Hydrocarbon Sorption in Flexible MOFs: Part I: Thermodynamic Analysis with the Dubinin-Based Universal Adsorption Theory (D-UAT)

Preißler-Kurzhöfer, Hannes, Lange, Marcus, Kolesnikov, Andrei, Möllmer, Jens, Erhart, Oliver, Kobalz, Merten, Krautscheid, Harald, Gläser, Roger

27 October 2023

The analysis of empirical sorption equilibrium datasets is still vital to gain insights into material–property relationships as computational methods remain in development, especially for complex materials such as flexible MOFs. Therefore, the Dubinin-based universal adsorption theory (D-UAT) was revisited and evaluated as a simple visualization, analysis, and prediction tool for sorption equilibrium data. Within the theory, gas properties are normalized into corresponding states using the critical temperatures of the respective sorptives. The study shows theoretically and experimentally that the D-UAT is able to condense differences of sorption data visualized in reduced Dubinin plots to just three governing parameters: (a) the accessible pore volume, (b) the reduced enthalpy of sorption, and (c) the framework’s reduced free energy differences (in case of flexible behavior). This makes the theory a fast visualization and analysis tool, the use as a prediction tool depends on rough assumptions, and thus is not recommended.

info:eu-repo/classification/ddc/540

ddc:540

Proposed Biomedical Applications of Zirconium-Based Metal-Organic Frameworks as Drug Delivery Systems

Perry-Mills, Ariel Margaret

01 January 2019

Metal-organic frameworks (MOFs) are a class of highly crystalline nanoporous materials that self-assemble from inorganic metal oxide clusters and multitopic organic linkers. MOFs can be altered in terms of the types of metals and structures of organic linkers used, allowing for a high degree of customization and manipulation of the synergistic chemical or physical properties that arise from the precise coordination of their molecular components, including exceptionally large surface area and pore size. Zirconium-based MOFs, called UiOs in honor of their conception at the University of Oslo, also show remarkable chemical stability in both acidic and basic environments, making them excellent candidates for biomedical applications as drug delivery systems, where they can either function as molecular cargo ships, with drugs packed into their pores, or as controlled release systems, in which drug molecules are directly attached to their ligands for precise delivery. The objective of this work is to prepare water-stable MOFs whose linkers are decorated with functional groups that have potential compatibility in drug delivery systems and to explore the efficacy of certain synthesis conditions in terms of the crystallinity of the MOF product. Thus, we hope to establish a basis for the ligation of anticancer drugs and fluorescent tags to MOFs for their controlled release at a specified location within the body. These targeted release mechanisms represent new therapeutic possibilities in terms of cancer treatment as their specificity would mitigate damage to healthy tissues, thereby addressing one of the greatest weakness of present treatment options.

metal-organic frameworks

drug delivery system

MOFs

nanomedicine

UiO-66

UiO-68

Oncology

Pharmacology

Reticular Chemistry for the Rational Design of Intricate Metal-Organic Frameworks

Jiang, Hao

11 1900

The rational design and construction of Metal-Organic Frameworks (MOFs) with intricate structural complexity are of prime importance in reticular chemistry. However, the design of intricate structures that can practically be synthesized is very difficult, and the suitable targeted intricate nets are still unexplored. Evidently, it is of great value to build the fundamental theory for the design of intricate structures. This dissertation is focused on the exploration of cutting-edge design methodologies in reticular chemistry. This research shows the design and synthesis of several MOF platforms (hex, fcu, gea and the) based on rare earth polynuclear clusters. Furthermore, this research unveils the latest addition, named merged nets approach, to the design toolbox in reticular chemistry for the rational design and construction of intricate mixed-linker MOFs. In essence, a valuable net for design enclosing two edges is rationally generated by merging two edge-transitive nets, spn and hxg. The resultant merged net, named sph net, offers potential for the deliberate design and construction of highly symmetric isoreticular intricate mixed-linker MOFs, sph-MOF-1 to 4, which represent the first examples of MOFs where the underlying net is merged from two 3-periodic edge-transitive nets. Furthermore, the underlying principle of the merged net approach, the fundamental merged net equation, and two key parameters are disclosed. Also, we discovered three analysis methods to check and validate corresponding signature nets in an edge-transitive net. Based on these analysis methods, a signature map of all edge-transitive nets was established. This map showing the systematic relationship among edge-transitive nets will help the material chemist to comprehend more about the underlying nets in reticular chemistry. Based on the revealed map, we systematically described the nine types of merging combination and 140 merged nets based on two edge-transitive nets. Among these enumerated nets, only 18 of them was shown on the RCSR database before. These enumerated merged nets significantly increased the designable targets in reticular chemistry. Using an example of enumerated sub net, we show how this approach can be utilized to design and synthesis mixed-linker porous materials based on the intricate sub-MOF platform, which presents one of the most intricate MOF structures synthesized by design.

Reticular Chemistry

Metal-Organic Frameworks

Intricate structure design

Graph theory in chemistry

Gas storage and separation

Molecular recognition

Synthesis of Bimetallic Paddlewheel Complexes and Metal Organic Frameworks for Future Use in Catalysis

Mattox, Tracy Marie

30 November 2006

No description available.

metal organic frameworks

coordination networks

lanthanide

paddlewheel

paddlewheel complexes

dirhodium

dirhodium catalyst

Gas Adsorption Applications of Porous Metal-Organic Frameworks

Ma, Shengqian

29 April 2008

No description available.

Chemistry

Porous metal-organic framework

hydrogen storage

methane storage

selective gas adsorption

Magnesium Sulfonyldibenzoates: Synthesis, Structure, Phase Transformation and Microscopic Studies

Lucas, Kaitlyn D.

January 2013

No description available.

Analytical Chemistry

Chemistry

Environmental Science

Molecules

magnesium sulfonyldibenzoate

metal-organic framework

crystal structure

phase transformation

The Growth and Characterization of Gallium Arsenide Nanowire Structures by Metal Organic Chemical Vapor Deposition

Minutillo, Nicholas G.

January 2014

No description available.

Physics

Metal Organic Chemical Vapor Deposition

Nanowires

Semiconductor

III-V

Photoluminescence

Binary metal organic framework derived hierarchical hollow Ni3S2/Co9S8/N-doped carbon composite with superior sodium storage performance

Liu, Xinye

January 2017

No description available.

Energy

Environmental Engineering

Metal-Organic Frameworks for Post-Combustion Carbon Capture - A Life Cycle Assessment

Gu, Xiangming

24 August 2018

No description available.

Chemical Engineering

post combustion capture

metal-organic framework

machine learning

life cycle assessment

Pyroelectric Properties of Ferroelectric Lanthanum Bismuth Titanate Thin Films

Palan, Rohit Chandulal

11 October 2001

No description available.

Engineering, Materials Science

Bismuth Titanate

Ferroelectric Properties

Pyroelectric Properties

Metal-Organic Decomposition

Thin Films