by rational design is presented, where geometric network parameters can be modified by the replacement of the appropriate molecular species. Due the multi-component nature of the systems, a finer tuning of the structure is enabled (independent substitution of each component) compared to homotopic assemblies. Moreover, a continuation of the multi-component concept is demonstrated, where organizational control is imposed to a homotopic system by adding an additional molecular species. It is demonstrated that a long range order and thermal stability is imposed onto meta-stable Cu-pyridyl coordination chains by cooperative assembly with a carboxylate species.

EPFL2009

Non-Cytotoxic, Bifunctional EuIII and TbIII Luminescent Macrocyclic Complexes for Luminescence Resonant Energy- Transfer Experiments

Jean-Claude Bünzli, Anne-Sophie Chauvin, Caroline Vandevyver

A new macrocyclic ligand,

L^3

, has been synthesised, based on the cyclen framework grafted with three phenacyl light-harvesting groups and a C5-alkyl chain bearing a carboxylic acid function as a potential linker for biological material. Acidity constants are determined by spectrophotometric titrations, as well as conditional stability constants for the resulting 1:1 complexes with trivalent lanthanide ions. The complexes have stabilities comparable to 1,4,7,10-tetrakis(carbamoylmethyl)- 1,4,7,10- tetraazacyclododecane (dtma) complexes, with

pLn \approx 12-13

. Photophysical properties of the ligand and of the

EuL^3

and

TbL^3

complexes have been determined for both microcrystalline samples and solutions in water and acetonitrile. They point to the metal ion being present in an environment with axial symmetry derived from the

C_4

point group. The hydration number determined for

TbL^3

decreases with increasing pH value and becomes fractional at pH 7.5, which points to an equilibrium between two differently solvated species and probably to the participation of the deprotonated carboxylic acid chain in the complexation. The quantum yields in water (1.9% for

Eu^{III}

, 3.4% for

Tb^{III}

) are smaller than those for complexes with the symmetrically substituted parent macrocycle, but efficient luminescence resonant energy transfer (LRET) was observed when Cy5 dye was added to the solutions. Finally, the influence of the

TbL^3

complex on cell viability is tested on both malignant (5D10 mouse hybridoma, Jurkat human T leukaemia, MCF-7 human breast carcinoma) and non-malignant (Hacat human keratinocyte) cell lines. Cell viability after 24 h incubation at

37^ {\circ}C

with

500\mu m

TbL^3

was >90% for all cell lines, except Jurkat (>70%). All of these properties make

LnL^3

complexes interesting potential probes for bioanalyses.

2007

Carboxylic Acid Functionalized Clathrochelate Complexes: Large, Robust, and Easy-to-Access Metalloligands

Mathieu Jérémie Marmier, Philip Pattison, Kurt Schenk, Rosario Scopelliti, Kay Severin, Euro Solari, Matthew David Wise

Polycarboxylate ligands are among the most important building blocks for the synthesis of metal–organic frameworks (MOFs). The ability to access these ligands in an efficient way is of key importance for future applications of MOFs. Here, we demonstrate that mono- and dinuclear clathrochelate complexes are versatile scaffolds for the preparation of polytopic carboxylate ligands. The largely inert clathrochelate complexes have a trigonal-bipyramidal shape. The synthesis of functionalized clathrochelates with two, three, four, or five carboxylic acid groups in the ligand periphery can be achieved in a few steps from simple starting materials. Apart from being easily accessible, the metalloligands display interesting characteristics for applications in metallasupramolecular chemistry and materials science: they are rigid, large (up to 2.2 nm), and robust and they can show additional functions (e.g., fluorescence or extra charge) depending on the metal ion that is present in the clathrochelate core. The utility of these new metalloligands in MOF chemistry is demonstrated by the synthesis of zinc- and zirconium-based coordination polymers. The combination of Zn(NO3)2 with clathrochelates having two or three carboxylic acid groups gives MOFs in which the clathrochelate ligands are connected by Zn4O clusters or zinc paddlewheel links. The structures of the resulting two- and three-dimensional networks could be established by single-crystal X-ray crystallography. The reaction of carboxylic acid functionalized clathrochelates with ZrCl4 gives amorphous powders that display permanent porosity after solvent removal.

Amer Chemical Soc2016