Combined Nuclear Magnetic Resonance and Molecular Dynamics Study of Methane Adsorption in M-2(dobdc) Metal-Organic Frameworks

We examine the diffusion of methane in the metal organic frameworks M-2(dobdc) (M = Mg, Ni, Zn; dobdc(4-) = 2,5-diwddo-1,4-benzenedicarboxylate) as a function of methane loading through a combination of nuclear magnetic resonance and molecular dynamics simulations. At low gas densities, our results suggest that favorable CH4-CH4 interactions lower the free energy barrier for methane hopping between coordinatively unsaturated metal sites and thus enhance the translational motion of methane down the c-axis. At higher gas densities, CH4-CH4 interactions become more significant, CH4-CH4 collisions become more frequent, and the gas self-diffusion begins to decrease. Finally, we observe that the self-diffusion coefficient of methane is inversely related to the binding energy at the coordinatively unsaturated metal sites, such that diffusion is most rapid in the Zn-2(dobdc) framework.

Characterization of metal organic frameworks of interest for gas adsorption/separation applications

Mehrdad Asgari

Metal-Organic Frameworks (MOFs) are a class of porous materials that are applicable in many energy and environmentally relevant areas, due to their unique features including unprecedented internal surface areas and easy chemical tunability. Gas separation and storage are among the most important applications for which MOFs have been extensively studied. Considering the large number of potential MOFs that can be accessed, through a combination of numerous metal clusters and organic linkers, determining the relationship between their structural features (such as pore size and shape and chemical functionalities) and corresponding gas adsorption properties is of utmost importance. In this regard, in-situ characterization, especially diffraction, can be advantageous. MOFs can offer high crystallinity, and so their structure can readily be characterized via diffraction. In addition, due to the presence of metal ions, and predefined molecular building blocks, which exhibit multiple chemical moieties, the potential energy surface for a guest molecule within a MOF cavity possesses multiple minima that correspond to well-defined adsorption sites with varying binding energies. This makes diffraction the most direct way to probe static site-specific binding properties. Given this, the focus of this work is on understanding the structure-derived function of MOFs of interest in gas separation/storage applications. To do this, standard adsorption experiments are coupled with in-situ diffraction techniques. The latter is able to reveal the location and orientation of adsorbed guest species inside the framework, provide insights into the framework response to varying pressure, temperature, and atmosphere, and allow one to determine the relative differences in binding energy between neighboring adsorption sites. The aforementioned information can then be used to rationalize the relationship between different physiochemical features of a given framework and their performance in an adsorption process. In addition to establishing structure-property relations for the usage of MOFs, the obtained experimental results are used to corroborate those calculated by DFT methods, providing a stress test for computational methods aimed at predicting the structures and properties of hypothetical MOFs. The first chapter of this thesis, the introduction, offers a brief review of different characterization methods for studying gas adsorption/separation applications in MOFs. Although the focus of this chapter is on carbon dioxide capture as the application, these characterization methods are also used to study other adsorption processes. The next three chapters, chapters 2-4, present several prominent MOF families that are of interest in hydrogen storage and carbon dioxide capture applications. These case studies demonstrate how using in-situ diffraction techniques coupled with adsorption measurements and DFT calculations can be used to gain molecular level insight into how small molecules bind inside the selected MOF structures. Further, these structure-property correlation studies are able to help unveil how altering MOF building blocks, such as metals and ligands, gives rise to enhanced or diminished adsorption properties. The last chapter, chapter 5, is a study of the response of an activated MOF to varying temperature; in this chapter various structural motions, which are responsible for a large negative thermal expansion (NTE), are elucidated.

EPFL2020

Chemical exchange in proteins

Mariachiara Verde

Nuclear Magnetic Resonance (NMR) spectroscopy offers many ways to investigate dynamic properties of molecules. A wide variety of experimental techniques can probe molecular dynamics on time scales that range from 10-12 to 103 seconds. Many lines of evidence point to the existence of large scale dynamics on milli- to microsecond time scale that are essential to molecular function. Those conformational motions can give rise to chemical exchange effects. So far in the literature two methods have been mainly used to study such processes: CPMG echo trains and R1ρ spin-lock relaxation experiments. The former is suited to investigate processes on the millisecond time scale, whereas R1ρ can probe processes ranging from milliseconds down to ca. microseconds. CPMG and R1ρ studies of the relaxation rates of single quantum (SQ) coherences can be complemented by multiple quantum coherence (MQ) coherences experiments which can provide information whether two (or more) spins are affected simultaneously by chemical exchange. The goal of this thesis is to characterize chemical exchange in proteins by new (Heteronuclear Double Resonance, HDR) and existing (relaxation compensated CPMG) methods. The presence of chemical exchange has been identified in APO-rMUP using the classical CPMG experiment on single quantum 15N magnetization, whereas in HOLO-rMUP no presence of chemical exchange has been found. Most of the thesis is dedicated to the analysis and the application of a new method, HDR, which is designed to determine the cross-relaxation rates between MQ operators. In fact, in heteronuclear systems, correlated chemical exchange contributes to cross-relaxation between MQ coherences 2IxSx and 2IySy. This method, based on MLEV-32 and WALTZ-16 used in double resonance mode, is designed to effectively preserve all relevant MQ coherences simultaneously so that the interconversion between MQ operators can only arise through cross-relaxation. This is an essential requirement if we want to measure, for example, small cross-relaxation rates between MQ operators. We have treated the effects of coherent evolution during the HDR sequences by numerical simulations and Average Hamiltonian Theory (AHT) showing that, under most conditions, the dynamics of MQ coherences is not affected by coherent evolution. This result is proved experimentally on the 15N-1H pair of selectively deuterated tBoc-glycine. The effect of relaxation during HDR sequences leads to an effective relaxation superoperator which is explored by numerical simulations and predicted by Average Liouvillian Theory (ALT). Finally the HDR MLEV-32 sequence is applied to amide 1H-15N pairs in ubiquitin and KIX proteins. In the case of ubiquitin the HDR MLEV-32 experiments and the numerical simulations run with parameters obtained from the literature are in good agreement, suggesting that HDR sequences could be used as a tool to obtain information about the dynamics of the system.

EPFL2009

Characterization of metal organic frameworks of interest for gas adsorption/separation applications

Mehrdad Asgari

EPFL2020

Chemical exchange in proteins

Mariachiara Verde

EPFL2009